Your search keyword '"O'Phelan, K"' showing total 87 results

1. PP425 [Brain » Brain]: PROGNOSTIC AND DIAGNOSTIC UTILITY OF INFLAMMASOME PROTEINS IN PEDIATRIC TRAUMATIC BRAIN INJURY

Author

Munoz Pareja, J. C., primary, De Rivero Vaccari, J., additional, Keane, R., additional, Wang, K., additional, Kobaissy, F., additional, Pringle, C., additional, Snodgrass, K., additional, Gober, J., additional, Coto, J., additional, Perez, P. K., additional, Mccrea, H., additional, Thorson, C., additional, O’phelan, K. H., additional, Swaby, K., additional, and Dietrich, W. D., additional

Published

2022

2. Worldwide Organization of Neurocritical Care: Results from the PRINCE Study Part 1

Author

Suarez, J. I., Martin, R. H., Bauza, C., Georgiadis, A., Venkatasubba Rao, C. P., Calvillo, E., Hemphill, J. C., Sung, G., Oddo, M., Taccone, Fabio Silvio, Leroux, P. D., Layon, A. J., Sarwal, A., Ali, A., Lele, A., Jarquin-Valdivia, A. A., Misiewska-Kaczur, A., Ahmad, A., Deeb, A. M., Jabbary, A. A., Fathy, A., Chan, A., Kern, CHRISTOPH ALEXANDER, Gritsan, A., Bshabshe, A. A., Malek, A., Schiefecker, A., Neto, A. R., ALHAJJ HASSAN, Ali, Zahrani, A. R. A., Sukumaran, A. V., Sarma, A. K., Aneman, A., Kramer, A., Naidech, A., Lacerda Gallardo, A. J., Miller, A., O'Connor, A., Kim, A., Afshinnik, A., Katila, A., Paulson, A., Parra, A., Rosengart, A., Almemari, A., Sanchez, B., Ray, B., Mccrum, B., Tegedor, B. V., Nathan, B., Tan, B., Emanuel, B., Pfaulser, B., Nazliel, B., Gil, B., Hightower, B., Francis, B., Roberts, B., Chaudhry, B., Romero, C., Graffagnino, C., VANDEN BERGHE, GREET CLARA, Hobohm, C., Dias, C., Bradford, C., Basignani, C., Chang, C., Junker, C., Lazaridis, C., Mcarthur, C., Williamson, C., Hebert, C., Ethan Kahn, D., Harvey, D., Laskowitz, D. T., Milzman, D., Chung, D., Greer, D., Seder, D., Miller, D. W., Barge, D., Roberts, D., Jordan, D., Bhonagiri, D., Nair, D., Aggarwal, D. G., Kutsogiannis, D. J., Laiwattana, D., Pinto, D. B., Bautista, D., Perez, D., Herrera, E. A., Singares, E. S., Manno, E., Wilensky, E. M., Giraldo, E. A., Jenkinson, E., Yarad, E., Zavala, E., Tesoro, E., Eskiogly, E., Bershad, E. M., Rosenthal, E., Coronel, E. B., Gordon, E., Salgado, E., Poch, E. J., Eriksson, E., Taccone, F. S., Al-Suwaidan, F., Sorond, F., Bilotta, F., Goldenberg, F. D., Rosciani, F., Bass, F., Bernard, F., Julian, F. B., Rasulo, F., Rincon, F., Santos, G., Anderson, G., Henderson, G., Meyfroidt, G., Wong, G. K. C., Aguilar, G., Rodriguez-Vega, G., Tamayo, G., Johnston, G., Kapinos, G., Abrego, G. C., Paul, G., Xu, G., Domeniconi, G., Dugan, G., Murthy, H. H. K., Peled, H., Zraiki, H., Alvarez, H., Rodgers, H., Vaitkevicius, H., Schumacher, H. C., Kobata, H., Al-Jehani, H., Lopez Delgado, H. J., Olmecah, H. M., Madrinan-Navia, H., Tran, H., Seppelt, I., Schirotzek, I., Medary, I. B., Maldonado, I. L., da Silva, I. R. F., Hemphill III, J. C., Javier Provencio, J., Mora, J. E., Abdullah, J. M., Langdon, J. R., Claassen, J., de Oliveira, J., Shilkin, J., Horn, J., Teitelbaum, J., Frank, J. I., Fletcher, J. J., Berkeley, J., Andersson, KIM JIMMY, Kirkwood, J., Welbourne, J., Song, J., Domingues, J. R. S., Paxton, J., Falla, J., Lokin, J., Dissin, J., Bonomo, J., Martinez, J. E., Mejia-Mantilla, J. H., Ramirez-Arce, J., Palo, J. E., Moretti, J. I., Gonzalez, J. R. Y., Levine, J. M., Medow, J., Pou, J. A. L., Ciro, J. D., Paucar, J. L. C., Wright, J. C., Bosel, J., Martinez, J., Mijangos-Mendez, J. C., Chalela, J., Granillo, J. F., Sohal, J., Hirsch, K. G., Donaldson, K., Cummings, K., Hubner, K. E., Wartenberg, K., Goyal, K., Sheth, K., Kunze, K., O'Phelan, K., Sheehan, K., Altaweel, L., Cross, L., Barrachina, L. G., Kuisle, L., Connolyy, L. S., Tack, L., Johnson, L., Shutter, L., Pelunkova, L., Ramos-Gomez, L. A., Camputaro, L. A., Kamran Athar, M., Madhusudan, M., Hashmi, M., Mokhtari, M., Jibaja, M., Muller, M. C. A., Costilla, M., Mirski, M., Ochoa, M. E., Pegoli, M., Dujardin, M. -F., Allasia, M., Teran, M. D., Gorman, Michael Murray, Chapman, M., Amatangelo, M., Nagayama, M., Dickinson, M., Koenig, M., Moreda, M., Berman, M., De Georgia, M., Kuiper, M., O'Leary, M., Rodricks, M., Schneck, M., Torbey, M., Defilippis, M., Meeker, M., Allen, David Michael, Llano, M., Villalobos, M., Treggiari, M., Tuppeny, M., Sharaby, M., Kottapally, M., Mcnett, M., Mcbride, M., Gomez, M., Varga, M., Kumar, M., Yazbeck, M. F., Smith, M., Stevenson Porter, N., Hammond, N., Karanjia, N., Sokhal, N., Singhal, N. S., Badjatia, N., Maldonado, N., Ko, N., Marinoff, N., Hernandez Aguilar, Orisel, Krauchi, O. R., Sanchez, O., Gomez, O., Rivera, O. S., Gilvaz, P. C., Raffa, P., Varelas, P., Promsin, P., Merlani, P., Shushma, P., Allan, P., Biston, P., Vespa, P., Amorim, P., de Azambuja Rodrigues, P. M., Hopkins, P., Hantson, P., Vanamoorthy, P., Gupta, P., Garvin, R., Badenes, R., Damani, R., Helbok, R., Dhar, R., Rawal, R., Carandang, R., Guisado, R., Luengo, R. -I. G., Sajjad, R., Davis, R., Rison, R. A., Hoesch, R., Murillo, R., Smith, R., Ball, R., Beer, R., Reshi, R. A., Landry, R., Puvanendiran, S., Ansari, S., Mukaddam, S., Garg, S., Mishra, S., Clark, S., Napolitano, Silvano, Pattnaik, S., Vosylius, S., John, S., Josephson, S. A., Glickman, S., Brehaut, S. S., Shiraz, S. A., Aguilera, S., Sternberg, S., Chou, S., Vallance, S., Lasocki, S., Schoenenberger, S., Bird, S., Finfer, S., Shieber, S., Vadi, S., Samavedam, S., Cordina, S., Feske, S., Glassner, S., Dixit, S., Dowling, S., Tena, S. A., Bowling, S., Francken, S., Muehlschlegel, S., Renard, S., Poli, S., Carter, T., Bleck, T. P., Trim, T., Breitenfeld, T., Van Bui, T., Shukla, U., Sinha, V., Rajajee, V., Aiyagari, V., Mccredie, V., Svigelj, V., Verma, V., Rao, V. A., David Freeman, W., Smith, W. S., Videtta, W., Habre, W., Hall, W., Coplin, W. M., Abdo, W. F., Wittebole, X., Titova, Y., PRINCE Study Investigators, Layon, A.J., Sarwal, A., Ali, A., Lele, A., Jarquin-Valdivia, A.A., Misiewska-Kaczur, A., Ahmad, A., Deeb, A.M., Jabbary, A.A., Fathy, A., Chan, A., Kern, A., Georgiadis, A., Gritsan, A., Bshabshe, A.A., Malek, A., Schiefecker, A., Neto, A.R., Hassan, A., Zahrani, ARA, Sukumaran, A.V., Sarma, A.K., Aneman, A., Kramer, A., Naidech, A., Lacerda Gallardo, A.J., Miller, A., O'Connor, A., Kim, A., Afshinnik, A., Katila, A., Paulson, A., Parra, A., Rosengart, A., Almemari, A., Sanchez, B., Ray, B., McCrum, B., Tegedor, B.V., Nathan, B., Tan, B., Emanuel, B., Pfaulser, B., Nazliel, B., Gil, B., Hightower, B., Francis, B., Roberts, B., Chaudhry, B., Romero, C., Graffagnino, C., Berghe, C., Hobohm, C., Dias, C., Bradford, C., Basignani, C., Chang, C., Venkatasubba Rao, C.P., Junker, C., Lazaridis, C., McArthur, C., Williamson, C., Hebert, C., Ethan Kahn, D., Harvey, D., Laskowitz, D.T., Milzman, D., Chung, D., Greer, D., Seder, D., Miller, D.W., Barge, D., Roberts, D., Jordan, D., Bhonagiri, D., Nair, D., Aggarwal, D.G., Kutsogiannis, D.J., Laiwattana, D., Pinto, D.B., Bautista, D., Perez, D., Herrera, E.A., Singares, E.S., Manno, E., Wilensky, E.M., Giraldo, E.A., Jenkinson, E., Yarad, E., Zavala, E., Tesoro, E., Eskiogly, E., Bershad, E.M., Rosenthal, E., Coronel, E.B., Gordon, E., Salgado, E., Poch, E.J., Calvillo, E., Eriksson, E., Taccone, F.S., Al-Suwaidan, F., Sorond, F., Bilotta, F., Goldenberg, F.D., Rosciani, F., Bass, F., Bernard, F., Julian, F.B., Rasulo, F., Rincon, F., Santos, G., Anderson, G., Henderson, G., Meyfroidt, G., Sung, G., Wong, GKC, Aguilar, G., Rodriguez-Vega, G., Tamayo, G., Johnston, G., Kapinos, G., Abrego, G.C., Paul, G., Xu, G., Domeniconi, G., Dugan, G., Murthy, HHK, Peled, H., Zraiki, H., Alvarez, H., Rodgers, H., Vaitkevicius, H., Schumacher, H.C., Kobata, H., Al-Jehani, H., Lopez Delgado, H.J., Olmecah, H.M., Madrinan-Navia, H., Tran, H., Seppelt, I., Schirotzek, I., Medary, I.B., Maldonado, I.L., da Silva, IRF, Hemphill Iii, J.C., Javier Provencio, J., Mora, J.E., Abdullah, J.M., Langdon, J.R., Claassen, J., de Oliveira, J., Shilkin, J., Horn, J., Teitelbaum, J., Frank, J.I., Fletcher, J.J., Berkeley, J., Kim, J., Kirkwood, J., Welbourne, J., Song, J., Domingues, JRS, Paxton, J., Falla, J., Lokin, J., Dissin, J., Bonomo, J., Martinez, J.E., Mejia-Mantilla, J.H., Ramirez-Arce, J., Palo, J.E., Moretti, J.I., Suarez, J.I., Gonzalez, JRY, Levine, J.M., Medow, J., Pou, JAL, Ciro, J.D., Paucar, JLC, Wright, J.C., Bosel, J., Martinez, J., Mijangos-Mendez, J.C., Chalela, J., Granillo, J.F., Sohal, J., Hirsch, K.G., Donaldson, K., Cummings, K., Hubner, K.E., Wartenberg, K., Goyal, K., Sheth, K., Kunze, K., O'Phelan, K., Sheehan, K., Altaweel, L., Cross, L., Barrachina, L.G., Kuisle, L., Connolyy, L.S., Tack, L., Johnson, L., Shutter, L., Pelunkova, L., Ramos-Gomez, L.A., Camputaro, L.A., Kamran Athar, M., Madhusudan, M., Hashmi, M., Mokhtari, M., Jibaja, M., Muller, MCA, Costilla, M., Mirski, M., Ochoa, M.E., Pegoli, M., Dujardin, M.F., Allasia, M., Teran, M.D., Gorman, M., Chapman, M., Amatangelo, M., Nagayama, M., Dickinson, M., Koenig, M., Moreda, M., Berman, M., De Georgia, M., Kuiper, M., O'Leary, M., Rodricks, M., Schneck, M., Torbey, M., DeFilippis, M., Meeker, M., Allen, M., Llano, M., Villalobos, M., Treggiari, M., Tuppeny, M., Sharaby, M., Kottapally, M., McNett, M., McBride, M., Gomez, M., Varga, M., Kumar, M., Yazbeck, M.F., Smith, M., Stevenson Porter, N., Hammond, N., Karanjia, N., Sokhal, N., Singhal, N.S., Badjatia, N., Maldonado, N., Ko, N., Marinoff, N., Hernandez, O., Krauchi, O.R., Sanchez, O., Gomez, O., Rivera, O.S., Gilvaz, P.C., Raffa, P., Varelas, P., Promsin, P., Merlani, P., Shushma, P., Allan, P., Biston, P., Vespa, P., Amorim, P., de Azambuja Rodrigues, P.M., Hopkins, P., Hantson, P., Vanamoorthy, P., Gupta, P., Garvin, R., Badenes, R., Damani, R., Helbok, R., Dhar, R., Rawal, R., Carandang, R., Guisado, R., Luengo, R.G., Sajjad, R., Davis, R., Rison, R.A., Hoesch, R., Murillo, R., Smith, R., Ball, R., Beer, R., Reshi, R.A., Landry, R., Puvanendiran, S., Ansari, S., Mukaddam, S., Garg, S., Mishra, S., Clark, S., Napolitano, S., Pattnaik, S., Vosylius, S., John, S., Josephson, S.A., Glickman, S., Brehaut, S.S., Shiraz, S.A., Aguilera, S., Sternberg, S., Chou, S., Vallance, S., Lasocki, S., Schoenenberger, S., Bird, S., Finfer, S., Shieber, S., Vadi, S., Samavedam, S., Cordina, S., Feske, S., Glassner, S., Dixit, S., Dowling, S., Tena, S.A., Bowling, S., Francken, S., Muehlschlegel, S., Renard, S., Poli, S., Carter, T., Bleck, T.P., Trim, T., Breitenfeld, T., Van Bui, T., Shukla, U., Sinha, V., Rajajee, V., Aiyagari, V., McCredie, V., Svigelj, V., Verma, V., Rao, V.A., David Freeman, W., Smith, W.S., Videtta, W., Habre, W., Hall, W., Coplin, W.M., Abdo, W.F., Wittebole, X., Titova, Y., Intensive Care Medicine, ANS - Neuroinfection & -inflammation, Other Research, ACS - Pulmonary hypertension & thrombosis, UCL - SSS/IREC/MEDA - Pôle de médecine aiguë, and UCL - (SLuc) Service de soins intensifs

Subjects

Internationality, Scope of practice, Latin Americans, medicine.medical_treatment, lnfectious Diseases and Global Health Radboud Institute for Molecular Life Sciences [Radboudumc 4], Pharmacists, Critical Care and Intensive Care Medicine, law.invention, 0302 clinical medicine, Clinical Protocols, Central Nervous System Diseases, law, Observational study, Epidemiology, Neurocritical care, Case report form, Academic Medical Centers, Intensive care unit, Telemedicine, Europe, Intensive Care Units, Prospective, Transportation of Patients, Neurology, Practice Guidelines as Topic, Critical care, Outcomes, Original Work, Respiratory Therapy, medicine.medical_specialty, Asia, Tomography Scanners, X-Ray Computed, Critical Care, Health Personnel, Oceania, Respiratory therapist, Neurosurgery, Pharmacist, Personnel Management, Resource Allocation, Middle East, 03 medical and health sciences, Physicians, medicine, Humans, Fellowships and Scholarships, business.industry, Internship and Residency, Neurointensive care, 030208 emergency & critical care medicine, Latin America, Family medicine, North America, Neurology (clinical), business, Delivery of Health Care, 030217 neurology & neurosurgery

Abstract

Introduction Neurocritical care focuses on the care of critically ill patients with an acute neurologic disorder and has grown significantly in the past few years. However, there is a lack of data that describe the scope of practice of neurointensivists and epidemiological data on the types of patients and treatments used in neurocritical care units worldwide. To address these issues, we designed a multicenter, international, point-prevalence, cross-sectional, prospective, observational, non-interventional study in the setting of neurocritical care (PRINCE Study). Methods In this manuscript, we analyzed data from the initial phase of the study that included registration, hospital, and intensive care unit (ICU) organizations. We present here descriptive statistics to summarize data from the registration case report form. We performed the Kruskal–Wallis test followed by the Dunn procedure to test for differences in practices among world regions. Results We analyzed information submitted by 257 participating sites from 47 countries. The majority of those sites, 119 (46.3%), were in North America, 44 (17.2%) in Europe, 34 (13.3%) in Asia, 9 (3.5%) in the Middle East, 34 (13.3%) in Latin America, and 14 (5.5%) in Oceania. Most ICUs are from academic institutions (73.4%) located in large urban centers (44% > 1 million inhabitants). We found significant differences in hospital and ICU organization, resource allocation, and use of patient management protocols. The highest nursing/patient ratio was in Oceania (100% 1:1). Dedicated Advanced Practiced Providers are mostly present in North America (73.7%) and are uncommon in Oceania (7.7%) and the Middle East (0%). The presence of dedicated respiratory therapist is common in North America (85%), Middle East (85%), and Latin America (84%) but less common in Europe (26%) and Oceania (7.7%). The presence of dedicated pharmacist is highest in North America (89%) and Oceania (85%) and least common in Latin America (38%). The majority of respondents reported having a dedicated neuro-ICU (67% overall; highest in North America: 82%; and lowest in Oceania: 14%). Conclusion The PRINCE Study results suggest that there is significant variability in the delivery of neurocritical care. The study also shows it is feasible to undertake international collaborations to gather global data about the practice of neurocritical care. Electronic supplementary material The online version of this article (10.1007/s12028-019-00750-3) contains supplementary material, which is available to authorized users.

Published

2020

3. Monitoring Inflammation (Including Fever) in Acute Brain Injury

Author

Provencio J. J., Badjatia N., Le Roux P., Menon D. K., Vespa P., Citerio G., Bader M. K., Brophy G. M., Diringer M. N., Stocchetti N., Videtta W., Armonda R., Boesel J., Chesnut R., Chou S., Claassen J., Czosnyka M., De Georgia M., Figaji A., Fugate J., Helbok R., Horowitz D., Hutchinson P., Kumar M., McNett M., Miller C., Naidech A., Oddo M., Olson D., O'Phelan K., Puppo C., Riker R., Robertson C., Schmidt J. M., Taccone F., Provencio, J, Badjatia, N, Le Roux, P, Menon, D, Vespa, P, Citerio, G, Bader, M, Brophy, G, Diringer, M, Stocchetti, N, Videtta, W, Armonda, R, Boesel, J, Chesnut, R, Chou, S, Claassen, J, Czosnyka, M, De Georgia, M, Figaji, A, Fugate, J, Helbok, R, Horowitz, D, Hutchinson, P, Kumar, M, Mcnett, M, Miller, C, Naidech, A, Oddo, M, Olson, D, O'Phelan, K, Puppo, C, Riker, R, Robertson, C, Schmidt, J, and Taccone, F

Subjects

medicine.medical_specialty, Neurology, Critical Care, Fever, Monitoring, medicine.medical_treatment, Inflammation, Targeted temperature management, Critical Care and Intensive Care Medicine, C-reactive protein, Predictive Value of Tests, White blood cell, Neurocritical care, medicine, Humans, Brain injury, Intensive care medicine, Immunity, Cellular, biology, business.industry, Shivering, Neurointensive care, Prognosis, medicine.anatomical_structure, Brain Injuries, Inflammatory cascade, biology.protein, Neurology (clinical), Inflammation Mediators, medicine.symptom, business, Biomarkers

Abstract

Inflammation is an important part of the normal physiologic response to acute brain injury (ABI). How inflammation is manifest determines if it augments or hinders the resolution of ABI. Monitoring body temperature, the cellular arm of the inflammatory cascade, and inflammatory proteins may help guide therapy. This summary will address the utility of inflammation monitoring in brain-injured adults. An electronic literature search was conducted for English language articles describing the testing, utility, and optimal methods to measure inflammation in ABI. Ninety-four articles were included in this review. Current evidence suggests that control of inflammation after ABI may hold promise for advances in good outcomes. However, our understanding of how much inflammation is good and how much is deleterious is not yet clear. Several important concepts emerge form our review. First, while continuous temperature monitoring of core body temperature is recommended, temperature pattern alone is not useful in distinguishing infectious from noninfectious fever. Second, when targeted temperature management is used, shivering should be monitored at least hourly. Finally, white blood cell levels and protein markers of inflammation may have a limited role in distinguishing infectious from noninfectious fever. Our understanding of optimal use of inflammation monitoring after ABI is limited currently but is an area of active investigation.

Published

2014

4. Intracranial Pressure and Cerebral Perfusion Pressure Monitoring in Non-TBI Patients: Special Considerations

Author

Helbok R., Olson D. W. M., Le Roux P. D., Vespa P., Menon D. K., Citerio G., Bader M. K., Brophy G. M., Diringer M. N., Stocchetti N., Videtta W., Armonda R., Badjatia N., Boesel J., Chesnut R., Chou S., Claassen J., Czosnyka M., De Georgia M., Figaji A., Fugate J., Horowitz D., Hutchinson P., Kumar M., McNett M., Miller C., Naidech A., Oddo M., O'Phelan K., Provencio J., Puppo C., Riker R., Robertson C., Schmidt J. M., Taccone F., Helbok, R, Olson, D, Le Roux, P, Vespa, P, Menon, D, Citerio, G, Bader, M, Brophy, G, Diringer, M, Stocchetti, N, Videtta, W, Armonda, R, Badjatia, N, Boesel, J, Chesnut, R, Chou, S, Claassen, J, Czosnyka, M, De Georgia, M, Figaji, A, Fugate, J, Horowitz, D, Hutchinson, P, Kumar, M, Mcnett, M, Miller, C, Naidech, A, Oddo, M, O'Phelan, K, Provencio, J, Puppo, C, Riker, R, Robertson, C, Schmidt, J, and Taccone, F

Subjects

Ventriculostomy, medicine.medical_specialty, Neurology, Subarachnoid hemorrhage, Critical Care, Intracranial Pressure, Traumatic brain injury, medicine.medical_treatment, Critical Care and Intensive Care Medicine, medicine, Humans, Cerebral perfusion pressure, Intracranial pressure, Coma, Intracerebral hemorrhage, Brain Diseases, integumentary system, business.industry, Patient Selection, musculoskeletal, neural, and ocular physiology, Prognosis, medicine.disease, Neurophysiological Monitoring, humanities, nervous system diseases, Brain edema, Coma, CPP, ICP, Intracerebral hemorrhage, Subarachnoid hemorrhage, Ventriculostomy, Cerebrovascular Circulation, Anesthesia, Neurology (clinical), medicine.symptom, business

Abstract

The effect of intracranial pressure (ICP) and the role of ICP monitoring are best studied in traumatic brain injury (TBI). However, a variety of acute neurologic illnesses e.g., subarachnoid hemorrhage, intracerebral hemorrhage, ischemic stroke, meningitis/encephalitis, and select metabolic disorders, e.g., liver failure and malignant, brain tumors can affect ICP. The purpose of this paper is to review the literature about ICP monitoring in conditions other than TBI and to provide recommendations how the technique may be used in patient management. A PubMed search between 1980 and September 2013 identified 989 articles; 225 of which were reviewed in detail. The technique used to monitor ICP in non-TBI conditions is similar to that used in TBI; however, indications for ICP monitoring often are intertwined with the presence of obstructive hydrocephalus and hence the use of ventricular catheters is more frequent. Increased ICP can adversely affect outcome, particularly when it fails to respond to treatment. However, patients with elevated ICP can still have favorable outcomes. Although the influence of ICP-based care on outcome in non-TBI conditions appears less robust than in TBI, monitoring ICP and cerebral perfusion pressure can play a role in guiding therapy in select patients.

Published

2014

5. International Multidisciplinary Consensus Conference on Multimodality Monitoring: ICU Processes of Care

Author

McNett M. M., Horowitz D. A., Le Roux P., Menon D. K., Vespa P., Citerio G., Bader M. K., Brophy G. M., Diringer M. N., Stocchetti N., Videtta W., Armonda R., Badjatia N., Boesel J., Chesnut R., Chou S., Claassen J., Czosnyka M., De Georgia M., Figaji A., Fugate J., Helbok R., Hutchinson P., Kumar M., Miller C., Naidech A., Oddo M., Olson D., O'Phelan K., Provencio J., Puppo C., Riker R., Robertson C., Schmidt J. M., Taccone F., Mcnett, M, Horowitz, D, Le Roux, P, Menon, D, Vespa, P, Citerio, G, Bader, M, Brophy, G, Diringer, M, Stocchetti, N, Videtta, W, Armonda, R, Badjatia, N, Boesel, J, Chesnut, R, Chou, S, Claassen, J, Czosnyka, M, De Georgia, M, Figaji, A, Fugate, J, Helbok, R, Hutchinson, P, Kumar, M, Miller, C, Naidech, A, Oddo, M, Olson, D, O'Phelan, K, Provencio, J, Puppo, C, Riker, R, Robertson, C, Schmidt, J, and Taccone, F

Subjects

medicine.medical_specialty, Consensus, Internationality, Critical Care, Population, MEDLINE, Benchmark, Critical Care and Intensive Care Medicine, law.invention, Clinical Protocols, Ambulatory care, law, Intensive care, Critical care nursing, Health care, Neurocritical care, Humans, Medicine, Mortality, Intensive care medicine, education, Outcome, education.field_of_study, business.industry, Process Assessment, Health Care, Neurointensive care, medicine.disease, Quality, Neurophysiological Monitoring, Intensive care unit, Brain Injuries, Neurology (clinical), Medical emergency, business

Abstract

There is an increased focus on evaluating processes of care, particularly in the high acuity and cost environment of intensive care. Evaluation of neurocritical-specific care and evidence-based protocol implementation are needed to effectively determine optimal processes of care and effect on patient outcomes. General quality measures to evaluate intensive care unit (ICU) processes of care have been proposed; however, applicability of these measures in neurocritical care populations has not been established. A comprehensive literature search was conducted for English language articles from 1990 to August 2013. A total of 1,061 articles were reviewed, with 145 meeting criteria for inclusion in this review. Care in specialized neurocritical care units or by neurocritical teams can have a positive impact on mortality, length of stay, and in some cases, functional outcome. Similarly, implementation of evidence-based protocol-directed care can enhance outcome in the neurocritical care population. There is significant evidence to support suggested quality indicators for the general ICU population, but limited research regarding specific use in neurocritical care. Quality indices for neurocritical care have been proposed; however, additional research is needed to further validate measures.

Published

2014

6. Monitoring Nutrition and Glucose in Acute Brain Injury

Author

Badjatia N., Vespa P., Le Roux P., Menon D. K., Citerio G., Bader M. K., Brophy G. M., Diringer M. N., Stocchetti N., Videtta W., Armonda R., Boesel J., Chesnut R., Chou S., Claassen J., Czosnyka M., De Georgia M., Figaji A., Fugate J., Helbok R., Horowitz D., Hutchinson P., Kumar M., McNett M., Miller C., Naidech A., Oddo M., Olson D., O'Phelan K., Provencio J., Puppo C., Riker R., Robertson C., Schmidt J. M., Taccone F., Badjatia, N, Vespa, P, Le Roux, P, Menon, D, Citerio, G, Bader, M, Brophy, G, Diringer, M, Stocchetti, N, Videtta, W, Armonda, R, Boesel, J, Chesnut, R, Chou, S, Claassen, J, Czosnyka, M, De Georgia, M, Figaji, A, Fugate, J, Helbok, R, Horowitz, D, Hutchinson, P, Kumar, M, Mcnett, M, Miller, C, Naidech, A, Oddo, M, Olson, D, O'Phelan, K, Provencio, J, Puppo, C, Riker, R, Robertson, C, Schmidt, J, and Taccone, F

Subjects

Blood Glucose, medicine.medical_specialty, Neurology, Critical Care, Population, Critical Care and Intensive Care Medicine, Enteral Nutrition, medicine, Humans, education, Adverse effect, Intensive care medicine, Neurophysiological Monitoring, Blood glucose monitoring, education.field_of_study, medicine.diagnostic_test, business.industry, Neurointensive care, Calorimetry, Indirect, Anthropometry, Nutrition Assessment, Parenteral nutrition, Brain Injuries, Neurology (clinical), Energy Metabolism, Brain injury, Energy expenditure, Glucose, Monitoring, Nitrogen balance, Nutritional assessment, business

Abstract

The metabolic response to injury is well described; however, very little is understood about optimal markers to measure this response. This summary will address the current evidence about monitoring nutritional status including blood glucose after acute brain injury (ABI). An electronic literature search was conducted for English language articles describing the testing, utility, and optimal methods to measure nutritional status and blood glucose levels in the neurocritical care population. A total of 45 articles were included in this review. Providing adequate and timely nutritional support can help improve outcome after ABI. However, the optimal content and total nutrition requirements remain unclear. In addition, how best to monitor the nutritional status in ABI is still being elucidated, and at present, there is no validated optimal method to monitor the global response to nutritional support on a day-to-day basis in ABI patients. Nitrogen balance may be monitored to assess the adequacy of caloric intake as it relates to protein energy metabolism, but indirect calorimetry, anthropometric measurement, or serum biomarker requires further validation. The adverse effects of hyperglycemia in ABI are well described, and data indicate that blood glucose should be carefully controlled in critically ill patients. However, the optimal frequency or duration for blood glucose monitoring after ABI remains poorly defined. There are significant knowledge gaps about monitoring nutritional status and response to nutritional interventions in ABI; these need to be addressed and hence few recommendations can be made. The optimal frequency and duration of blood glucose monitoring need further study.

Published

2014

7. Multimodality Monitoring: Informatics, Integration Data Display and Analysis

Author

Schmidt J. M., De Georgia M., Le Roux P., Menon D. K., Vespa P., Citerio G., Bader M. K., Brophy G. M., Diringer M. N., Stocchetti N., Videtta W., Armonda R., Badjatia N., Boesel J., Chesnut R., Chou S., Claassen J., Czosnyka M., Figaji A., Fugate J., Helbok R., Horowitz D., Hutchinson P., Kumar M., McNett M., Miller C., Naidech A., Oddo M., Olson D., O'Phelan K., Provencio J., Puppo C., Riker R., Robertson C., Taccone F., Schmidt, J, De Georgia, M, Le Roux, P, Menon, D, Vespa, P, Citerio, G, Bader, M, Brophy, G, Diringer, M, Stocchetti, N, Videtta, W, Armonda, R, Badjatia, N, Boesel, J, Chesnut, R, Chou, S, Claassen, J, Czosnyka, M, Figaji, A, Fugate, J, Helbok, R, Horowitz, D, Hutchinson, P, Kumar, M, Mcnett, M, Miller, C, Naidech, A, Oddo, M, Olson, D, O'Phelan, K, Provencio, J, Puppo, C, Riker, R, Robertson, C, and Taccone, F

Subjects

Information management, Telemedicine, Decision support system, Critical Care, business.industry, Critical care, Data display, Data integration, Decision support, Informatics, Neuromonitoring, Critical Care and Intensive Care Medicine, computer.software_genre, Neurophysiological Monitoring, Health informatics, Data science, Data warehouse, Systems Integration, Intensive care, Informatics, Data Display, Humans, Medicine, Medical Informatics Applications, Neurology (clinical), business, computer, Data integration

Abstract

The goal of multimodality neuromonitoring is to provide continuous, real-time assessment of brain physiology to prevent, detect, and attenuate secondary brain injury. Clinical informatics deals with biomedical data, information, and knowledge including their acquisition, storage, retrieval, and optimal use for clinical decision-making. An electronic literature search was conducted for English language articles describing the use of informatics in the intensive care unit setting from January 1990 to August 2013. A total of 64 studies were included in this review. Clinical informatics infrastructure should be adopted that enables a wide range of linear and nonlinear analytical methods be applied to patient data. Specific time epochs of clinical interest should be reviewable. Analysis strategies of monitor alarms may help address alarm fatigue. Ergonomic data display that present results from analyses with clinical information in a sensible uncomplicated manner improve clinical decision-making. Collecting and archiving the highest resolution physiologic and phenotypic data in a comprehensive open format data warehouse is a crucial first step toward information management and two-way translational research for multimodality monitoring. The infrastructure required is largely the same as that needed for telemedicine intensive care applications, which under the right circumstances improves care quality while reducing cost.

Published

2014

8. Global Monitoring in the Neurocritical Care Unit

Author

Olson, D, Andrew Kofke, W, O'Phelan, K, Gupta, P, Figueroa, S, Smirnakis, S, Leroux, P, Suarez, J, Citerio, G, Olson D. W. M., Andrew Kofke W., O'Phelan K., Gupta P. K., Figueroa S. A., Smirnakis S. M., Leroux P. D., Suarez J. I., Citerio Giuseppe, Olson, D, Andrew Kofke, W, O'Phelan, K, Gupta, P, Figueroa, S, Smirnakis, S, Leroux, P, Suarez, J, Citerio, G, Olson D. W. M., Andrew Kofke W., O'Phelan K., Gupta P. K., Figueroa S. A., Smirnakis S. M., Leroux P. D., Suarez J. I., and Citerio Giuseppe

Abstract

Effective methods of monitoring the status of patients with neurological injuries began with non-invasive observations and evolved during the past several decades to include more invasive monitoring tools and physiologic measures. The monitoring paradigm continues to evolve, this time back toward the use of less invasive tools. In parallel, the science of monitoring began with the global assessment of the patient’s neurological condition, evolved to focus on regional monitoring techniques, and with the advent of enhanced computing capabilities is now moving back to focus on global monitoring. The purpose of this session of the Second Neurocritical Care Research Conference was to collaboratively develop a comprehensive understanding of the state of the science for global brain monitoring and to identify research priorities for intracranial pressure monitoring, neuroimaging, and neuro-electrophysiology monitoring.

Published

2015

9. Regional Brain Monitoring in the Neurocritical Care Unit

Author

Frontera, J, Ziai, W, O'Phelan, K, Leroux, P, Kirkpatrick, P, Diringer, M, Suarez, J, Citerio, G, Frontera J., Ziai W., O'Phelan K., Leroux P. D., Kirkpatrick P. J., Diringer M. N., Suarez J. I., Citerio Giuseppe, Frontera, J, Ziai, W, O'Phelan, K, Leroux, P, Kirkpatrick, P, Diringer, M, Suarez, J, Citerio, G, Frontera J., Ziai W., O'Phelan K., Leroux P. D., Kirkpatrick P. J., Diringer M. N., Suarez J. I., and Citerio Giuseppe

Abstract

Regional multimodality monitoring has evolved over the last several years as a tool to understand the mechanisms of brain injury and brain function at the cellular level. Multimodality monitoring offers an important augmentation to the clinical exam and is especially useful in comatose neurocritical care patients. Cerebral microdialysis, brain tissue oxygen monitoring, and cerebral blood flow monitoring all offer insight into permutations in brain chemistry and function that occur in the context of brain injury. These tools may allow for development of individual therapeutic strategies that are mechanistically driven and goal-directed. We present a summary of the discussions that took place during the Second Neurocritical Care Research Conference regarding regional brain monitoring.

Published

2015

10. Regional Brain Monitoring in the Neurocritical Care Unit

Author

Frontera J., Ziai W., O'Phelan K., Leroux P. D., Kirkpatrick P. J., Diringer M. N., Suarez J. I., Citerio Giuseppe, Frontera, J, Ziai, W, O'Phelan, K, Leroux, P, Kirkpatrick, P, Diringer, M, Suarez, J, and Citerio, G

Subjects

Brain Diseases, medicine.medical_specialty, Neurology, Critical Care, business.industry, Clinical exam, Neurointensive care, Context (language use), Brain monitoring, Critical Care and Intensive Care Medicine, Neurophysiological Monitoring, Oxygen monitoring, Cerebral blood flow, Humans, Medicine, Brain tissue oxygenation, Cerebral blood flow, Microdialysis, Neurocritical care, Neuromonitoring, Neurology (clinical), business, Intensive care medicine, Brain function

Abstract

Regional multimodality monitoring has evolved over the last several years as a tool to understand the mechanisms of brain injury and brain function at the cellular level. Multimodality monitoring offers an important augmentation to the clinical exam and is especially useful in comatose neurocritical care patients. Cerebral microdialysis, brain tissue oxygen monitoring, and cerebral blood flow monitoring all offer insight into permutations in brain chemistry and function that occur in the context of brain injury. These tools may allow for development of individual therapeutic strategies that are mechanistically driven and goal-directed. We present a summary of the discussions that took place during the Second Neurocritical Care Research Conference regarding regional brain monitoring.

Published

2015

11. The Future of Neurocritical Care Research: Proceedings and Recommendations from the Fifth Neurocritical Care Research Network Conference.

Author

Hocker, S., Shah, S., Vespa, P., Provencio, J. J., Calvillo, E., Olson, D. M., Venkatasubba Rao, C. P., Hemphill III, J. C., Helbok, R., Human, T., Kamel, H., Madden, L. K., Nyquist, P., Bentho, O., O'Phelan, K., Lewin III, J. J., Alexander, S., Ziai, W., Chou, S. H., and Rincon, F.

Subjects

TEAMS in the workplace, CONFERENCES & conventions

Abstract

The Fifth Neurocritical Care Research Network (NCRN) Conference held in Boca Raton, Florida, in September of 2018 was devoted to challenging the current status quo and examining the role of the Neurocritical Care Society (NCS) in driving the science and research of neurocritical care. The aim of this in-person meeting was to set the agenda for the NCS's Neurocritical Care Research Central, which is the overall research arm of the society. Prior to the meeting, all 103 participants received educational content (book and seminar) on the 'Blue Ocean Strategy®,' a concept from the business world which aims to identify undiscovered and uncontested market space, and to brainstorm innovative ideas and methods with which to address current challenges in neurocritical care research. Three five-member working groups met at least four times by teleconference prior to the in-person meeting to prepare answers to a set of questions using the Blue Ocean Strategy concept as a platform. At the Fifth NCRN Conference, these groups presented to a five-member jury and all attendees for open discussion. The jury then developed a set of recommendations for NCS to consider in order to move neurocritical care research forward. We have summarized the topics discussed at the conference and put forward recommendations for the future direction of the NCRN and neurocritical care research in general. [ABSTRACT FROM AUTHOR]

Published

2020

12. International Multidisciplinary Consensus Conference on Multimodality Monitoring: ICU Processes of Care

Author

Mcnett, M, Horowitz, D, Le Roux, P, Menon, D, Vespa, P, Citerio, G, Bader, M, Brophy, G, Diringer, M, Stocchetti, N, Videtta, W, Armonda, R, Badjatia, N, Boesel, J, Chesnut, R, Chou, S, Claassen, J, Czosnyka, M, De Georgia, M, Figaji, A, Fugate, J, Helbok, R, Hutchinson, P, Kumar, M, Miller, C, Naidech, A, Oddo, M, Olson, D, O'Phelan, K, Provencio, J, Puppo, C, Riker, R, Robertson, C, Schmidt, J, Taccone, F, McNett M. M., Horowitz D. A., Le Roux P., Menon D. K., Vespa P., Citerio G., Bader M. K., Brophy G. M., Diringer M. N., Stocchetti N., Videtta W., Armonda R., Badjatia N., Boesel J., Chesnut R., Chou S., Claassen J., Czosnyka M., De Georgia M., Figaji A., Fugate J., Helbok R., Hutchinson P., Kumar M., Miller C., Naidech A., Oddo M., Olson D., O'Phelan K., Provencio J., Puppo C., Riker R., Robertson C., Schmidt J. M., Taccone F., Mcnett, M, Horowitz, D, Le Roux, P, Menon, D, Vespa, P, Citerio, G, Bader, M, Brophy, G, Diringer, M, Stocchetti, N, Videtta, W, Armonda, R, Badjatia, N, Boesel, J, Chesnut, R, Chou, S, Claassen, J, Czosnyka, M, De Georgia, M, Figaji, A, Fugate, J, Helbok, R, Hutchinson, P, Kumar, M, Miller, C, Naidech, A, Oddo, M, Olson, D, O'Phelan, K, Provencio, J, Puppo, C, Riker, R, Robertson, C, Schmidt, J, Taccone, F, McNett M. M., Horowitz D. A., Le Roux P., Menon D. K., Vespa P., Citerio G., Bader M. K., Brophy G. M., Diringer M. N., Stocchetti N., Videtta W., Armonda R., Badjatia N., Boesel J., Chesnut R., Chou S., Claassen J., Czosnyka M., De Georgia M., Figaji A., Fugate J., Helbok R., Hutchinson P., Kumar M., Miller C., Naidech A., Oddo M., Olson D., O'Phelan K., Provencio J., Puppo C., Riker R., Robertson C., Schmidt J. M., and Taccone F.

Abstract

There is an increased focus on evaluating processes of care, particularly in the high acuity and cost environment of intensive care. Evaluation of neurocritical-specific care and evidence-based protocol implementation are needed to effectively determine optimal processes of care and effect on patient outcomes. General quality measures to evaluate intensive care unit (ICU) processes of care have been proposed; however, applicability of these measures in neurocritical care populations has not been established. A comprehensive literature search was conducted for English language articles from 1990 to August 2013. A total of 1,061 articles were reviewed, with 145 meeting criteria for inclusion in this review. Care in specialized neurocritical care units or by neurocritical teams can have a positive impact on mortality, length of stay, and in some cases, functional outcome. Similarly, implementation of evidence-based protocol-directed care can enhance outcome in the neurocritical care population. There is significant evidence to support suggested quality indicators for the general ICU population, but limited research regarding specific use in neurocritical care. Quality indices for neurocritical care have been proposed; however, additional research is needed to further validate measures.

Published

2014

13. Multimodality Monitoring Consensus Statement: Monitoring in Emerging Economies

Author

Figaji, A, Puppo, C, Le Roux, P, Menon, D, Vespa, P, Citerio, G, Bader, M, Brophy, G, Diringer, M, Stocchetti, N, Videtta, W, Armonda, R, Badjatia, N, Boesel, J, Chesnut, R, Chou, S, Claassen, J, Czosnyka, M, De Georgia, M, Fugate, J, Helbok, R, Horowitz, D, Hutchinson, P, Kumar, M, Mcnett, M, Miller, C, Naidech, A, Oddo, M, Olson, D, O'Phelan, K, Provencio, J, Riker, R, Robertson, C, Schmidt, J, Taccone, F, Figaji A., Puppo C., Le Roux P., Menon D. K., Vespa P., Citerio G., Bader M. K., Brophy G. M., Diringer M. N., Stocchetti N., Videtta W., Armonda R., Badjatia N., Boesel J., Chesnut R., Chou S., Claassen J., Czosnyka M., De Georgia M., Fugate J., Helbok R., Horowitz D., Hutchinson P., Kumar M., McNett M., Miller C., Naidech A., Oddo M., Olson D., O'Phelan K., Provencio J., Riker R., Robertson C., Schmidt J. M., Taccone F., Figaji, A, Puppo, C, Le Roux, P, Menon, D, Vespa, P, Citerio, G, Bader, M, Brophy, G, Diringer, M, Stocchetti, N, Videtta, W, Armonda, R, Badjatia, N, Boesel, J, Chesnut, R, Chou, S, Claassen, J, Czosnyka, M, De Georgia, M, Fugate, J, Helbok, R, Horowitz, D, Hutchinson, P, Kumar, M, Mcnett, M, Miller, C, Naidech, A, Oddo, M, Olson, D, O'Phelan, K, Provencio, J, Riker, R, Robertson, C, Schmidt, J, Taccone, F, Figaji A., Puppo C., Le Roux P., Menon D. K., Vespa P., Citerio G., Bader M. K., Brophy G. M., Diringer M. N., Stocchetti N., Videtta W., Armonda R., Badjatia N., Boesel J., Chesnut R., Chou S., Claassen J., Czosnyka M., De Georgia M., Fugate J., Helbok R., Horowitz D., Hutchinson P., Kumar M., McNett M., Miller C., Naidech A., Oddo M., Olson D., O'Phelan K., Provencio J., Riker R., Robertson C., Schmidt J. M., and Taccone F.

Abstract

The burden of disease and so the need for care is often greater at hospitals in emerging economies. This is compounded by frequent restrictions in the delivery of good quality clinical care due to resource limitations. However, there is substantial heterogeneity in this economically defined group, such that advanced brain monitoring is routinely practiced at certain centers that have an interest in neurocritical care. It also must be recognized that significant heterogeneity in the delivery of neurocritical care exists even within individual high-income countries (HICs), determined by costs and level of interest. Direct comparisons of data between HICs and the group of low- and middle-income countries (LAMICs) are made difficult by differences in patient demographics, selection for ICU admission, therapies administered, and outcome assessment. Evidence suggests that potential benefits of multimodality monitoring depend on an appropriate environment and clinical expertise. There is no evidence to suggest that patients in LAMICs where such resources exist should be treated any differently to patients from HICs. The potential for outcome benefits in LAMICs is arguably greater in absolute terms because of the large burden of disease; however, the relative cost/benefit ratio of such monitoring in this setting must be viewed in context of the overall priorities in delivering health care at individual institutions.

Published

2014

14. Multimodality Monitoring: Informatics, Integration Data Display and Analysis

Author

Schmidt, J, De Georgia, M, Le Roux, P, Menon, D, Vespa, P, Citerio, G, Bader, M, Brophy, G, Diringer, M, Stocchetti, N, Videtta, W, Armonda, R, Badjatia, N, Boesel, J, Chesnut, R, Chou, S, Claassen, J, Czosnyka, M, Figaji, A, Fugate, J, Helbok, R, Horowitz, D, Hutchinson, P, Kumar, M, Mcnett, M, Miller, C, Naidech, A, Oddo, M, Olson, D, O'Phelan, K, Provencio, J, Puppo, C, Riker, R, Robertson, C, Taccone, F, Schmidt J. M., De Georgia M., Le Roux P., Menon D. K., Vespa P., Citerio G., Bader M. K., Brophy G. M., Diringer M. N., Stocchetti N., Videtta W., Armonda R., Badjatia N., Boesel J., Chesnut R., Chou S., Claassen J., Czosnyka M., Figaji A., Fugate J., Helbok R., Horowitz D., Hutchinson P., Kumar M., McNett M., Miller C., Naidech A., Oddo M., Olson D., O'Phelan K., Provencio J., Puppo C., Riker R., Robertson C., Taccone F., Schmidt, J, De Georgia, M, Le Roux, P, Menon, D, Vespa, P, Citerio, G, Bader, M, Brophy, G, Diringer, M, Stocchetti, N, Videtta, W, Armonda, R, Badjatia, N, Boesel, J, Chesnut, R, Chou, S, Claassen, J, Czosnyka, M, Figaji, A, Fugate, J, Helbok, R, Horowitz, D, Hutchinson, P, Kumar, M, Mcnett, M, Miller, C, Naidech, A, Oddo, M, Olson, D, O'Phelan, K, Provencio, J, Puppo, C, Riker, R, Robertson, C, Taccone, F, Schmidt J. M., De Georgia M., Le Roux P., Menon D. K., Vespa P., Citerio G., Bader M. K., Brophy G. M., Diringer M. N., Stocchetti N., Videtta W., Armonda R., Badjatia N., Boesel J., Chesnut R., Chou S., Claassen J., Czosnyka M., Figaji A., Fugate J., Helbok R., Horowitz D., Hutchinson P., Kumar M., McNett M., Miller C., Naidech A., Oddo M., Olson D., O'Phelan K., Provencio J., Puppo C., Riker R., Robertson C., and Taccone F.

Abstract

The goal of multimodality neuromonitoring is to provide continuous, real-time assessment of brain physiology to prevent, detect, and attenuate secondary brain injury. Clinical informatics deals with biomedical data, information, and knowledge including their acquisition, storage, retrieval, and optimal use for clinical decision-making. An electronic literature search was conducted for English language articles describing the use of informatics in the intensive care unit setting from January 1990 to August 2013. A total of 64 studies were included in this review. Clinical informatics infrastructure should be adopted that enables a wide range of linear and nonlinear analytical methods be applied to patient data. Specific time epochs of clinical interest should be reviewable. Analysis strategies of monitor alarms may help address alarm fatigue. Ergonomic data display that present results from analyses with clinical information in a sensible uncomplicated manner improve clinical decision-making. Collecting and archiving the highest resolution physiologic and phenotypic data in a comprehensive open format data warehouse is a crucial first step toward information management and two-way translational research for multimodality monitoring. The infrastructure required is largely the same as that needed for telemedicine intensive care applications, which under the right circumstances improves care quality while reducing cost.

Published

2014

15. Monitoring Inflammation (Including Fever) in Acute Brain Injury

Author

Provencio, J, Badjatia, N, Le Roux, P, Menon, D, Vespa, P, Citerio, G, Bader, M, Brophy, G, Diringer, M, Stocchetti, N, Videtta, W, Armonda, R, Boesel, J, Chesnut, R, Chou, S, Claassen, J, Czosnyka, M, De Georgia, M, Figaji, A, Fugate, J, Helbok, R, Horowitz, D, Hutchinson, P, Kumar, M, Mcnett, M, Miller, C, Naidech, A, Oddo, M, Olson, D, O'Phelan, K, Puppo, C, Riker, R, Robertson, C, Schmidt, J, Taccone, F, Provencio J. J., Badjatia N., Le Roux P., Menon D. K., Vespa P., Citerio G., Bader M. K., Brophy G. M., Diringer M. N., Stocchetti N., Videtta W., Armonda R., Boesel J., Chesnut R., Chou S., Claassen J., Czosnyka M., De Georgia M., Figaji A., Fugate J., Helbok R., Horowitz D., Hutchinson P., Kumar M., McNett M., Miller C., Naidech A., Oddo M., Olson D., O'Phelan K., Puppo C., Riker R., Robertson C., Schmidt J. M., Taccone F., Provencio, J, Badjatia, N, Le Roux, P, Menon, D, Vespa, P, Citerio, G, Bader, M, Brophy, G, Diringer, M, Stocchetti, N, Videtta, W, Armonda, R, Boesel, J, Chesnut, R, Chou, S, Claassen, J, Czosnyka, M, De Georgia, M, Figaji, A, Fugate, J, Helbok, R, Horowitz, D, Hutchinson, P, Kumar, M, Mcnett, M, Miller, C, Naidech, A, Oddo, M, Olson, D, O'Phelan, K, Puppo, C, Riker, R, Robertson, C, Schmidt, J, Taccone, F, Provencio J. J., Badjatia N., Le Roux P., Menon D. K., Vespa P., Citerio G., Bader M. K., Brophy G. M., Diringer M. N., Stocchetti N., Videtta W., Armonda R., Boesel J., Chesnut R., Chou S., Claassen J., Czosnyka M., De Georgia M., Figaji A., Fugate J., Helbok R., Horowitz D., Hutchinson P., Kumar M., McNett M., Miller C., Naidech A., Oddo M., Olson D., O'Phelan K., Puppo C., Riker R., Robertson C., Schmidt J. M., and Taccone F.

Abstract

Inflammation is an important part of the normal physiologic response to acute brain injury (ABI). How inflammation is manifest determines if it augments or hinders the resolution of ABI. Monitoring body temperature, the cellular arm of the inflammatory cascade, and inflammatory proteins may help guide therapy. This summary will address the utility of inflammation monitoring in brain-injured adults. An electronic literature search was conducted for English language articles describing the testing, utility, and optimal methods to measure inflammation in ABI. Ninety-four articles were included in this review. Current evidence suggests that control of inflammation after ABI may hold promise for advances in good outcomes. However, our understanding of how much inflammation is good and how much is deleterious is not yet clear. Several important concepts emerge form our review. First, while continuous temperature monitoring of core body temperature is recommended, temperature pattern alone is not useful in distinguishing infectious from noninfectious fever. Second, when targeted temperature management is used, shivering should be monitored at least hourly. Finally, white blood cell levels and protein markers of inflammation may have a limited role in distinguishing infectious from noninfectious fever. Our understanding of optimal use of inflammation monitoring after ABI is limited currently but is an area of active investigation.

Published

2014

16. Monitoring Nutrition and Glucose in Acute Brain Injury

Author

Badjatia, N, Vespa, P, Le Roux, P, Menon, D, Citerio, G, Bader, M, Brophy, G, Diringer, M, Stocchetti, N, Videtta, W, Armonda, R, Boesel, J, Chesnut, R, Chou, S, Claassen, J, Czosnyka, M, De Georgia, M, Figaji, A, Fugate, J, Helbok, R, Horowitz, D, Hutchinson, P, Kumar, M, Mcnett, M, Miller, C, Naidech, A, Oddo, M, Olson, D, O'Phelan, K, Provencio, J, Puppo, C, Riker, R, Robertson, C, Schmidt, J, Taccone, F, Badjatia N., Vespa P., Le Roux P., Menon D. K., Citerio G., Bader M. K., Brophy G. M., Diringer M. N., Stocchetti N., Videtta W., Armonda R., Boesel J., Chesnut R., Chou S., Claassen J., Czosnyka M., De Georgia M., Figaji A., Fugate J., Helbok R., Horowitz D., Hutchinson P., Kumar M., McNett M., Miller C., Naidech A., Oddo M., Olson D., O'Phelan K., Provencio J., Puppo C., Riker R., Robertson C., Schmidt J. M., Taccone F., Badjatia, N, Vespa, P, Le Roux, P, Menon, D, Citerio, G, Bader, M, Brophy, G, Diringer, M, Stocchetti, N, Videtta, W, Armonda, R, Boesel, J, Chesnut, R, Chou, S, Claassen, J, Czosnyka, M, De Georgia, M, Figaji, A, Fugate, J, Helbok, R, Horowitz, D, Hutchinson, P, Kumar, M, Mcnett, M, Miller, C, Naidech, A, Oddo, M, Olson, D, O'Phelan, K, Provencio, J, Puppo, C, Riker, R, Robertson, C, Schmidt, J, Taccone, F, Badjatia N., Vespa P., Le Roux P., Menon D. K., Citerio G., Bader M. K., Brophy G. M., Diringer M. N., Stocchetti N., Videtta W., Armonda R., Boesel J., Chesnut R., Chou S., Claassen J., Czosnyka M., De Georgia M., Figaji A., Fugate J., Helbok R., Horowitz D., Hutchinson P., Kumar M., McNett M., Miller C., Naidech A., Oddo M., Olson D., O'Phelan K., Provencio J., Puppo C., Riker R., Robertson C., Schmidt J. M., and Taccone F.

Abstract

The metabolic response to injury is well described; however, very little is understood about optimal markers to measure this response. This summary will address the current evidence about monitoring nutritional status including blood glucose after acute brain injury (ABI). An electronic literature search was conducted for English language articles describing the testing, utility, and optimal methods to measure nutritional status and blood glucose levels in the neurocritical care population. A total of 45 articles were included in this review. Providing adequate and timely nutritional support can help improve outcome after ABI. However, the optimal content and total nutrition requirements remain unclear. In addition, how best to monitor the nutritional status in ABI is still being elucidated, and at present, there is no validated optimal method to monitor the global response to nutritional support on a day-to-day basis in ABI patients. Nitrogen balance may be monitored to assess the adequacy of caloric intake as it relates to protein energy metabolism, but indirect calorimetry, anthropometric measurement, or serum biomarker requires further validation. The adverse effects of hyperglycemia in ABI are well described, and data indicate that blood glucose should be carefully controlled in critically ill patients. However, the optimal frequency or duration for blood glucose monitoring after ABI remains poorly defined. There are significant knowledge gaps about monitoring nutritional status and response to nutritional interventions in ABI; these need to be addressed and hence few recommendations can be made. The optimal frequency and duration of blood glucose monitoring need further study.

Published

2014

17. International Multidisciplinary Consensus Conference on Multimodality Monitoring: Cerebral Metabolism

Author

Hutchinson, P, O'Phelan, K, Le Roux, P, Menon, D, Vespa, P, Citerio, G, Bader, M, Brophy, G, Diringer, M, Stocchetti, N, Videtta, W, Armonda, R, Badjatia, N, Boesel, J, Chesnut, R, Chou, S, Claassen, J, Czosnyka, M, De Georgia, M, Figaji, A, Fugate, J, Helbok, R, Horowitz, D, Kumar, M, Mcnett, M, Miller, C, Naidech, A, Oddo, M, Olson, D, Provencio, J, Puppo, C, Riker, R, Robertson, C, Schmidt, J, Taccone, F, Hutchinson P., O'Phelan K., Le Roux P., Menon D. K., Vespa P., Citerio G., Bader M. K., Brophy G. M., Diringer M. N., Stocchetti N., Videtta W., Armonda R., Badjatia N., Boesel J., Chesnut R., Chou S., Claassen J., Czosnyka M., De Georgia M., Figaji A., Fugate J., Helbok R., Horowitz D., Kumar M., McNett M., Miller C., Naidech A., Oddo M., Olson D., Provencio J., Puppo C., Riker R., Robertson C., Schmidt J. M., Taccone F., Hutchinson, P, O'Phelan, K, Le Roux, P, Menon, D, Vespa, P, Citerio, G, Bader, M, Brophy, G, Diringer, M, Stocchetti, N, Videtta, W, Armonda, R, Badjatia, N, Boesel, J, Chesnut, R, Chou, S, Claassen, J, Czosnyka, M, De Georgia, M, Figaji, A, Fugate, J, Helbok, R, Horowitz, D, Kumar, M, Mcnett, M, Miller, C, Naidech, A, Oddo, M, Olson, D, Provencio, J, Puppo, C, Riker, R, Robertson, C, Schmidt, J, Taccone, F, Hutchinson P., O'Phelan K., Le Roux P., Menon D. K., Vespa P., Citerio G., Bader M. K., Brophy G. M., Diringer M. N., Stocchetti N., Videtta W., Armonda R., Badjatia N., Boesel J., Chesnut R., Chou S., Claassen J., Czosnyka M., De Georgia M., Figaji A., Fugate J., Helbok R., Horowitz D., Kumar M., McNett M., Miller C., Naidech A., Oddo M., Olson D., Provencio J., Puppo C., Riker R., Robertson C., Schmidt J. M., and Taccone F.

Abstract

Microdialysis is a powerful technique, which enables the chemistry of the extracellular space to be measured directly. Applying this technique to patients in neurointensive care has increased our understanding of the pathophysiology of traumatic brain injury and spontaneous hemorrhage. In parallel, it is important to determine the place of microdialysis in assisting in the management of patients on an individual intention to treat basis. This is made possible by the availability of analyzers which can measure the concentration of glucose, pyruvate, lactate, and glutamate at the bedside. Samples can then be stored for later analysis of other substrate and metabolites e.g., other amino acids and cytokines. The objective of this paper is to review the fundamental literature pertinent to the clinical application of microdialysis in neurointensive care and to give recommendations on how the technique can be applied to assist in patient management and contribute to outcome. A literature search detected 1,933 publications of which 55 were used for data abstraction and analysis. The role of microdialysis was evaluated in three conditions (traumatic brain injury, subarachnoid hemorrhage, and intracerebral hemorrhage) and recommendations focused on three fundamental areas (relationship to outcome, application of microdialysis to guide therapy, and the ability of microdialysis to predict secondary deterioration).

Published

2014

18. Clinical Monitoring Scales in Acute Brain Injury: Assessment of Coma, Pain, Agitation, and Delirium

Author

Riker, R, Fugate, J, Le Roux, P, Menon, D, Vespa, P, Citerio, G, Bader, M, Brophy, G, Diringer, M, Stocchetti, N, Videtta, W, Armonda, R, Badjatia, N, Boesel, J, Chesnut, R, Chou, S, Claassen, J, Czosnyka, M, De Georgia, M, Figaji, A, Helbok, R, Horowitz, D, Hutchinson, P, Kumar, M, Mcnett, M, Miller, C, Naidech, A, Oddo, M, Olson, D, O'Phelan, K, Provencio, J, Puppo, C, Robertson, C, Schmidt, J, Taccone, F, Riker R. R., Fugate J. E., Le Roux P., Menon D. K., Vespa P., Citerio G., Bader M. K., Brophy G. M., Diringer M. N., Stocchetti N., Videtta W., Armonda R., Badjatia N., Boesel J., Chesnut R., Chou S., Claassen J., Czosnyka M., De Georgia M., Figaji A., Helbok R., Horowitz D., Hutchinson P., Kumar M., McNett M., Miller C., Naidech A., Oddo M., Olson D., O'Phelan K., Provencio J., Puppo C., Robertson C., Schmidt J. M., Taccone F., Riker, R, Fugate, J, Le Roux, P, Menon, D, Vespa, P, Citerio, G, Bader, M, Brophy, G, Diringer, M, Stocchetti, N, Videtta, W, Armonda, R, Badjatia, N, Boesel, J, Chesnut, R, Chou, S, Claassen, J, Czosnyka, M, De Georgia, M, Figaji, A, Helbok, R, Horowitz, D, Hutchinson, P, Kumar, M, Mcnett, M, Miller, C, Naidech, A, Oddo, M, Olson, D, O'Phelan, K, Provencio, J, Puppo, C, Robertson, C, Schmidt, J, Taccone, F, Riker R. R., Fugate J. E., Le Roux P., Menon D. K., Vespa P., Citerio G., Bader M. K., Brophy G. M., Diringer M. N., Stocchetti N., Videtta W., Armonda R., Badjatia N., Boesel J., Chesnut R., Chou S., Claassen J., Czosnyka M., De Georgia M., Figaji A., Helbok R., Horowitz D., Hutchinson P., Kumar M., McNett M., Miller C., Naidech A., Oddo M., Olson D., O'Phelan K., Provencio J., Puppo C., Robertson C., Schmidt J. M., and Taccone F.

Abstract

Serial clinical examination represents the most fundamental and basic form of neurological monitoring, and is often the first and only form of such monitoring in patients. Even in patients subjected to physiological monitoring using a range of technologies, the clinical examination remains an essential tool to follow neurological progress. Key aspects of the clinical examination have now been systematized into scoring schemes, and address consciousness, pain, agitation, and delirium (PAD). The Glasgow Coma Scale has been the traditional tool to measure consciousness, but the full outline of unresponsiveness (FOUR) score has recently been validated in a variety of settings, and at present, both represent clinically useful tools. Assessment of PAD in neurologically compromised patients present special challenges. For pain, the Numeric Rating Scale is the preferred initial approach, with either the Behavioral Pain Scale or the Critical Care Pain Observation Tool in subjects who are not able to respond. The Nociception Coma Scale-Revised may be useful in patients with severe disorders of consciousness. Conventional sedation scoring tools for critical care, such as the Richmond Area Sedation Scale (RASS) and Sedation–Agitation Scale (SAS) may provide reasonable tools in some neurocritical care patients. The use of sedative drugs and neuromuscular blockers may invalidate the use of some clinical examination tools in others. The use of sedation interruption to assess neurological status can result in physiological derangement in unstable patients (such as those with uncontrolled intracranial hypertension), and is not recommended.

Published

2014

19. Monitoring of Brain and Systemic Oxygenation in Neurocritical Care Patients

Author

Oddo, M, Bosel, J, Le Roux, P, Menon, D, Vespa, P, Citerio, G, Bader, M, Brophy, G, Diringer, M, Stocchetti, N, Videtta, W, Armonda, R, Badjatia, N, Chesnut, R, Chou, S, Claassen, J, Czosnyka, M, De Georgia, M, Figaji, A, Fugate, J, Helbok, R, Horowitz, D, Hutchinson, P, Kumar, M, Mcnett, M, Miller, C, Naidech, A, Olson, D, O'Phelan, K, Provencio, J, Puppo, C, Riker, R, Robertson, C, Schmidt, J, Taccone, F, Oddo M., Bosel J., Le Roux P., Menon D. K., Vespa P., Citerio G., Bader M. K., Brophy G. M., Diringer M. N., Stocchetti N., Videtta W., Armonda R., Badjatia N., Chesnut R., Chou S., Claassen J., Czosnyka M., De Georgia M., Figaji A., Fugate J., Helbok R., Horowitz D., Hutchinson P., Kumar M., McNett M., Miller C., Naidech A., Olson D., O'Phelan K., Provencio J., Puppo C., Riker R., Robertson C., Schmidt J. M., Taccone F., Oddo, M, Bosel, J, Le Roux, P, Menon, D, Vespa, P, Citerio, G, Bader, M, Brophy, G, Diringer, M, Stocchetti, N, Videtta, W, Armonda, R, Badjatia, N, Chesnut, R, Chou, S, Claassen, J, Czosnyka, M, De Georgia, M, Figaji, A, Fugate, J, Helbok, R, Horowitz, D, Hutchinson, P, Kumar, M, Mcnett, M, Miller, C, Naidech, A, Olson, D, O'Phelan, K, Provencio, J, Puppo, C, Riker, R, Robertson, C, Schmidt, J, Taccone, F, Oddo M., Bosel J., Le Roux P., Menon D. K., Vespa P., Citerio G., Bader M. K., Brophy G. M., Diringer M. N., Stocchetti N., Videtta W., Armonda R., Badjatia N., Chesnut R., Chou S., Claassen J., Czosnyka M., De Georgia M., Figaji A., Fugate J., Helbok R., Horowitz D., Hutchinson P., Kumar M., McNett M., Miller C., Naidech A., Olson D., O'Phelan K., Provencio J., Puppo C., Riker R., Robertson C., Schmidt J. M., and Taccone F.

Abstract

Maintenance of adequate oxygenation is a mainstay of intensive care, however, recommendations on the safety, accuracy, and the potential clinical utility of invasive and non-invasive tools to monitor brain and systemic oxygenation in neurocritical care are lacking. A literature search was conducted for English language articles describing bedside brain and systemic oxygen monitoring in neurocritical care patients from 1980 to August 2013. Imaging techniques e.g., PET are not considered. A total of 281 studies were included, the majority described patients with traumatic brain injury (TBI). All tools for oxygen monitoring are safe. Parenchymal brain oxygen (PbtO2) monitoring is accurate to detect brain hypoxia, and it is recommended to titrate individual targets of cerebral perfusion pressure (CPP), ventilator parameters (PaCO2, PaO2), and transfusion, and to manage intracranial hypertension, in combination with ICP monitoring. SjvO2 is less accurate than PbtO2. Given limited data, NIRS is not recommended at present for adult patients who require neurocritical care. Systemic monitoring of oxygen (PaO2, SaO2, SpO2) and CO2 (PaCO2, end-tidal CO2) is recommended in patients who require neurocritical care.

Published

2014

20. Monitoring of Cerebral Blood Flow and Ischemia in the Critically Ill

Author

Miller, C, Armonda, R, Le Roux, P, Menon, D, Vespa, P, Citerio, G, Bader, M, Brophy, G, Diringer, M, Stocchetti, N, Videtta, W, Badjatia, N, Boesel, J, Chesnut, R, Chou, S, Claassen, J, Czosnyka, M, De Georgia, M, Figaji, A, Fugate, J, Helbok, R, Horowitz, D, Hutchinson, P, Kumar, M, Mcnett, M, Naidech, A, Oddo, M, Olson, D, O'Phelan, K, Provencio, J, Puppo, C, Riker, R, Robertson, C, Schmidt, J, Taccone, F, Miller C., Armonda R., Le Roux P., Menon D. K., Vespa P., Citerio G., Bader M. K., Brophy G. M., Diringer M. N., Stocchetti N., Videtta W., Badjatia N., Boesel J., Chesnut R., Chou S., Claassen J., Czosnyka M., De Georgia M., Figaji A., Fugate J., Helbok R., Horowitz D., Hutchinson P., Kumar M., McNett M., Naidech A., Oddo M., Olson D., O'Phelan K., Provencio J., Puppo C., Riker R., Robertson C., Schmidt J. M., Taccone F., Miller, C, Armonda, R, Le Roux, P, Menon, D, Vespa, P, Citerio, G, Bader, M, Brophy, G, Diringer, M, Stocchetti, N, Videtta, W, Badjatia, N, Boesel, J, Chesnut, R, Chou, S, Claassen, J, Czosnyka, M, De Georgia, M, Figaji, A, Fugate, J, Helbok, R, Horowitz, D, Hutchinson, P, Kumar, M, Mcnett, M, Naidech, A, Oddo, M, Olson, D, O'Phelan, K, Provencio, J, Puppo, C, Riker, R, Robertson, C, Schmidt, J, Taccone, F, Miller C., Armonda R., Le Roux P., Menon D. K., Vespa P., Citerio G., Bader M. K., Brophy G. M., Diringer M. N., Stocchetti N., Videtta W., Badjatia N., Boesel J., Chesnut R., Chou S., Claassen J., Czosnyka M., De Georgia M., Figaji A., Fugate J., Helbok R., Horowitz D., Hutchinson P., Kumar M., McNett M., Naidech A., Oddo M., Olson D., O'Phelan K., Provencio J., Puppo C., Riker R., Robertson C., Schmidt J. M., and Taccone F.

Abstract

Secondary ischemic injury is common after acute brain injury and can be evaluated with the use of neuromonitoring devices. This manuscript provides guidelines for the use of devices to monitor cerebral blood flow (CBF) in critically ill patients. A Medline search was conducted to address essential pre-specified questions related to the utility of CBF monitoring. Peer-reviewed recommendations were constructed according to the GRADE criteria based upon the available supporting literature. Transcranial Doppler ultrasonography (TCD) and transcranial color-coded duplex sonography (TCCS) are predictive of angiographic vasospasm and delayed ischemic neurological deficits after aneurysmal subarachnoid hemorrhage. TCD and TCCS may be beneficial in identifying vasospasm after traumatic brain injury. TCD and TCCS have shortcomings in identifying some secondary ischemic risks. Implantable thermal diffusion flowmetry (TDF) probes may provide real-time continuous quantitative assessment of ischemic risks. Data are lacking regarding ischemic thresholds for TDF or their correlation with ischemic injury and clinical outcomes.TCD and TCCS can be used to monitor CBF in the neurocritical care unit. Better and more developed methods of continuous CBF monitoring are needed to limit secondary ischemic injury in the neurocritical care unit.

Published

2014

21. Intracranial Pressure Monitoring: Fundamental Considerations and Rationale for Monitoring

Author

Chesnut, R, Videtta, W, Vespa, P, Le Roux, P, Menon, D, Citerio, G, Bader, M, Brophy, G, Diringer, M, Stocchetti, N, Armonda, R, Badjatia, N, Boesel, J, Chou, S, Claassen, J, Czosnyka, M, De Georgia, M, Figaji, A, Fugate, J, Helbok, R, Horowitz, D, Hutchinson, P, Kumar, M, Mcnett, M, Miller, C, Naidech, A, Oddo, M, Olson, D, O'Phelan, K, Provencio, J, Puppo, C, Riker, R, Robertson, C, Schmidt, J, Taccone, F, Chesnut R., Videtta W., Vespa P., Le Roux P., Menon D. K., Citerio G., Bader M. K., Brophy G. M., Diringer M. N., Stocchetti N., Armonda R., Badjatia N., Boesel J., Chou S., Claassen J., Czosnyka M., De Georgia M., Figaji A., Fugate J., Helbok R., Horowitz D., Hutchinson P., Kumar M., McNett M., Miller C., Naidech A., Oddo M., Olson D., O'Phelan K., Provencio J., Puppo C., Riker R., Robertson C., Schmidt J. M., Taccone F., Chesnut, R, Videtta, W, Vespa, P, Le Roux, P, Menon, D, Citerio, G, Bader, M, Brophy, G, Diringer, M, Stocchetti, N, Armonda, R, Badjatia, N, Boesel, J, Chou, S, Claassen, J, Czosnyka, M, De Georgia, M, Figaji, A, Fugate, J, Helbok, R, Horowitz, D, Hutchinson, P, Kumar, M, Mcnett, M, Miller, C, Naidech, A, Oddo, M, Olson, D, O'Phelan, K, Provencio, J, Puppo, C, Riker, R, Robertson, C, Schmidt, J, Taccone, F, Chesnut R., Videtta W., Vespa P., Le Roux P., Menon D. K., Citerio G., Bader M. K., Brophy G. M., Diringer M. N., Stocchetti N., Armonda R., Badjatia N., Boesel J., Chou S., Claassen J., Czosnyka M., De Georgia M., Figaji A., Fugate J., Helbok R., Horowitz D., Hutchinson P., Kumar M., McNett M., Miller C., Naidech A., Oddo M., Olson D., O'Phelan K., Provencio J., Puppo C., Riker R., Robertson C., Schmidt J. M., and Taccone F.

Abstract

Traumatic brain injury (TBI) is a major cause of death and disability worldwide. In large part critical care for TBI is focused on the identification and management of secondary brain injury. This requires effective neuromonitoring that traditionally has centered on intracranial pressure (ICP). The purpose of this paper is to review the fundamental literature relative to the clinical application of ICP monitoring in TBI critical care and to provide recommendations on how the technique maybe applied to help patient management and enhance outcome. A PubMed search between 1980 and September 2013 identified 2,253 articles; 244 of which were reviewed in detail to prepare this report and the evidentiary tables. Several important concepts emerge from this review. ICP monitoring is safe and is best performed using a parenchymal monitor or ventricular catheter. While the indications for ICP monitoring are well established, there remains great variability in its use. Increased ICP, particularly the pattern of the increase and ICP refractory to treatment is associated with increased mortality. Class I evidence is lacking on how monitoring and management of ICP influences outcome. However, a large body of observational data suggests that ICP management has the potential to influence outcome, particularly when care is targeted and individualized and supplemented with data from other monitors including the clinical examination and imaging.

Published

2014

22. Monitoring of Cerebral Autoregulation

Author

Czosnyka, M, Miller, C, Le Roux, P, Menon, D, Vespa, P, Citerio, G, Bader, M, Brophy, G, Diringer, M, Stocchetti, N, Videtta, W, Armonda, R, Badjatia, N, Boesel, J, Chesnut, R, Chou, S, Claassen, J, De Georgia, M, Figaji, A, Fugate, J, Helbok, R, Horowitz, D, Hutchinson, P, Kumar, M, Mcnett, M, Naidech, A, Oddo, M, Olson, D, O'Phelan, K, Provencio, J, Puppo, C, Riker, R, Robertson, C, Schmidt, J, Taccone, F, Czosnyka M., Miller C., Le Roux P., Menon D. K., Vespa P., Citerio G., Bader M. K., Brophy G. M., Diringer M. N., Stocchetti N., Videtta W., Armonda R., Badjatia N., Boesel J., Chesnut R., Chou S., Claassen J., De Georgia M., Figaji A., Fugate J., Helbok R., Horowitz D., Hutchinson P., Kumar M., McNett M., Naidech A., Oddo M., Olson D., O'Phelan K., Provencio J., Puppo C., Riker R., Robertson C., Schmidt J. M., Taccone F., Czosnyka, M, Miller, C, Le Roux, P, Menon, D, Vespa, P, Citerio, G, Bader, M, Brophy, G, Diringer, M, Stocchetti, N, Videtta, W, Armonda, R, Badjatia, N, Boesel, J, Chesnut, R, Chou, S, Claassen, J, De Georgia, M, Figaji, A, Fugate, J, Helbok, R, Horowitz, D, Hutchinson, P, Kumar, M, Mcnett, M, Naidech, A, Oddo, M, Olson, D, O'Phelan, K, Provencio, J, Puppo, C, Riker, R, Robertson, C, Schmidt, J, Taccone, F, Czosnyka M., Miller C., Le Roux P., Menon D. K., Vespa P., Citerio G., Bader M. K., Brophy G. M., Diringer M. N., Stocchetti N., Videtta W., Armonda R., Badjatia N., Boesel J., Chesnut R., Chou S., Claassen J., De Georgia M., Figaji A., Fugate J., Helbok R., Horowitz D., Hutchinson P., Kumar M., McNett M., Naidech A., Oddo M., Olson D., O'Phelan K., Provencio J., Puppo C., Riker R., Robertson C., Schmidt J. M., and Taccone F.

Abstract

Pressure autoregulation is an important hemodynamic mechanism that protects the brain against inappropriate fluctuations in cerebral blood flow in the face of changing cerebral perfusion pressure (CPP). Static autoregulation represents how far cerebrovascular resistance changes when CPP varies, and dynamic autoregulation represents how fast these changes happen. Both have been monitored in the setting of neurocritical care to aid prognostication and contribute to individualizing CPP targets in patients. Failure of autoregulation is associated with a worse outcome in various acute neurological diseases. Several studies have used transcranial Doppler ultrasound, intracranial pressure (ICP with vascular reactivity as surrogate measure of autoregulation), and near-infrared spectroscopy to continuously monitor the impact of spontaneous fluctuations in CPP on cerebrovascular physiology and to calculate derived variables of autoregulatory efficiency. Many patients who undergo such monitoring demonstrate a range of CPP in which autoregulatory efficiency is optimal. Management of patients at or near this optimal level of CPP is associated with better outcomes in traumatic brain injury. Many of these studies have utilized the concept of the pressure reactivity index, a correlation coefficient between ICP and mean arterial pressure. While further studies are needed, these data suggest that monitoring of autoregulation could aid prognostication and may help identify optimal CPP levels in individual patients.

Published

2014

23. The International Multi-disciplinary Consensus Conference on Multimodality Monitoring: Future Directions and Emerging Technologies

Author

Vespa, P, Menon, D, Le Roux, P, Citerio, G, Bader, M, Brophy, G, Diringer, M, Stocchetti, N, Videtta, W, Armonda, R, Badjatia, N, Boesel, J, Chesnut, R, Chou, S, Claassen, J, Czosnyka, M, De Georgia, M, Figaji, A, Fugate, J, Helbok, R, Horowitz, D, Hutchinson, P, Kumar, M, Mcnett, M, Miller, C, Naidech, A, Oddo, M, Olson, D, O'Phelan, K, Provencio, J, Puppo, C, Riker, R, Robertson, C, Schmidt, J, Taccone, F, Vespa P., Menon D., Le Roux P., Citerio G., Bader M. K., Brophy G. M., Diringer M. N., Stocchetti N., Videtta W., Armonda R., Badjatia N., Boesel J., Chesnut R., Chou S., Claassen J., Czosnyka M., De Georgia M., Figaji A., Fugate J., Helbok R., Horowitz D., Hutchinson P., Kumar M., McNett M., Miller C., Naidech A., Oddo M., Olson D., O'Phelan K., Provencio J., Puppo C., Riker R., Robertson C., Schmidt J. M., Taccone F., Vespa, P, Menon, D, Le Roux, P, Citerio, G, Bader, M, Brophy, G, Diringer, M, Stocchetti, N, Videtta, W, Armonda, R, Badjatia, N, Boesel, J, Chesnut, R, Chou, S, Claassen, J, Czosnyka, M, De Georgia, M, Figaji, A, Fugate, J, Helbok, R, Horowitz, D, Hutchinson, P, Kumar, M, Mcnett, M, Miller, C, Naidech, A, Oddo, M, Olson, D, O'Phelan, K, Provencio, J, Puppo, C, Riker, R, Robertson, C, Schmidt, J, Taccone, F, Vespa P., Menon D., Le Roux P., Citerio G., Bader M. K., Brophy G. M., Diringer M. N., Stocchetti N., Videtta W., Armonda R., Badjatia N., Boesel J., Chesnut R., Chou S., Claassen J., Czosnyka M., De Georgia M., Figaji A., Fugate J., Helbok R., Horowitz D., Hutchinson P., Kumar M., McNett M., Miller C., Naidech A., Oddo M., Olson D., O'Phelan K., Provencio J., Puppo C., Riker R., Robertson C., Schmidt J. M., and Taccone F.

Abstract

Neuromonitoring has evolved rapidly in recent years and there now are many new monitors that have revealed a great deal about the ongoing pathophysiology of brain injury and coma. Further evolution will include the consolidation of multi-modality monitoring (MMM), the development of next-generation informatics tools to identify complex physiologic events and decision support tools to permit targeted individualized care. In this review, we examine future directions and emerging technologies in neuromonitoring including: (1) device development, (2) what is the current limitation(s) of MMM in its present format(s), (3) what would improve the ability of MMM to enhance neurocritical care, and (4) how do we develop evidence for use of MMM?

Published

2014

24. Intracranial Pressure and Cerebral Perfusion Pressure Monitoring in Non-TBI Patients: Special Considerations

Author

Helbok, R, Olson, D, Le Roux, P, Vespa, P, Menon, D, Citerio, G, Bader, M, Brophy, G, Diringer, M, Stocchetti, N, Videtta, W, Armonda, R, Badjatia, N, Boesel, J, Chesnut, R, Chou, S, Claassen, J, Czosnyka, M, De Georgia, M, Figaji, A, Fugate, J, Horowitz, D, Hutchinson, P, Kumar, M, Mcnett, M, Miller, C, Naidech, A, Oddo, M, O'Phelan, K, Provencio, J, Puppo, C, Riker, R, Robertson, C, Schmidt, J, Taccone, F, Helbok R., Olson D. W. M., Le Roux P. D., Vespa P., Menon D. K., Citerio G., Bader M. K., Brophy G. M., Diringer M. N., Stocchetti N., Videtta W., Armonda R., Badjatia N., Boesel J., Chesnut R., Chou S., Claassen J., Czosnyka M., De Georgia M., Figaji A., Fugate J., Horowitz D., Hutchinson P., Kumar M., McNett M., Miller C., Naidech A., Oddo M., O'Phelan K., Provencio J., Puppo C., Riker R., Robertson C., Schmidt J. M., Taccone F., Helbok, R, Olson, D, Le Roux, P, Vespa, P, Menon, D, Citerio, G, Bader, M, Brophy, G, Diringer, M, Stocchetti, N, Videtta, W, Armonda, R, Badjatia, N, Boesel, J, Chesnut, R, Chou, S, Claassen, J, Czosnyka, M, De Georgia, M, Figaji, A, Fugate, J, Horowitz, D, Hutchinson, P, Kumar, M, Mcnett, M, Miller, C, Naidech, A, Oddo, M, O'Phelan, K, Provencio, J, Puppo, C, Riker, R, Robertson, C, Schmidt, J, Taccone, F, Helbok R., Olson D. W. M., Le Roux P. D., Vespa P., Menon D. K., Citerio G., Bader M. K., Brophy G. M., Diringer M. N., Stocchetti N., Videtta W., Armonda R., Badjatia N., Boesel J., Chesnut R., Chou S., Claassen J., Czosnyka M., De Georgia M., Figaji A., Fugate J., Horowitz D., Hutchinson P., Kumar M., McNett M., Miller C., Naidech A., Oddo M., O'Phelan K., Provencio J., Puppo C., Riker R., Robertson C., Schmidt J. M., and Taccone F.

Abstract

The effect of intracranial pressure (ICP) and the role of ICP monitoring are best studied in traumatic brain injury (TBI). However, a variety of acute neurologic illnesses e.g., subarachnoid hemorrhage, intracerebral hemorrhage, ischemic stroke, meningitis/encephalitis, and select metabolic disorders, e.g., liver failure and malignant, brain tumors can affect ICP. The purpose of this paper is to review the literature about ICP monitoring in conditions other than TBI and to provide recommendations how the technique may be used in patient management. A PubMed search between 1980 and September 2013 identified 989 articles; 225 of which were reviewed in detail. The technique used to monitor ICP in non-TBI conditions is similar to that used in TBI; however, indications for ICP monitoring often are intertwined with the presence of obstructive hydrocephalus and hence the use of ventricular catheters is more frequent. Increased ICP can adversely affect outcome, particularly when it fails to respond to treatment. However, patients with elevated ICP can still have favorable outcomes. Although the influence of ICP-based care on outcome in non-TBI conditions appears less robust than in TBI, monitoring ICP and cerebral perfusion pressure can play a role in guiding therapy in select patients.

Published

2014

25. Electrophysiologic Monitoring in Acute Brain Injury

Author

Claassen, J, Vespa, P, Le Roux, P, Menon, D, Citerio, G, Bader, M, Brophy, G, Diringer, M, Stocchetti, N, Videtta, W, Armonda, R, Badjatia, N, Boesel, J, Chesnut, R, Chou, S, Czosnyka, M, De Georgia, M, Figaji, A, Fugate, J, Helbok, R, Horowitz, D, Hutchinson, P, Kumar, M, Mcnett, M, Miller, C, Naidech, A, Oddo, M, Olson, D, O'Phelan, K, Provencio, J, Puppo, C, Riker, R, Robertson, C, Schmidt, J, Taccone, F, Claassen J., Vespa P., Le Roux P., Menon D. K., Citerio G., Bader M. K., Brophy G. M., Diringer M. N., Stocchetti N., Videtta W., Armonda R., Badjatia N., Boesel J., Chesnut R., Chou S., Czosnyka M., De Georgia M., Figaji A., Fugate J., Helbok R., Horowitz D., Hutchinson P., Kumar M., McNett M., Miller C., Naidech A., Oddo M., Olson D., O'Phelan K., Provencio J., Puppo C., Riker R., Robertson C., Schmidt J. M., Taccone F., Claassen, J, Vespa, P, Le Roux, P, Menon, D, Citerio, G, Bader, M, Brophy, G, Diringer, M, Stocchetti, N, Videtta, W, Armonda, R, Badjatia, N, Boesel, J, Chesnut, R, Chou, S, Czosnyka, M, De Georgia, M, Figaji, A, Fugate, J, Helbok, R, Horowitz, D, Hutchinson, P, Kumar, M, Mcnett, M, Miller, C, Naidech, A, Oddo, M, Olson, D, O'Phelan, K, Provencio, J, Puppo, C, Riker, R, Robertson, C, Schmidt, J, Taccone, F, Claassen J., Vespa P., Le Roux P., Menon D. K., Citerio G., Bader M. K., Brophy G. M., Diringer M. N., Stocchetti N., Videtta W., Armonda R., Badjatia N., Boesel J., Chesnut R., Chou S., Czosnyka M., De Georgia M., Figaji A., Fugate J., Helbok R., Horowitz D., Hutchinson P., Kumar M., McNett M., Miller C., Naidech A., Oddo M., Olson D., O'Phelan K., Provencio J., Puppo C., Riker R., Robertson C., Schmidt J. M., and Taccone F.

Abstract

To determine the optimal use and indications of electroencephalography (EEG) in critical care management of acute brain injury (ABI). An electronic literature search was conducted for articles in English describing electrophysiological monitoring in ABI from January 1990 to August 2013. A total of 165 studies were included. EEG is a useful monitor for seizure and ischemia detection. There is a well-described role for EEG in convulsive status epilepticus and cardiac arrest (CA). Data suggest EEG should be considered in all patients with ABI and unexplained and persistent altered consciousness and in comatose intensive care unit (ICU) patients without an acute primary brain condition who have an unexplained impairment of mental status. There remain uncertainties about certain technical details, e.g., the minimum duration of EEG studies, the montage, and electrodes. Data obtained from both EEG and EP studies may help estimate prognosis in ABI patients, particularly following CA and traumatic brain injury. Data supporting these recommendations is sparse, and high quality studies are needed. EEG is used to monitor and detect seizures and ischemia in ICU patients and indications for EEG are clear for certain disease states, however, uncertainty remains on other applications.

Published

2014

26. Electrophysiologic monitoring in acute brain injury

Author

Claassen J., Vespa P., Le Roux P., Menon D. K., Citerio G., Bader M. K., Brophy G. M., Diringer M. N., Stocchetti N., Videtta W., Armonda R., Badjatia N., Boesel J., Chesnut R., Chou S., Czosnyka M., De Georgia M., Figaji A., Fugate J., Helbok R., Horowitz D., Hutchinson P., Kumar M., McNett M., Miller C., Naidech A., Oddo M., Olson D., O'Phelan K., Provencio J., Puppo C., Riker R., Robertson C., Schmidt J. M., Taccone F., Claassen, J, Vespa, P, Le Roux, P, Menon, D, Citerio, G, Bader, M, Brophy, G, Diringer, M, Stocchetti, N, Videtta, W, Armonda, R, Badjatia, N, Boesel, J, Chesnut, R, Chou, S, Czosnyka, M, De Georgia, M, Figaji, A, Fugate, J, Helbok, R, Horowitz, D, Hutchinson, P, Kumar, M, Mcnett, M, Miller, C, Naidech, A, Oddo, M, Olson, D, O'Phelan, K, Provencio, J, Puppo, C, Riker, R, Robertson, C, Schmidt, J, and Taccone, F

Subjects

medicine.medical_specialty, Neurology, Critical Care, Traumatic brain injury, Ischemia, Electroencephalography, Critical Care and Intensive Care Medicine, EEG-fMRI, law.invention, Brain Ischemia, law, Seizures, medicine, Humans, Evoked potential, medicine.diagnostic_test, business.industry, Patient Selection, medicine.disease, Intensive care unit, Heart Arrest, Bispectral index, Electroencephalography, Evoked potential, Ischemia, Prognosis, Quantitative EEG, Seizure, Bispectral index, Anesthesia, Brain Injuries, Emergency medicine, Neurology (clinical), business

Abstract

To determine the optimal use and indications of electroencephalography (EEG) in critical care management of acute brain injury (ABI). An electronic literature search was conducted for articles in English describing electrophysiological monitoring in ABI from January 1990 to August 2013. A total of 165 studies were included. EEG is a useful monitor for seizure and ischemia detection. There is a well-described role for EEG in convulsive status epilepticus and cardiac arrest (CA). Data suggest EEG should be considered in all patients with ABI and unexplained and persistent altered consciousness and in comatose intensive care unit (ICU) patients without an acute primary brain condition who have an unexplained impairment of mental status. There remain uncertainties about certain technical details, e.g., the minimum duration of EEG studies, the montage, and electrodes. Data obtained from both EEG and EP studies may help estimate prognosis in ABI patients, particularly following CA and traumatic brain injury. Data supporting these recommendations is sparse, and high quality studies are needed. EEG is used to monitor and detect seizures and ischemia in ICU patients and indications for EEG are clear for certain disease states, however, uncertainty remains on other applications.

Published

2014

27. Monitoring of brain and systemic oxygenation in neurocritical care patients

Author

Oddo M., Bosel J., Le Roux P., Menon D. K., Vespa P., Citerio G., Bader M. K., Brophy G. M., Diringer M. N., Stocchetti N., Videtta W., Armonda R., Badjatia N., Chesnut R., Chou S., Claassen J., Czosnyka M., De Georgia M., Figaji A., Fugate J., Helbok R., Horowitz D., Hutchinson P., Kumar M., McNett M., Miller C., Naidech A., Olson D., O'Phelan K., Provencio J., Puppo C., Riker R., Robertson C., Schmidt J. M., Taccone F., Oddo, M, Bosel, J, Le Roux, P, Menon, D, Vespa, P, Citerio, G, Bader, M, Brophy, G, Diringer, M, Stocchetti, N, Videtta, W, Armonda, R, Badjatia, N, Chesnut, R, Chou, S, Claassen, J, Czosnyka, M, De Georgia, M, Figaji, A, Fugate, J, Helbok, R, Horowitz, D, Hutchinson, P, Kumar, M, Mcnett, M, Miller, C, Naidech, A, Olson, D, O'Phelan, K, Provencio, J, Puppo, C, Riker, R, Robertson, C, Schmidt, J, Taccone, F, and Participants in the International Multidisciplinary Consensus Conference on Multimodality Monitoring

Subjects

medicine.medical_specialty, Neurology, Critical Care, Intracranial Pressure, business.industry, Traumatic brain injury, Neurointensive care, Reproducibility of Results, Brain Hypoxia, Oxygenation, Critical Care and Intensive Care Medicine, medicine.disease, Prognosis, Neurophysiological Monitoring, Brain oxygen, Carbon dioxide, Jugular oxygen saturation, Near-infrared spectroscopy, Neurocritical care, Systemic oxygenation, Oxygen monitoring, Intensive care, Brain Injuries, Medicine, Humans, Neurology (clinical), Oximetry, Cerebral perfusion pressure, business, Intensive care medicine

Abstract

Maintenance of adequate oxygenation is a mainstay of intensive care, however, recommendations on the safety, accuracy, and the potential clinical utility of invasive and non-invasive tools to monitor brain and systemic oxygenation in neurocritical care are lacking. A literature search was conducted for English language articles describing bedside brain and systemic oxygen monitoring in neurocritical care patients from 1980 to August 2013. Imaging techniques e.g., PET are not considered. A total of 281 studies were included, the majority described patients with traumatic brain injury (TBI). All tools for oxygen monitoring are safe. Parenchymal brain oxygen (PbtO2) monitoring is accurate to detect brain hypoxia, and it is recommended to titrate individual targets of cerebral perfusion pressure (CPP), ventilator parameters (PaCO2, PaO2), and transfusion, and to manage intracranial hypertension, in combination with ICP monitoring. SjvO2 is less accurate than PbtO2. Given limited data, NIRS is not recommended at present for adult patients who require neurocritical care. Systemic monitoring of oxygen (PaO2, SaO2, SpO2) and CO2 (PaCO2, end-tidal CO2) is recommended in patients who require neurocritical care.

Published

2014

28. Intracranial pressure monitoring: fundamental considerations and rationale for monitoring

Author

Chesnut R., Videtta W., Vespa P., Le Roux P., Menon D. K., Citerio G., Bader M. K., Brophy G. M., Diringer M. N., Stocchetti N., Armonda R., Badjatia N., Boesel J., Chou S., Claassen J., Czosnyka M., De Georgia M., Figaji A., Fugate J., Helbok R., Horowitz D., Hutchinson P., Kumar M., McNett M., Miller C., Naidech A., Oddo M., Olson D., O'Phelan K., Provencio J., Puppo C., Riker R., Robertson C., Schmidt J. M., Taccone F., Chesnut, R, Videtta, W, Vespa, P, Le Roux, P, Menon, D, Citerio, G, Bader, M, Brophy, G, Diringer, M, Stocchetti, N, Armonda, R, Badjatia, N, Boesel, J, Chou, S, Claassen, J, Czosnyka, M, De Georgia, M, Figaji, A, Fugate, J, Helbok, R, Horowitz, D, Hutchinson, P, Kumar, M, Mcnett, M, Miller, C, Naidech, A, Oddo, M, Olson, D, O'Phelan, K, Provencio, J, Puppo, C, Riker, R, Robertson, C, Schmidt, J, and Taccone, F

Subjects

medicine.medical_specialty, Neurology, Critical Care, Intracranial Pressure, Traumatic brain injury, Physical examination, Critical Care and Intensive Care Medicine, medicine, Humans, Brain injury, Cerebral perfusion pressure, Coma, Intracranial pressure, Multimodality monitoring, Cerebral perfusion pressure, Intensive care medicine, Neurophysiological Monitoring, Intracranial pressure, integumentary system, medicine.diagnostic_test, business.industry, musculoskeletal, neural, and ocular physiology, Patient Selection, medicine.disease, Prognosis, nervous system diseases, Brain Injuries, Intracranial pressure monitoring, Observational study, Neurology (clinical), business

Abstract

Traumatic brain injury (TBI) is a major cause of death and disability worldwide. In large part critical care for TBI is focused on the identification and management of secondary brain injury. This requires effective neuromonitoring that traditionally has centered on intracranial pressure (ICP). The purpose of this paper is to review the fundamental literature relative to the clinical application of ICP monitoring in TBI critical care and to provide recommendations on how the technique maybe applied to help patient management and enhance outcome. A PubMed search between 1980 and September 2013 identified 2,253 articles; 244 of which were reviewed in detail to prepare this report and the evidentiary tables. Several important concepts emerge from this review. ICP monitoring is safe and is best performed using a parenchymal monitor or ventricular catheter. While the indications for ICP monitoring are well established, there remains great variability in its use. Increased ICP, particularly the pattern of the increase and ICP refractory to treatment is associated with increased mortality. Class I evidence is lacking on how monitoring and management of ICP influences outcome. However, a large body of observational data suggests that ICP management has the potential to influence outcome, particularly when care is targeted and individualized and supplemented with data from other monitors including the clinical examination and imaging.

Published

2014

29. Multimodality monitoring consensus statement: monitoring in emerging economies

Author

Figaji A., Puppo C., Le Roux P., Menon D. K., Vespa P., Citerio G., Bader M. K., Brophy G. M., Diringer M. N., Stocchetti N., Videtta W., Armonda R., Badjatia N., Boesel J., Chesnut R., Chou S., Claassen J., Czosnyka M., De Georgia M., Fugate J., Helbok R., Horowitz D., Hutchinson P., Kumar M., McNett M., Miller C., Naidech A., Oddo M., Olson D., O'Phelan K., Provencio J., Riker R., Robertson C., Schmidt J. M., Taccone F., Figaji, A, Puppo, C, Le Roux, P, Menon, D, Vespa, P, Citerio, G, Bader, M, Brophy, G, Diringer, M, Stocchetti, N, Videtta, W, Armonda, R, Badjatia, N, Boesel, J, Chesnut, R, Chou, S, Claassen, J, Czosnyka, M, De Georgia, M, Fugate, J, Helbok, R, Horowitz, D, Hutchinson, P, Kumar, M, Mcnett, M, Miller, C, Naidech, A, Oddo, M, Olson, D, O'Phelan, K, Provencio, J, Riker, R, Robertson, C, Schmidt, J, and Taccone, F

Subjects

medicine.medical_specialty, Consensus, Critical Care, media_common.quotation_subject, Developing country, Context (language use), Critical Care and Intensive Care Medicine, Multimodality, Resource (project management), Clinical Protocols, Health care, medicine, Developing countries, Low- and middle-income countries, Multimodality monitoring, Neurocritical care, Traumatic brain injury, Humans, Quality (business), Intensive care medicine, Emerging markets, Developing Countries, media_common, business.industry, Patient Selection, Neurointensive care, medicine.disease, Neurophysiological Monitoring, Brain Injuries, Neurology (clinical), Medical emergency, business

Abstract

The burden of disease and so the need for care is often greater at hospitals in emerging economies. This is compounded by frequent restrictions in the delivery of good quality clinical care due to resource limitations. However, there is substantial heterogeneity in this economically defined group, such that advanced brain monitoring is routinely practiced at certain centers that have an interest in neurocritical care. It also must be recognized that significant heterogeneity in the delivery of neurocritical care exists even within individual high-income countries (HICs), determined by costs and level of interest. Direct comparisons of data between HICs and the group of low- and middle-income countries (LAMICs) are made difficult by differences in patient demographics, selection for ICU admission, therapies administered, and outcome assessment. Evidence suggests that potential benefits of multimodality monitoring depend on an appropriate environment and clinical expertise. There is no evidence to suggest that patients in LAMICs where such resources exist should be treated any differently to patients from HICs. The potential for outcome benefits in LAMICs is arguably greater in absolute terms because of the large burden of disease; however, the relative cost/benefit ratio of such monitoring in this setting must be viewed in context of the overall priorities in delivering health care at individual institutions.

Published

2014

30. Consensus summary statement of the International Multidisciplinary Consensus Conference on Multimodality Monitoring in Neurocritical Care

Author

Le Roux, P, Menon, D, Vespa, P, Bader, M, Brophy, G, Diringer, M, Stocchetti, N, Videtta, W, Armonda, R, Badjatia, N, Boeesel, J, Chesnut, R, Chou, S, Claassen, J, Czosnyka, M, De Georgia, M, Figaji, A, Fugate, J, Helbok, R, Horowitz, D, Hutchinson, P, Kumar, M, McNett, M, Miller, C, Naidech, A, Oddo, M, Olson, D, O'Phelan, K, Provencio, J, Puppo, C, Riker, R, Robertson, C, Schmidt, M, Taccone, F., CITERIO, GIUSEPPE, Le Roux, P, Menon, D, Citerio, G, Vespa, P, Bader, M, Brophy, G, Diringer, M, Stocchetti, N, Videtta, W, Armonda, R, Badjatia, N, Boeesel, J, Chesnut, R, Chou, S, Claassen, J, Czosnyka, M, De Georgia, M, Figaji, A, Fugate, J, Helbok, R, Horowitz, D, Hutchinson, P, Kumar, M, Mcnett, M, Miller, C, Naidech, A, Oddo, M, Olson, D, O'Phelan, K, Provencio, J, Puppo, C, Riker, R, Robertson, C, Schmidt, M, and Taccone, F

Subjects

multimodality monitoring in intensive care

Abstract

Neurocritical care depends, in part, on careful patient monitoring but as yet there are little data on what processes are the most important to monitor, how these should be monitored, and whether monitoring these processes is cost-effective and impacts outcome. At the same time, bioinformatics is a rapidly emerging field in critical care but as yet there is little agreement or standardization on what information is important and how it should be displayed and analyzed. The Neurocritical Care Society in collaboration with the European Society of Intensive Care Medicine, the Society for Critical Care Medicine, and the Latin America Brain Injury Consortium organized an international, multidisciplinary consensus conference to begin to address these needs. International experts from neurosurgery, neurocritical care, neurology, critical care, neuroanesthesiology, nursing, pharmacy, and informatics were recruited on the basis of their research, publication record, and expertise. They undertook a systematic literature review to develop recommendations about specific topics on physiologic processes important to the care of patients with disorders that require neurocritical care. This review does not make recommendations about treatment, imaging, and intraoperative monitoring. A multidisciplinary jury, selected for their expertise in clinical investigation and development of practice guidelines, guided this process. The GRADE system was used to develop recommendations based on literature review, discussion, integrating the literature with the participants' collective experience, and critical review by an impartial jury. Emphasis was placed on the principle that recommendations should be based on both data quality and on trade-offs and translation into clinical practice. Strong consideration was given to providing pragmatic guidance and recommendations for bedside neuromonitoring, even in the absence of high quality data. © 2014 Springer-Verlag and ESICM.

Published

2014

31. Monitoring of Cerebral Blood Flow and Ischemia in the Critically Ill

Author

Miller C., Armonda R., Le Roux P., Menon D. K., Vespa P., Citerio G., Bader M. K., Brophy G. M., Diringer M. N., Stocchetti N., Videtta W., Badjatia N., Boesel J., Chesnut R., Chou S., Claassen J., Czosnyka M., De Georgia M., Figaji A., Fugate J., Helbok R., Horowitz D., Hutchinson P., Kumar M., McNett M., Naidech A., Oddo M., Olson D., O'Phelan K., Provencio J., Puppo C., Riker R., Robertson C., Schmidt J. M., Taccone F., Miller, C, Armonda, R, Le Roux, P, Menon, D, Vespa, P, Citerio, G, Bader, M, Brophy, G, Diringer, M, Stocchetti, N, Videtta, W, Badjatia, N, Boesel, J, Chesnut, R, Chou, S, Claassen, J, Czosnyka, M, De Georgia, M, Figaji, A, Fugate, J, Helbok, R, Horowitz, D, Hutchinson, P, Kumar, M, Mcnett, M, Naidech, A, Oddo, M, Olson, D, O'Phelan, K, Provencio, J, Puppo, C, Riker, R, Robertson, C, Schmidt, J, and Taccone, F

Subjects

Subarachnoid hemorrhage, Critical Care, Traumatic brain injury, Ultrasonography, Doppler, Transcranial, Ischemia, Critical Care and Intensive Care Medicine, Brain Ischemia, medicine, Neurocritical care, Humans, medicine.diagnostic_test, business.industry, Neurointensive care, Transcranial Doppler, Vasospasm, Cerebral blood flow, medicine.disease, Cerebral Angiography, Thermal diffusion flowmetry, Anesthesia, Cerebrovascular Circulation, cardiovascular system, Neurology (clinical), business, Rheology, Cerebral angiography, Multimodality monitoring

Abstract

Secondary ischemic injury is common after acute brain injury and can be evaluated with the use of neuromonitoring devices. This manuscript provides guidelines for the use of devices to monitor cerebral blood flow (CBF) in critically ill patients. A Medline search was conducted to address essential pre-specified questions related to the utility of CBF monitoring. Peer-reviewed recommendations were constructed according to the GRADE criteria based upon the available supporting literature. Transcranial Doppler ultrasonography (TCD) and transcranial color-coded duplex sonography (TCCS) are predictive of angiographic vasospasm and delayed ischemic neurological deficits after aneurysmal subarachnoid hemorrhage. TCD and TCCS may be beneficial in identifying vasospasm after traumatic brain injury. TCD and TCCS have shortcomings in identifying some secondary ischemic risks. Implantable thermal diffusion flowmetry (TDF) probes may provide real-time continuous quantitative assessment of ischemic risks. Data are lacking regarding ischemic thresholds for TDF or their correlation with ischemic injury and clinical outcomes.TCD and TCCS can be used to monitor CBF in the neurocritical care unit. Better and more developed methods of continuous CBF monitoring are needed to limit secondary ischemic injury in the neurocritical care unit.

Published

2014

32. Clinical Monitoring Scales in Acute Brain Injury: Assessment of Coma, Pain, Agitation, and Delirium

Author

Riker R. R., Fugate J. E., Le Roux P., Menon D. K., Vespa P., Citerio G., Bader M. K., Brophy G. M., Diringer M. N., Stocchetti N., Videtta W., Armonda R., Badjatia N., Boesel J., Chesnut R., Chou S., Claassen J., Czosnyka M., De Georgia M., Figaji A., Helbok R., Horowitz D., Hutchinson P., Kumar M., McNett M., Miller C., Naidech A., Oddo M., Olson D., O'Phelan K., Provencio J., Puppo C., Robertson C., Schmidt J. M., Taccone F., Riker, R, Fugate, J, Le Roux, P, Menon, D, Vespa, P, Citerio, G, Bader, M, Brophy, G, Diringer, M, Stocchetti, N, Videtta, W, Armonda, R, Badjatia, N, Boesel, J, Chesnut, R, Chou, S, Claassen, J, Czosnyka, M, De Georgia, M, Figaji, A, Helbok, R, Horowitz, D, Hutchinson, P, Kumar, M, Mcnett, M, Miller, C, Naidech, A, Oddo, M, Olson, D, O'Phelan, K, Provencio, J, Puppo, C, Robertson, C, Schmidt, J, and Taccone, F

Subjects

medicine.medical_specialty, Neurology, Critical Care, Sedation, Pain, Disorders of consciousness, Critical Care and Intensive Care Medicine, medicine, Humans, Coma, Intensive care medicine, Psychomotor Agitation, Coma, Delirium, Neurologic examination, Pain, Scale, Sedation, Neurologic Examination, Trauma Severity Indices, business.industry, Glasgow Coma Scale, Neurointensive care, Delirium, Reproducibility of Results, Pain scale, medicine.disease, Anesthesia, Brain Injuries, Neurology (clinical), medicine.symptom, business

Abstract

Serial clinical examination represents the most fundamental and basic form of neurological monitoring, and is often the first and only form of such monitoring in patients. Even in patients subjected to physiological monitoring using a range of technologies, the clinical examination remains an essential tool to follow neurological progress. Key aspects of the clinical examination have now been systematized into scoring schemes, and address consciousness, pain, agitation, and delirium (PAD). The Glasgow Coma Scale has been the traditional tool to measure consciousness, but the full outline of unresponsiveness (FOUR) score has recently been validated in a variety of settings, and at present, both represent clinically useful tools. Assessment of PAD in neurologically compromised patients present special challenges. For pain, the Numeric Rating Scale is the preferred initial approach, with either the Behavioral Pain Scale or the Critical Care Pain Observation Tool in subjects who are not able to respond. The Nociception Coma Scale-Revised may be useful in patients with severe disorders of consciousness. Conventional sedation scoring tools for critical care, such as the Richmond Area Sedation Scale (RASS) and Sedation–Agitation Scale (SAS) may provide reasonable tools in some neurocritical care patients. The use of sedative drugs and neuromuscular blockers may invalidate the use of some clinical examination tools in others. The use of sedation interruption to assess neurological status can result in physiological derangement in unstable patients (such as those with uncontrolled intracranial hypertension), and is not recommended.

Published

2014

33. Monitoring of Cerebral Autoregulation

Author

Czosnyka M., Miller C., Le Roux P., Menon D. K., Vespa P., Citerio G., Bader M. K., Brophy G. M., Diringer M. N., Stocchetti N., Videtta W., Armonda R., Badjatia N., Boesel J., Chesnut R., Chou S., Claassen J., De Georgia M., Figaji A., Fugate J., Helbok R., Horowitz D., Hutchinson P., Kumar M., McNett M., Naidech A., Oddo M., Olson D., O'Phelan K., Provencio J., Puppo C., Riker R., Robertson C., Schmidt J. M., Taccone F., Czosnyka, M, Miller, C, Le Roux, P, Menon, D, Vespa, P, Citerio, G, Bader, M, Brophy, G, Diringer, M, Stocchetti, N, Videtta, W, Armonda, R, Badjatia, N, Boesel, J, Chesnut, R, Chou, S, Claassen, J, De Georgia, M, Figaji, A, Fugate, J, Helbok, R, Horowitz, D, Hutchinson, P, Kumar, M, Mcnett, M, Naidech, A, Oddo, M, Olson, D, O'Phelan, K, Provencio, J, Puppo, C, Riker, R, Robertson, C, Schmidt, J, and Taccone, F

Subjects

Mean arterial pressure, Critical Care, Intracranial Pressure, Traumatic brain injury, business.industry, musculoskeletal, neural, and ocular physiology, Autoregulation, Cerebral blood flow, Cerebral perfusion pressure, Near-infrared spectroscopy, Pressure reactivity, Transcranial doppler ultrasound, Prognosis, Critical Care and Intensive Care Medicine, medicine.disease, Neurophysiological Monitoring, Cerebral autoregulation, Transcranial Doppler, Cerebral blood flow, Brain Injuries, Cerebrovascular Circulation, Anesthesia, medicine, Homeostasis, Humans, Autoregulation, Neurology (clinical), Cerebral perfusion pressure, business, Intracranial pressure

Abstract

Pressure autoregulation is an important hemodynamic mechanism that protects the brain against inappropriate fluctuations in cerebral blood flow in the face of changing cerebral perfusion pressure (CPP). Static autoregulation represents how far cerebrovascular resistance changes when CPP varies, and dynamic autoregulation represents how fast these changes happen. Both have been monitored in the setting of neurocritical care to aid prognostication and contribute to individualizing CPP targets in patients. Failure of autoregulation is associated with a worse outcome in various acute neurological diseases. Several studies have used transcranial Doppler ultrasound, intracranial pressure (ICP with vascular reactivity as surrogate measure of autoregulation), and near-infrared spectroscopy to continuously monitor the impact of spontaneous fluctuations in CPP on cerebrovascular physiology and to calculate derived variables of autoregulatory efficiency. Many patients who undergo such monitoring demonstrate a range of CPP in which autoregulatory efficiency is optimal. Management of patients at or near this optimal level of CPP is associated with better outcomes in traumatic brain injury. Many of these studies have utilized the concept of the pressure reactivity index, a correlation coefficient between ICP and mean arterial pressure. While further studies are needed, these data suggest that monitoring of autoregulation could aid prognostication and may help identify optimal CPP levels in individual patients.

Published

2014

34. International Multidisciplinary Consensus Conference on Multimodality Monitoring: Cerebral Metabolism

Author

Hutchinson P., O'Phelan K., Le Roux P., Menon D. K., Vespa P., Citerio G., Bader M. K., Brophy G. M., Diringer M. N., Stocchetti N., Videtta W., Armonda R., Badjatia N., Boesel J., Chesnut R., Chou S., Claassen J., Czosnyka M., De Georgia M., Figaji A., Fugate J., Helbok R., Horowitz D., Kumar M., McNett M., Miller C., Naidech A., Oddo M., Olson D., Provencio J., Puppo C., Riker R., Robertson C., Schmidt J. M., Taccone F., Hutchinson, P, O'Phelan, K, Le Roux, P, Menon, D, Vespa, P, Citerio, G, Bader, M, Brophy, G, Diringer, M, Stocchetti, N, Videtta, W, Armonda, R, Badjatia, N, Boesel, J, Chesnut, R, Chou, S, Claassen, J, Czosnyka, M, De Georgia, M, Figaji, A, Fugate, J, Helbok, R, Horowitz, D, Kumar, M, Mcnett, M, Miller, C, Naidech, A, Oddo, M, Olson, D, Provencio, J, Puppo, C, Riker, R, Robertson, C, Schmidt, J, and Taccone, F

Subjects

Microdialysis, medicine.medical_specialty, Subarachnoid hemorrhage, Neurology, Consensus, Critical Care, Traumatic brain injury, Critical Care and Intensive Care Medicine, Multidisciplinary approach, medicine, Humans, Intensive care medicine, Intracerebral hemorrhage, Intention-to-treat analysis, business.industry, Glucose, Glutamate, Intracerebral hemorrhage, Lactate, Lactate pyruvate ratio, Microdialysis, Subarachnoid hemorrhage, Traumatic brain injury, Neurointensive care, Brain, Subarachnoid Hemorrhage, medicine.disease, Neurophysiological Monitoring, Brain Injuries, Neurology (clinical), business, Biomarkers

Abstract

Microdialysis is a powerful technique, which enables the chemistry of the extracellular space to be measured directly. Applying this technique to patients in neurointensive care has increased our understanding of the pathophysiology of traumatic brain injury and spontaneous hemorrhage. In parallel, it is important to determine the place of microdialysis in assisting in the management of patients on an individual intention to treat basis. This is made possible by the availability of analyzers which can measure the concentration of glucose, pyruvate, lactate, and glutamate at the bedside. Samples can then be stored for later analysis of other substrate and metabolites e.g., other amino acids and cytokines. The objective of this paper is to review the fundamental literature pertinent to the clinical application of microdialysis in neurointensive care and to give recommendations on how the technique can be applied to assist in patient management and contribute to outcome. A literature search detected 1,933 publications of which 55 were used for data abstraction and analysis. The role of microdialysis was evaluated in three conditions (traumatic brain injury, subarachnoid hemorrhage, and intracerebral hemorrhage) and recommendations focused on three fundamental areas (relationship to outcome, application of microdialysis to guide therapy, and the ability of microdialysis to predict secondary deterioration).

Published

2014

35. The International Multidisciplinary Consensus Conference on Multimodality Monitoring in Neurocritical Care: Evidentiary Tables : A Statement for Healthcare Professionals from the Neurocritical Care Society and the European Society of Intensive Care Medicine

Author

Le Roux, P, Menon, D, Citerio, G, Vespa, P, Bader, M, Brophy, G, Diringer, M, Stocchetti, N, Videtta, W, Armonda, R, Badjatia, N, Bösel, J, Chesnut, R, Chou, S, Claassen, J, Czosnyka, M, De Georgia, M, Figaji, A, Fugate, J, Helbok, R, Horowitz, D, Hutchinson, P, Kumar, M, Mcnett, M, Miller, C, Naidech, A, Oddo, M, Olson, D, O'Phelan, K, Javier Provencio, J, Puppo, C, Riker, R, Roberson, C, Schmidt, M, Taccone, F, McNett, M, Taccone, F., CITERIO, GIUSEPPE, Le Roux, P, Menon, D, Citerio, G, Vespa, P, Bader, M, Brophy, G, Diringer, M, Stocchetti, N, Videtta, W, Armonda, R, Badjatia, N, Bösel, J, Chesnut, R, Chou, S, Claassen, J, Czosnyka, M, De Georgia, M, Figaji, A, Fugate, J, Helbok, R, Horowitz, D, Hutchinson, P, Kumar, M, Mcnett, M, Miller, C, Naidech, A, Oddo, M, Olson, D, O'Phelan, K, Javier Provencio, J, Puppo, C, Riker, R, Roberson, C, Schmidt, M, Taccone, F, McNett, M, Taccone, F., and CITERIO, GIUSEPPE

Abstract

A variety of technologies have been developed to assist decision-making during the management of patients with acute brain injury who require intensive care. A large body of research has been generated describing these various technologies. The Neurocritical Care Society (NCS) in collaboration with the European Society of Intensive Care Medicine (ESICM), the Society for Critical Care Medicine (SCCM), and the Latin America Brain Injury Consortium (LABIC) organized an international, multidisciplinary consensus conference to perform a systematic review of the published literature to help develop evidence-based practice recommendations on bedside physiologic monitoring. This supplement contains a Consensus Summary Statement with recommendations and individual topic reviews on physiologic processes important in the care of acute brain injury. In this article we provide the evidentiary tables for select topics including systemic hemodynamics, intracranial pressure, brain and systemic oxygenation, EEG, brain metabolism, biomarkers, processes of care and monitoring in emerging economies to provide the clinician ready access to evidence that supports recommendations about neuromonitoring.

Published

2014

36. Consensus Summary Statement of the International Multidisciplinary Consensus Conference on Multimodality Monitoring in Neurocritical Care : A statement for healthcare professionals from the Neurocritical Care Society and the European Society of Intensive Care Medicine

Author

Le Roux, P, Menon, D, Citerio, G, Vespa, P, Bader, M, Brophy, G, Diringer, M, Stocchetti, N, Videtta, W, Armonda, R, Badjatia, N, Böesel, J, Chesnut, R, Chou, S, Claassen, J, Czosnyka, M, De Georgia, M, Figaji, A, Fugate, J, Helbok, R, Horowitz, D, Hutchinson, P, Kumar, M, Mcnett, M, Miller, C, Naidech, A, Oddo, M, Olson, D, O'Phelan, K, Provencio, J, Puppo, C, Riker, R, Robertson, C, Schmidt, M, Taccone, F, CITERIO, GIUSEPPE, McNett, M, Taccone, F., Le Roux, P, Menon, D, Citerio, G, Vespa, P, Bader, M, Brophy, G, Diringer, M, Stocchetti, N, Videtta, W, Armonda, R, Badjatia, N, Böesel, J, Chesnut, R, Chou, S, Claassen, J, Czosnyka, M, De Georgia, M, Figaji, A, Fugate, J, Helbok, R, Horowitz, D, Hutchinson, P, Kumar, M, Mcnett, M, Miller, C, Naidech, A, Oddo, M, Olson, D, O'Phelan, K, Provencio, J, Puppo, C, Riker, R, Robertson, C, Schmidt, M, Taccone, F, CITERIO, GIUSEPPE, McNett, M, and Taccone, F.

Abstract

Neurocritical care depends, in part, on careful patient monitoring but as yet there are little data on what processes are the most important to monitor, how these should be monitored, and whether monitoring these processes is cost-effective and impacts outcome. At the same time, bioinformatics is a rapidly emerging field in critical care but as yet there is little agreement or standardization on what information is important and how it should be displayed and analyzed. The Neurocritical Care Society in collaboration with the European Society of Intensive Care Medicine, the Society for Critical Care Medicine, and the Latin America Brain Injury Consortium organized an international, multidisciplinary consensus conference to begin to address these needs. International experts from neurosurgery, neurocritical care, neurology, critical care, neuroanesthesiology, nursing, pharmacy, and informatics were recruited on the basis of their research, publication record, and expertise. They undertook a systematic literature review to develop recommendations about specific topics on physiologic processes important to the care of patients with disorders that require neurocritical care. This review does not make recommendations about treatment, imaging, and intraoperative monitoring. A multidisciplinary jury, selected for their expertise in clinical investigation and development of practice guidelines, guided this process. The GRADE system was used to develop recommendations based on literature review, discussion, integrating the literature with the participants' collective experience, and critical review by an impartial jury. Emphasis was placed on the principle that recommendations should be based on both data quality and on trade-offs and translation into clinical practice. Strong consideration was given to providing pragmatic guidance and recommendations for bedside neuromonitoring, even in the absence of high quality data.

Published

2014

37. The International Multidisciplinary Consensus Conference on Multimodality Monitoring in Neurocritical Care: A List of Recommendations and Additional Conclusions: A Statement for Healthcare Professionals From the Neurocritical Care Society and the European Society of Intensive Care Medicine

Author

Le Roux, P, Menon, D, Citerio, G, Vespa, P, Bader, M, Brophy, G, Diringer, M, Stocchetti, N, Videtta, W, Armonda, R, Badjatia, N, Bösel, J, Chesnut, R, Chou, S, Claassen, J, Czosnyka, M, De Georgia, M, Figaji, A, Fugate, J, Helbok, R, Horowitz, D, Hutchinson, P, Kumar, M, Mcnett, M, Miller, C, Naidech, A, Oddo, M, Olson, D, O’Phelan, K, Provencio, J, Puppo, C, Riker, R, Roberson, C, Schmidt, M, Taccone, F, McNett, M, Le Roux, P, Menon, D, Citerio, G, Vespa, P, Bader, M, Brophy, G, Diringer, M, Stocchetti, N, Videtta, W, Armonda, R, Badjatia, N, Bösel, J, Chesnut, R, Chou, S, Claassen, J, Czosnyka, M, De Georgia, M, Figaji, A, Fugate, J, Helbok, R, Horowitz, D, Hutchinson, P, Kumar, M, Mcnett, M, Miller, C, Naidech, A, Oddo, M, Olson, D, O’Phelan, K, Provencio, J, Puppo, C, Riker, R, Roberson, C, Schmidt, M, Taccone, F, and McNett, M

Abstract

Careful patient monitoring using a variety of techniques including clinical and laboratory evaluation, bedside physiological monitoring with continuous or non-continuous techniques and imaging is fundamental to the care of patients who require neurocritical care. How best to perform and use bedside monitoring is still being elucidated. To create a basic platform for care and a foundation for further research the Neurocritical Care Society in collaboration with the European Society of Intensive Care Medicine, the Society for Critical Care Medicine and the Latin America Brain Injury Consortium organized an international, multidisciplinary consensus conference to develop recommendations about physiologic bedside monitoring. This supplement contains a Consensus Summary Statement with recommendations and individual topic reviews as a background to the recommendations. In this article, we highlight the recommendations and provide additional conclusions as an aid to the reader and to facilitate bedside care.

Published

2014

38. Acute seizures after intracerebral hemorrhage: a factor in progressive midline shift and outcome.

Author

Vespa PM, O'Phelan K, Shah M, Mirabelli J, Starkman S, Kidwell C, Saver J, Nuwer MR, Frazee JG, McArthur DA, Martin NA, Vespa, P M, O'Phelan, K, Shah, M, Mirabelli, J, Starkman, S, Kidwell, C, Saver, J, Nuwer, M R, and Frazee, J G

Published

2003

39. Surfers' myelopathy: A case series of 19 novice surfers with nontraumatic myelopathy

Author

Chang, C. W. J., primary, Donovan, D. J., additional, Liem, L. K., additional, O'Phelan, K. H., additional, Green, D. M., additional, Bassin, S., additional, and Asai, S., additional

Published

2012

40. Pericontusional brain tissue exhibits persistent elevation of lactate/pyruvate ratio independent of cerebral perfusion pressure.

Author

Vespa PM, O'Phelan K, McArthur D, Miller C, Eliseo M, Hirt D, Glenn T, and Hovda DA

Abstract

Objective: To determine whether pericontusional tissue exhibits neurochemical responsiveness to changes in cerebral perfusion pressure as measured by microdialysis lactate/pyruvate ratio.Design: Prospective monitoring with retrospective data analysis.Setting: Single-center academic neurologic intensive care unit.Patients: Twenty-one patients with severe traumatic brain injury (Glasgow Coma Scale score 3-8).Interventions: None.Measurements and Main Results: Cerebral microdialysis was performed for the initial 7 days after traumatic brain injury. Thirteen patients had microdialysis probes in normal tissue and eight had two probes, one of which was located in pericontusional tissue. Retrospective analysis was performed to determine if microdialysis levels in pericontusional tissue demonstrates higher levels of lactate/pyruvate ratio than normal tissue and if lactate/pyruvate ratio increased with reductions in cerebral perfusion pressure. Univariate analysis revealed higher values for glutamate and lactate/pyruvate ratio in pericontusional tissue compared with normal tissue. However, based on the mixed-effects model analysis, the percent time of elevated lactate/pyruvate ratio was significantly higher in pericontusional tissue (40 +/- 59% vs. 17 +/- 37%, p < .05), and the mean lactate/pyruvate ratio values showed only a trend relationship (62 +/- 134 vs. 34 +/- 78, p < .06). When examined by cerebral perfusion pressure threshold, cerebral perfusion pressure <60 mm Hg was not associated with higher lactate/pyruvate ratio values in normal or pericontusional tissue. In addition, no single cerebral perfusion pressure threshold was associated with a significant reduction in lactate/pyruvate ratio in either pericontusional or normal tissue (p < .08).Conclusions: Sustained increases in lactate/pyruvate ratio occurred more frequently in pericontusional tissue compared with normal brain tissue. The lactate/pyruvate ratio was not related to cerebral perfusion pressure, nor was the percent time-burden of elevated lactate/pyruvate ratio related to any particular sustained cerebral perfusion pressure threshold. Lactate/pyruvate ratio values appear to be elevated despite cerebral perfusion pressure values customarily considered to be adequate. [ABSTRACT FROM AUTHOR]

Published

2007

41. The International Multidisciplinary Consensus Conference on Multimodality Monitoring in Neurocritical Care: Evidentiary Tables

Author

Paul M. Vespa, Gretchen M. Brophy, Michael N. Diringer, J. Javier Provencio, Monisha A. Kumar, Andrew M. Naidech, Corinna Puppo, Peter J. Hutchinson, Randall M. Chesnut, Mauro Oddo, Jennifer E. Fugate, Michael De Georgia, Chad Miller, Peter D. Le Roux, Sherry Chou, Jan Claassen, Mary Kay Bader, Fabio Silvio Taccone, Richard R. Riker, Julian Bösel, David K. Menon, Rocco A. Armonda, Michael Schmidt, Raimund Helbok, Marek Czosnyka, Nino Stocchetti, Molly McNett, DaiWai W. Olson, Kristine O’Phelan, Giuseppe Citerio, Neeraj Badjatia, Anthony Figaji, Walter Videtta, David A. Horowitz, Claudia Roberson, Le Roux, P, Menon, D, Citerio, G, Vespa, P, Bader, M, Brophy, G, Diringer, M, Stocchetti, N, Videtta, W, Armonda, R, Badjatia, N, Bösel, J, Chesnut, R, Chou, S, Claassen, J, Czosnyka, M, De Georgia, M, Figaji, A, Fugate, J, Helbok, R, Horowitz, D, Hutchinson, P, Kumar, M, Mcnett, M, Miller, C, Naidech, A, Oddo, M, Olson, D, O'Phelan, K, Javier Provencio, J, Puppo, C, Riker, R, Roberson, C, Schmidt, M, and Taccone, F

Subjects

Research design, medicine.medical_specialty, Consensus, Evidence-Based Medicine, Internationality, Critical Care, business.industry, Data Collection, MEDLINE, Neurointensive care, Evidence-based medicine, Neuromonitoring, Critical Care and Intensive Care Medicine, Neurophysiological Monitoring, Clinical trial, Research Design, Multidisciplinary approach, Intensive care, medicine, Humans, Neurology (clinical), Intensive care medicine, business, Societies, Medical

Abstract

A variety of technologies have been developed to assist decision-making during the management of patients with acute brain injury who require intensive care. A large body of research has been generated describing these various technologies. The Neurocritical Care Society (NCS) in collaboration with the European Society of Intensive Care Medicine (ESICM), the Society for Critical Care Medicine (SCCM), and the Latin America Brain Injury Consortium (LABIC) organized an international, multidisciplinary consensus conference to perform a systematic review of the published literature to help develop evidence-based practice recommendations on bedside physiologic monitoring. This supplement contains a Consensus Summary Statement with recommendations and individual topic reviews on physiologic processes important in the care of acute brain injury. In this article we provide the evidentiary tables for select topics including systemic hemodynamics, intracranial pressure, brain and systemic oxygenation, EEG, brain metabolism, biomarkers, processes of care and monitoring in emerging economies to provide the clinician ready access to evidence that supports recommendations about neuromonitoring.

Published

2014

42. Consensus Summary Statement of the International Multidisciplinary Consensus Conference on Multimodality Monitoring in Neurocritical Care

Author

Peter Hutchinson, Julian J. Böesel, Gretchen M. Brophy, Michael N. Diringer, Nino Stocchetti, Kristine O’Phelan, Anthony A. Figaji, Walter Videtta, Monisha A. Kumar, Peter D. Le Roux, Neeraj Badjatia, David A. Horowitz, Michael Schmidt, Chad Miller, Paul M. Vespa, J. Javier Provencio, Sherry Chou, Giuseppe Citerio, Raimund Helbok, Marek Czosnyka, Michael De Georgia, Mauro Oddo, DaiWai M. Olson, Mary Kay Bader, Molly McNett, Randall M. Chesnut, Corinna Puppo, Fabio Silvio Taccone, Jan Claassen, Richard R. Riker, Rocco Armonda, David K. Menon, Claudia S. Robertson, Andrew M. Naidech, Jennifer E. Fugate, Le Roux, P, Menon, D, Citerio, G, Vespa, P, Bader, M, Brophy, G, Diringer, M, Stocchetti, N, Videtta, W, Armonda, R, Badjatia, N, Böesel, J, Chesnut, R, Chou, S, Claassen, J, Czosnyka, M, De Georgia, M, Figaji, A, Fugate, J, Helbok, R, Horowitz, D, Hutchinson, P, Kumar, M, Mcnett, M, Miller, C, Naidech, A, Oddo, M, Olson, D, O'Phelan, K, Provencio, J, Puppo, C, Riker, R, Robertson, C, Schmidt, M, and Taccone, F

Subjects

medicine.medical_specialty, Consensus, Intracranial Pressure, Critical Care, Standardization, Health Personnel, MEDLINE, Pharmacy, Critical Care and Intensive Care Medicine, Severity of Illness Index, Electrocardiography, Multidisciplinary approach, medicine, Humans, Oximetry, Intensive care medicine, Societies, Medical, Monitoring, Physiologic, Brain Diseases, Trauma Severity Indices, business.industry, Consensus Conference on Multimodality Monitoring in Neurocritical Care, Neurointensive care, Electroencephalography, Neurophysiological Monitoring, Systematic review, Informatics, Data quality, Neurology (clinical), Nervous System Diseases, business, Biomarkers

Abstract

Neurocritical care depends, in part, on careful patient monitoring but as yet there are little data on what processes are the most important to monitor, how these should be monitored, and whether monitoring these processes is cost-effective and impacts outcome. At the same time, bioinformatics is a rapidly emerging field in critical care but as yet there is little agreement or standardization on what information is important and how it should be displayed and analyzed. The Neurocritical Care Society in collaboration with the European Society of Intensive Care Medicine, the Society for Critical Care Medicine, and the Latin America Brain Injury Consortium organized an international, multidisciplinary consensus conference to begin to address these needs. International experts from neurosurgery, neurocritical care, neurology, critical care, neuroanesthesiology, nursing, pharmacy, and informatics were recruited on the basis of their research, publication record, and expertise. They undertook a systematic literature review to develop recommendations about specific topics on physiologic processes important to the care of patients with disorders that require neurocritical care. This review does not make recommendations about treatment, imaging, and intraoperative monitoring. A multidisciplinary jury, selected for their expertise in clinical investigation and development of practice guidelines, guided this process. The GRADE system was used to develop recommendations based on literature review, discussion, integrating the literature with the participants' collective experience, and critical review by an impartial jury. Emphasis was placed on the principle that recommendations should be based on both data quality and on trade-offs and translation into clinical practice. Strong consideration was given to providing pragmatic guidance and recommendations for bedside neuromonitoring, even in the absence of high quality data.

Published

2014

43. Global monitoring in the neurocritical care unit

Author

David Tirschwell, MCCOY STEPHEN ELI, Halinder Mangat, Stephen Figueroa, DaiWai Olson, David Seder, Giuseppe Citerio, J. Michael Schmidt, Sarah Livesay, Olson, D, Andrew Kofke, W, O'Phelan, K, Gupta, P, Figueroa, S, Smirnakis, S, Leroux, P, Suarez, J, and Citerio, G

Subjects

medicine.medical_specialty, Brain Diseases, Critical Care, business.industry, Less invasive, Neurointensive care, Brain monitoring, Critical Care and Intensive Care Medicine, medicine.disease, Neurophysiological Monitoring, Unit (housing), Electrophysiology, Intracranial pressure, Neurocritical care, Neuroimaging, Neuromonitoring, Neuroprotection, medicine, Intracranial pressure monitoring, Humans, Neurology (clinical), Medical emergency, State of the science, Intensive care medicine, business

Abstract

Effective methods of monitoring the status of patients with neurological injuries began with non-invasive observations and evolved during the past several decades to include more invasive monitoring tools and physiologic measures. The monitoring paradigm continues to evolve, this time back toward the use of less invasive tools. In parallel, the science of monitoring began with the global assessment of the patient’s neurological condition, evolved to focus on regional monitoring techniques, and with the advent of enhanced computing capabilities is now moving back to focus on global monitoring. The purpose of this session of the Second Neurocritical Care Research Conference was to collaboratively develop a comprehensive understanding of the state of the science for global brain monitoring and to identify research priorities for intracranial pressure monitoring, neuroimaging, and neuro-electrophysiology monitoring.

Published

2015

44. The International Multidisciplinary Consensus Conference on Multimodality Monitoring in Neurocritical Care: a list of recommendations and additional conclusions: a statement for healthcare professionals from the Neurocritical Care Society and the European Society of Intensive Care Medicine

Author

Kristine O’Phelan, Neeraj Badjatia, Walter Videtta, Gretchen M. Brophy, Fabio Silvio Taccone, Rocco Armonda, David A. Horowitz, Claudia Roberson, Michael N. Diringer, Monisha A. Kumar, Molly McNett, Anthony Figaji, Jan Claassen, Giuseppe Citerio, Chad Miller, Corinna Puppo, Richard R. Riker, David K. Menon, Mauro Oddo, Paul M. Vespa, Sherry Chou, Jennifer E. Fugate, Randall M. Chesnut, Peter J. Hutchinson, Peter D. Le Roux, J. Javier Provencio, Andrew M. Naidech, Michael De Georgia, Mary Kay Bader, Julian Bösel, Nino Stocchetti, Michael Schmidt, Raimund Helbok, Marek Czosnyka, DaiWai W. Olson, Le Roux, P, Menon, D, Citerio, G, Vespa, P, Bader, M, Brophy, G, Diringer, M, Stocchetti, N, Videtta, W, Armonda, R, Badjatia, N, Bösel, J, Chesnut, R, Chou, S, Claassen, J, Czosnyka, M, De Georgia, M, Figaji, A, Fugate, J, Helbok, R, Horowitz, D, Hutchinson, P, Kumar, M, Mcnett, M, Miller, C, Naidech, A, Oddo, M, Olson, D, O’Phelan, K, Provencio, J, Puppo, C, Riker, R, Roberson, C, Schmidt, M, and Taccone, F

Subjects

medicine.medical_specialty, Consensus, Internationality, Critical Care, Intracranial Pressure, Bio-informatic, Remote patient monitoring, Point-of-Care Systems, MEDLINE, Neuromonitoring, Critical Care and Intensive Care Medicine, Article, Multimodality, Brain metabolism, Brain oxygen, Traumatic brain injury, Clinical Protocols, Multidisciplinary approach, Grading of recommendations assessment development and evaluation (GRADE), Neurocritical care, medicine, Humans, Intensive care medicine, Clinical guideline, Neurophysiological Monitoring, Brain physiology, Societies, Medical, Statement (computer science), business.industry, Patient Selection, Neurointensive care, Electroencephalography, Biomarker, Clinical trial, Multimodal monitoring, Consensus development conference, Microdialysi, Brain Injuries, Cerebrovascular Circulation, Neurology (clinical), Blood Gas Analysis, business

Abstract

Careful patient monitoring using a variety of techniques including clinical and laboratory evaluation, bedside physiological monitoring with continuous or non-continuous techniques and imaging is fundamental to the care of patients who require neurocritical care. How best to perform and use bedside monitoring is still being elucidated. To create a basic platform for care and a foundation for further research the Neurocritical Care Society in collaboration with the European Society of Intensive Care Medicine, the Society for Critical Care Medicine and the Latin America Brain Injury Consortium organized an international, multidisciplinary consensus conference to develop recommendations about physiologic bedside monitoring. This supplement contains a Consensus Summary Statement with recommendations and individual topic reviews as a background to the recommendations. In this article, we highlight the recommendations and provide additional conclusions as an aid to the reader and to facilitate bedside care.

Published

2014

45. Implementing a Bedside Percutaneous Tracheostomy and Ultrasound Gastrostomy Team Reduces Length of Stay and Hospital Costs Across Multiple Critical Care Units in a 1500 Bed Tertiary Care Center.

Author

Houghton D, Patel S, Gerasim S, Buryk Y, Massad N, Alkhachroum A, Atallah HY, and O'Phelan K

Abstract

Background: Thousands of critically ill patients every year in the United States receive tracheostomy and gastrostomy procedures. Recent research has investigated the benefits of a combined team approach to these procedures, with associated decreases in length of stay (LOS) and hospital costs. This study's objective was to determine if implementing a bedside percutaneous tracheostomy and percutaneous ultrasound gastrostomy (PUG) team would reduce LOS and hospital costs. Design and Methods: This retrospective chart review compares the impact of implementing an ICU bedside percutaneous tracheostomy and PUG service team to the hospital's previous workflow (ie, pre-implementation). Inclusion criteria were adult patients with Ventilator Dependent Respiratory Failure (VDRF), a clinical indication for both procedures while admitted to the ICU and received both tracheostomy and gastrostomy procedures while admitted to the hospital. Pre- and post-implementation groups were compared across patients' demographics, clinical characteristics, and outcomes. ICU LOS, hospital LOS and total hospital costs were the primary outcome measures. Results: A total of 101 adult critically ill patients were included in the analysis; 49 patients were in the pre-implementation group and 52 patients in the post-implementation group (ie, PUG group). Patients in the PUG group had a significantly shorter mean ICU LOS and hospital LOS, 10.9- and 14.7-day reductions respectively (p = 0.010, p = 0.006). PUG group patients also had a significant reduction in total hospital costs, a per patient cost savings of $34 778 (p = 0.043). Conclusions: This study supports implementing a bedside percutaneous tracheostomy and PUG team to reduce LOS and total hospital costs in patients with VDRF., Competing Interests: Declaration of Conflicting InterestsThe author(s) disclosed receipt of the following financial support for the research, authorship, and/or publication of this article: This work was partially supported by CoapTech, Inc. to Jackson Health System to cover IRB fees and time and effort for Drs. Atallah and Patel to complete data collection activities. No other author(s) received financial support for the research, authorship, and/or publication of this article.

Published

2024

46. Resting-State EEG Signature of Early Consciousness Recovery in Comatose Patients with Traumatic Brain Injury.

Author

Alkhachroum A, Fló E, Manolovitz B, Cohan H, Shammassian B, Bass D, Aklepi G, Monexe E, Ghamasaee P, Sobczak E, Samano D, Saavedra AB, Massad N, Kottapally M, Merenda A, Cordeiro JG, Jagid J, Kanner AM, Rundek T, O'Phelan K, Claassen J, and Sitt JD

Abstract

Background: Resting-state electroencephalography (rsEEG) is usually obtained to assess seizures in comatose patients with traumatic brain injury (TBI). We aim to investigate rsEEG measures and their prediction of early recovery of consciousness in patients with TBI., Methods: This is a retrospective study of comatose patients with TBI who were admitted to a trauma center (October 2013 to January 2022). Demographics, basic clinical data, imaging characteristics, and EEGs were collected. We calculated the following using 10-min rsEEGs: power spectral density, permutation entropy (complexity measure), weighted symbolic mutual information (wSMI, global information sharing measure), Kolmogorov complexity (Kolcom, complexity measure), and heart-evoked potentials (the averaged EEG signal relative to the corresponding QRS complex on electrocardiography). We evaluated the prediction of consciousness recovery before hospital discharge using clinical, imaging, and rsEEG data via a support vector machine., Results: We studied 113 of 134 (84%) patients with rsEEGs. A total of 73 (65%) patients recovered consciousness before discharge. Patients who recovered consciousness were younger (40 vs. 50 years, p = 0.01). Patients who recovered also had higher Kolcom (U = 1688, p = 0.01), increased beta power (U = 1,652 p = 0.003) with higher variability across channels (U = 1534, p = 0.034) and epochs (U = 1711, p = 0.004), lower delta power (U = 981, p = 0.04), and higher connectivity across time and channels as measured by wSMI in the theta band (U = 1636, p = 0.026; U = 1639, p = 0.024) than those who did not recover. The area under the receiver operating characteristic curve for rsEEG was higher than that for clinical data (using age, motor response, pupil reactivity) and higher than that for the Marshall computed tomography classification (0.69 vs. 0.66 vs. 0.56, respectively; p < 0.001)., Conclusions: We describe the rsEEG signature in recovery of consciousness prior to discharge in comatose patients with TBI. rsEEG measures performed modestly better than the clinical and imaging data in predicting recovery., (© 2024. Springer Science+Business Media, LLC, part of Springer Nature and Neurocritical Care Society.)

Published

2024

47. Resting-State EEG Signature of Early Consciousness Recovery in Comatose Traumatic Brain Injury Patients.

Author

Alkhachroum A, Flo E, Manolovitz B, Stradecki-Cohan HM, Shammassian B, Bass D, Aklepi G, Monexe E, Ghamasaee P, Sobczak E, Samano D, Saavedra AB, Massad N, Kottapally M, Merenda A, Cordeiro JG, Jagid J, Kanner AM, Rundek T, O'Phelan K, Claassen J, and Sitt J

Abstract

Background Resting-state electroencephalogram (rsEEG) is usually obtained to assess seizures in comatose patients with traumatic brain injury (TBI) patients. We aim to investigate rsEEG measures and their prediction of early recovery of consciousness in comatose TBI patients. Methods This is a retrospective study of comatose TBI patients who were admitted to a level-1 trauma center (10/2013-1/2022). Demographics, basic clinical data, imaging characteristics, and EEG data were collected. We calculated using 10-minute rsEEGs: power spectral density (PSD), permutation entropy (PE - complexity measure), weighted symbolic-mutual-information (wSMI - global information sharing measure), Kolmogorov complexity (Kolcom - complexity measure), and heart-evoked potentials (HEP - the averaged EEG signal relative to the corresponding QRS complex on electrocardiogram). We evaluated the prediction of consciousness recovery before hospital discharge using clinical, imaging, rsEEG data via Support Vector Machine with a linear kernel (SVM). Results We studied 113 (out of 134, 84%) patients with rsEEGs. A total of 73 (65%) patients recovered consciousness before discharge. Patients who recovered consciousness were younger (40 vs. 50, p .01). Patients who recovered consciousness had higher Kolcom (U = 1688, p = 0.01,), increased beta power (U = 1652 p = 0.003), with higher variability across channels ( U = 1534, p = 0.034), and epochs (U = 1711, p = 0.004), lower delta power (U = 981, p = 0.04) and showed higher connectivity across time and channels as measured by wSMI in the theta band (U = 1636, p = .026, U = 1639, p = 0.024) than those who didn't recover. The ROC-AUC improved from 0.66 (using age, motor response, pupils' reactivity, and CT Marshall classification) to 0.69 (p < 0.001) when adding rsEEG measures. Conclusion We describe the rsEEG EEG signature in recovery of consciousness prior to discharge in comatose TBI patients. Resting-state EEG measures improved prediction beyond the clinical and imaging data.

Published

2024

48. Covert Tracking to Visual Stimuli in Comatose Patients With Traumatic Brain Injury.

Author

Alkhachroum A, Aklepi G, Sarafraz A, Robayo LE, Manolovitz BM, Blandino CF, Arwari B, Sobczak E, Bass DH, Ghamasaee P, Samano D, Massad N, Kottapally M, Merenda A, Dib S, Jagid JR, Dietrich WD, Rundek T, O'Phelan K, Claassen J, and Walker MF

Subjects

Humans, Consciousness physiology, Prognosis, Physical Examination, Coma etiology, Brain Injuries, Traumatic complications

Abstract

Objectives: This study investigated video eye tracking (VET) in comatose patients with traumatic brain injury (TBI)., Methods: We recruited healthy participants and unresponsive patients with TBI. We surveyed the patients' clinicians on whether the patient was tracking and performed the Coma Recovery Scale-Revised (CRS-R). We recorded eye movements in response to motion of a finger, a face, a mirror, and an optokinetic stimulus using VET glasses. Patients were classified as covert tracking (tracking on VET alone) and overt tracking (VET and clinical examination). The ability to obey commands was evaluated at 6-month follow-up., Results: We recruited 20 healthy participants and 10 patients with TBI. The use of VET was feasible in all participants and patients. Two patients demonstrated covert tracking (CRS-R of 6 and 8), 2 demonstrated overt tracking (CRS-R of 22 and 11), and 6 patients had no tracking (CRS-R of 8, 6, 5, 7, 6, and 7). Five of 56 (9%) tracking assessments were missed on clinical examination. All patients with tracking recovered consciousness at follow-up, whereas only 2 of 6 patients without tracking recovered at follow-up., Discussion: VET is a feasible method to measure covert tracking. Future studies are needed to confirm the prognostic value of covert tracking., (© 2023 American Academy of Neurology.)

Published

2023

49. Predictors and Temporal Trends of Withdrawal of Life-Sustaining Therapy After Acute Stroke in the Florida Stroke Registry.

Author

Alkhachroum A, Zhou L, Asdaghi N, Gardener H, Ying H, Gutierrez CM, Manolovitz BM, Samano D, Bass D, Foster D, Sur NB, Rose DZ, Jameson A, Massad N, Kottapally M, Merenda A, Starke RM, O'Phelan K, Romano JG, Claassen J, Sacco RL, and Rundek T

Abstract

Temporal trends and factors associated with the withdrawal of life-sustaining therapy (WLST) after acute stroke are not well determined., Design: Observational study (2008-2021)., Setting: Florida Stroke Registry (152 hospitals)., Patients: Acute ischemic stroke (AIS), intracerebral hemorrhage (ICH), and subarachnoid hemorrhage (SAH) patients., Interventions: None., Measurements and Main Results: Importance plots were performed to generate the most predictive factors of WLST. Area under the curve (AUC) for the receiver operating curve were generated for the performance of logistic regression (LR) and random forest (RF) models. Regression analysis was applied to evaluate temporal trends. Among 309,393 AIS patients, 47,485 ICH patients, and 16,694 SAH patients; 9%, 28%, and 19% subsequently had WLST. Patients who had WLST were older (77 vs 70 yr), more women (57% vs 49%), White (76% vs 67%), with greater stroke severity on the National Institutes of Health Stroke Scale greater than or equal to 5 (29% vs 19%), more likely hospitalized in comprehensive stroke centers (52% vs 44%), had Medicare insurance (53% vs 44%), and more likely to have impaired level of consciousness (38% vs 12%). Most predictors associated with the decision to WLST in AIS were age, stroke severity, region, insurance status, center type, race, and level of consciousness (RF AUC of 0.93 and LR AUC of 0.85). Predictors in ICH included age, impaired level of consciousness, region, race, insurance status, center type, and prestroke ambulation status (RF AUC of 0.76 and LR AUC of 0.71). Factors in SAH included age, impaired level of consciousness, region, insurance status, race, and stroke center type (RF AUC of 0.82 and LR AUC of 0.72). Despite a decrease in the rates of early WLST (< 2 d) and mortality, the overall rates of WLST remained stable., Conclusions: In acute hospitalized stroke patients in Florida, factors other than brain injury alone contribute to the decision to WLST. Potential predictors not measured in this study include education, culture, faith and beliefs, and patient/family and physician preferences. The overall rates of WLST have not changed in the last 2 decades., Competing Interests: This work represents the author’s independent analysis of local or multicenter data gathered using the American Heart Association (AHA) Get With The Guidelines (GWTG) Patient Management Tool/IQVIA Registry Platform but is not an analysis of the national GWTG dataset and does not represent findings from the AHA GWTG National Program. Dr. Alkhachroum is supported by an institutional KL2 Career Development Award from the Miami Clinical and Translational Science Institute (CTSI) National Center for Advancing Translational Sciences (NCATS) UL1TR002736 and by the National Institute of Neurological Disorders and Stroke of the National Institutes of Health (NIH) under Award Number K23NS126577 and R21NS128326. He is a junior editor for Journal of Clinical and Translational Science. Dr. Asdaghi is supported by salary support from the Florida Stroke Registry (FSR) COHAN-A1 R2 contract. Dr. Sur is supported by an institutional KL2 Career Development Award from the Miami CTSI NCATS KL2TR002737, the Florida Department of Health for work on the FSR. Dr. Sur serves as CME/Highlights Editor for journal Stroke and is on the editorial board for the Journal of the American College of Cardiology: Advances. Dr. Starke is supported by supported by the Neurosurgery Research & Education Foundation, Joe Niekro Foundation, Brain Aneurysm Foundation, Bee Foundation, Department of Health Biomedical Research Grant (21K02AWD-007000) and by the NIH (R01NS111119-01A1) and (UL1TR002736, KL2TR002737) through the Miami CTSI, from the NCATS and the National Institute on Minority Health and Health Disparities. Its contents are solely the responsibility of the authors and do not necessarily represent the official views of the NIH. Dr. Starke has an unrestricted research grant from Medtronic and Balt and has consulting and teaching agreements with Penumbra, Abbott, Medtronic, Balt, InNeuroCo, Cerenovus, Naglreiter, Tonbridge, Von Medical, and Optimize Vascular. Dr. Romano is supported by grant funding from the NIH R01 MD012467 and U24 NS107267. Dr. Claassen is supported by grant funding from the NIH R01 NS106014, R03 NS112760, R21 NS128326, and the Dana Foundation. Dr. Claassen is a minority shareholder at iCE Neurosystems. Dr. Sacco is funded by the Florida Department of Health for work on the FSR and by grants from the NIH (R01 NS029993, R01 MD012467, R01 NS040807, U10NS086528), and the NCATS (UL1 TR002736 and KL2 TR002737) and receives compensation from the AHA as Editor-In-Chief of Stroke. Dr. Rundek is funded by the Florida Department of Health for work on the FSR and by the grants from the NIH (R01 MD012467, R01 NS029993, R01 NS040807, and 1U24 NS107267), and the NCATS (UL1 TR002736 and KL2 TR002737). The remaining authors have not disclosed any potential conflicts of interest., (Copyright © 2023 The Authors. Published by Wolters Kluwer Health, Inc. on behalf of the Society of Critical Care Medicine.)

Published

2023

50. Posttraumatic Stress Symptoms Among COVID-19 Survivors After Hospitalization.

Author

Sobczak E, Swafford EP, Samano D, Bass D, Ghamasaee P, Kottapally M, Merenda A, O'Phelan K, Romano JG, Sacco RL, Rundek T, and Alkhachroum A

Subjects

Humans, Female, Middle Aged, Aged, Male, Aftercare, Patient Discharge, Survivors psychology, Stress Disorders, Post-Traumatic epidemiology, Stress Disorders, Post-Traumatic etiology, Stress Disorders, Post-Traumatic diagnosis, COVID-19 epidemiology, COVID-19 complications

Abstract

Objective: Limited data are available on posttraumatic stress symptoms (PTSS) among COVID-19 survivors. This study aimed to contribute to this knowledge base., Methods: PTSS among COVID-19 survivors who had been hospitalized were investigated. Patients were identified as COVID-19 positive at hospital admission. COVID-19 survivors were surveyed with the Posttraumatic Stress Disorder Checklist (PCL-5) between March and October 2020 at 5- and 12-month postdischarge follow-up points., Results: Of 411 patients, 331 (81%) survived to hospital discharge. Of these survivors, 83 (25%) completed the PCL-5 at the 5-month follow-up. Of those patients, 12 (14%) screened positive for PTSS. At the 12-month follow-up, four of eight patients remained PTSS positive. Mean age of follow-up participants was 62±15 years; 47% were women, 65% were White, and 63% were Hispanic. PTSS-positive patients were predominantly non-White (67% vs. 30%, p=0.02), and although the differences were not statistically significant, these patients tended to be younger (56 vs. 63 years, p=0.08) and have shorter intensive care unit stays (2.0 vs. 12.5 days, p=0.06). PTSS-positive and PTSS-negative groups did not differ significantly in prehospitalization neurological diagnoses (11% vs. 8%), psychiatric diagnoses (17% vs. 21%), and intensive care admission status (25% vs. 25%). More patients in the PTSS-positive group had returned to the emergency department (50% vs. 14%, p<0.01) and reported fatigue at follow-up (100% vs. 42%, p<0.001). In the multivariate logistic regression model, non-White race (OR=11, 95% CI=2-91) and returning to the emergency department (OR=19, 95% CI=3-252) were associated with PTSS-positive status., Conclusion: PTSS were twice as common among hospitalized COVID-19 survivors than among those in the general population., Competing Interests: Dr. Romano has received funding from Genentech. Dr. Sacco has received personal compensation from the American Heart Association for his role as editor-in-chief of Stroke. The other authors report no financial relationships with commercial interests.

Published

2023