Your search keyword '"Puppo, C."' showing total 18 results

1. 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 DK, Citerio G, Vespa P, Bader MK, Brophy G, Diringer MN, 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 JJ, Puppo C, Riker R, Roberson C, Schmidt M, and Taccone F

Subjects

Blood Gas Analysis, Brain Injuries therapy, Cerebrovascular Circulation physiology, Clinical Protocols, Consensus, Electroencephalography, Humans, Internationality, Intracranial Pressure physiology, Patient Selection, Point-of-Care Systems, Societies, Medical, Brain Injuries diagnosis, Brain Injuries physiopathology, Critical Care, Neurophysiological Monitoring

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

2. Multimodality monitoring consensus statement: monitoring in emerging economies.

Author

Figaji A and Puppo C

Subjects

Brain Injuries therapy, Clinical Protocols, Consensus, Humans, Patient Selection, Brain Injuries diagnosis, Brain Injuries physiopathology, Critical Care, Developing Countries, Neurophysiological Monitoring

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

3. Bedside study of cerebral critical closing pressure in patients with severe traumatic brain injury: a transcranial Doppler study.

Author

Puppo C, Camacho J, Yelicich B, Moraes L, Biestro A, and Gomez H

Subjects

Adolescent, Adult, Blood Flow Velocity physiology, Brain Injuries surgery, Decompressive Craniectomy methods, Female, Humans, Male, Middle Aged, Statistics as Topic, Young Adult, Blood Pressure physiology, Brain Injuries diagnostic imaging, Brain Injuries physiopathology, Echocardiography, Doppler, Intracranial Pressure physiology

Abstract

Objective: Cerebral critical closing pressure (CrCP) is the arterial pressure (AP) below which small arterial cerebral vessels collapse. Our objective was to estimate cerebral CrCP in 12 severe TBI patients, relating transcranial Doppler flow velocity (FV) and AP data., Methods: FV, intracranial pressure (ICP) and invasive AP were prospectively acquired at 50 Hz. CrCP was estimated using three methods (M): M(1): amplitude ratio of FV/AP first harmonics; M(2): AP axis intersection of the regression line between systolic and diastolic values of FV and AP; M(3): AP axis intersection of the regression line between decreasing AP and FV simultaneous values., Results: There were 12 patients. Frequent negative CrCP values were found. Average M(1):-12 mmHg; M(2):-33 mmHg; M(3):-43 mmHg. Correlation between the three methods was significant (P < 0.01). M(1) showed the lowest range and more positive values. The better limits of agreement (Bland and Altman test) were between M(2) and M(3)., Conclusions: The frequently found negative values do not allow us for the moment, to use any of these three methods for clinical guidance.

Published

2012

4. One-minute dynamic cerebral autoregulation in severe head injury patients and its comparison with static autoregulation. A transcranial Doppler study.

Author

Puppo C, López L, Caragna E, and Biestro A

Subjects

Adolescent, Adult, Blood Pressure physiology, Female, Humans, Hyperemia diagnostic imaging, Hyperemia physiopathology, Intracranial Pressure physiology, Male, Middle Aged, Time Factors, Trauma Severity Indices, Vasodilation physiology, Brain Injuries diagnostic imaging, Brain Injuries physiopathology, Cerebrovascular Circulation physiology, Homeostasis physiology, Ultrasonography, Doppler, Transcranial

Abstract

Objective: To compare dynamic and static responses of cerebral blood flow to sudden or slow changes in arterial pressure in severe traumatic brain injury (TBI) patients., Design: Prospective study., Patients and Methods: We studied 12 severe TBI patients, age 16-63 years, and median GCS 6. We determined the dynamic cerebral autoregulation: response of cerebral blood flow velocity to a step blood pressure drop, and the static cerebral autoregulation: change in cerebral blood flow velocity after a slow hypertensive challenge., Results: During the dynamic response, the median drop in arterial pressure was 21 mm Hg. Dynamic response was graded between 9 (best) and 0 (worst). The median value was 5; four patients showed high values, (8-9), five patients showed intermediate values (4-6). In three patients (value = 0), the CBFV drop was greater than the cerebral perfusion pressure drop, and maintained through 60 s. The static cerebral autoregulation was preserved in 6/11 patients. The comparison between the two showed four different combinations. The five patients with impaired static cerebral autoregulation showed unfavorable outcome., Conclusions: A sharp dynamic vasodilator response could not be sustained, and a slow or absent reaction to a sudden hypotensive challenge could show an acceptable cerebral autoregulation in the steady state. We found that patients with impaired static cerebral autoregulation had a poor outcome, whereas those with preserved static cerebral autoregulation experience favorable outcomes.

Published

2008

5. Indomethacin and cerebral autoregulation in severe head injured patients: a transcranial Doppler study.

Author

Puppo C, Lopez L, Farina G, Caragna E, Moraes L, Iturralde A, and Biestro A

Subjects

Adolescent, Adult, Blood Flow Velocity drug effects, Blood Pressure drug effects, Brain Injuries diagnostic imaging, Female, Humans, Male, Middle Aged, Prospective Studies, Ultrasonography, Doppler, Transcranial, Anti-Inflammatory Agents, Non-Steroidal pharmacology, Brain Injuries physiopathology, Cerebrovascular Circulation drug effects, Homeostasis drug effects, Indomethacin pharmacology, Intracranial Pressure drug effects

Abstract

Objective: To assess the effect of indomethacin on cerebral autoregulation, systemic and cerebral haemodynamics, in severe head trauma patients., Design: Prospective, controlled clinical trial, with repeated measurements., Settings: A 12-bed adult general intensive care unit in a third level referral university hospital., Patients: 16 severely head injured patients, 14 males, age range 17-60., Interventions: Indomethacin was administrated as a load plus continuous infusion. Indomethacin reactivity was assessed as the estimated cerebral blood flow change elicited by the load. Dynamic and static cerebral autoregulation tests were performed before indomethacin administration, and during its infusion., Measurements and Main Results: Systemic and cerebral haemodynamic changes were assessed through continuous monitoring of mean arterial pressure, transcranial Doppler cerebral blood flow velocity, intracranial pressure, cerebral perfusion pressure, and jugular venous oxygen saturation. Indomethacin loading dose was immediately followed by a cerebral blood flow median decrease of 36 or 29% (p = ns) evaluated by two different methods, by an ICP decrease and by an AVDO(2) increase from 3.52 to 6.15 mL/dL (p = 0.002). Dynamic autoregulation increased from a median of 28 to 57% (p<0.05) during indomethacin infusion; static autoregulation also increased, from a median of 72 to 89% (p = ns)., Conclusions: Indomethacin decreased intracranial pressure and cerebral blood flow, and increased cerebral perfusion pressure, while maintaining tissue properties of further extracting O(2). The increase in both autoregulatory values reveals an enhancement of cerebral microvasculature reactivity under indomethacin, during hypertensive and--especially--during hypotensive situations.

Published

2007

6. Hypothermia.

Author

Sahuquillo J, Biestro A, and Puppo C

Subjects

Clinical Trials as Topic, Humans, Intracranial Hypertension etiology, Patient Selection, Prognosis, Time Factors, Brain Injuries complications, Hypothermia, Induced methods, Intracranial Hypertension therapy

Published

2004

7. Use of indomethacin in brain-injured patients with cerebral perfusion pressure impairment: preliminary report.

Author

Biestro AA, Alberti RA, Soca AE, Cancela M, Puppo CB, and Borovich B

Subjects

Adolescent, Adult, Blood Pressure, Body Temperature drug effects, Carbon Dioxide administration & dosage, Carbon Dioxide therapeutic use, Child, Cyclooxygenase Inhibitors administration & dosage, Female, Glasgow Coma Scale, Humans, Hyperventilation, Indomethacin administration & dosage, Infusions, Intravenous, Injections, Intravenous, Intracranial Pressure drug effects, Male, Mannitol administration & dosage, Mannitol therapeutic use, Rectum, Subarachnoid Hemorrhage drug therapy, Thiopental administration & dosage, Thiopental therapeutic use, Brain Injuries drug therapy, Cerebrovascular Circulation drug effects, Cyclooxygenase Inhibitors therapeutic use, Indomethacin therapeutic use, Pseudotumor Cerebri drug therapy

Abstract

The effect of indomethacin, a cyclooxygenase inhibitor, was studied in the treatment of 10 patients with head injury and one patient with spontaneous subarachnoid hemorrhage, each of whom presented with high intracranial pressure (ICP) (34.4 +/- 13.1 mm Hg) and cerebral perfusion pressure (CPP) impairment (67.0 +/- 15.4 mm Hg), which did not improve with standard therapy using mannitol, hyperventilation, and barbiturates. The patient had Glasgow Coma Scale scores of 8 or less. Recordings were made of the patients' ICP and mean arterial blood pressure from the nurse's end-hour recording at the bedside, as well as of their CPP, rectal temperature, and standard therapy regimens. The authors assessed the effects of an indomethacin bolus (50 mg in 20 minutes) on ICP and CPP; an indomethacin infusion (21.5 +/- 11 mg/hour over 30 +/- 9 hours) on ICP, CPP, rectal temperature, and standard therapy regimens (matching the values before and during infusion in a similar time interval); and discontinuation of indomethacin treatment on ICP, CPP, and rectal temperature. The indomethacin bolus was very effective in lowering ICP (p < 0.0005) and improving CPP (p < 0.006). The indomethacin infusion decreased ICP (p < 0.02), but did not improve CPP and rectal temperature. The effects of standard therapy regimens before and during indomethacin infusion showed no significant changes, except in three patients in whom mannitol reestablished its action on ICP and CPP. Sudden discontinuation of indomethacin treatment was followed by significant ICP rebound. The authors suggest that indomethacin may be considered one of the frontline agents for raised ICP and CPP impairment.

Published

1995

8. 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

9. 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

10. 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

11. 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

12. 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

13. 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

14. 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

15. 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

16. 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

17. Cerebral Critical Closing Pressure: Is the Multiparameter Model Better Suited to Estimate Physiology of Cerebral Hemodynamics?

Author

Puppo, C., Camacho, J., Varsos, G., Yelicich, B., Gómez, H., Moraes, L., Biestro, A., Czosnyka, M., Varsos, G V, and Gómez, H

Subjects

*INTRACRANIAL pressure, *BLOOD pressure, *BRAIN injuries, *BLOOD flow measurement, *HOSPITAL care

Abstract

Background: Cerebral critical closing pressure (CrCP) is the level of arterial blood pressure (ABP) at which small brain vessels close and blood flow stops. This value is always greater than intracranial pressure (ICP). The difference between CrCP and ICP is explained by the tone of the small cerebral vessels (wall tension). CrCP value is used in several dynamic cerebral autoregulation models. However, the different methods for calculation of CrCP show frequent negative values. These findings are viewed as a methodological limitation. We intended to evaluate CrCP in patients with severe traumatic brain injury (TBI) with a new multiparameter impedance-based model and compare it with results found earlier using a transcranial Doppler (TCD)-ABP pulse waveform-based method.Methods: Twelve severe TBI patients hospitalized during September 2005-May 2007. Ten men, mean age 32 years (16-61). Four had decompressive craniectomies (DC); three presented anisocoria. Patients were monitored with TCD cerebral blood flow velocity (FV), invasive ABP, and ICP. Data were acquired at 50 Hz with an in-house developed data acquisition system. We compared the earlier studied "first harmonic" method (M1) results with results from a new recently developed (M2) "multiparameter method."Results: M1: In seven patients CrCP values were negative, reaching -150 mmHg. M2: All positive values; only one lower than ICP (ICP 60 mmHg/ CrCP 57 mmHg). There was a significant difference between M1 and M2 values (M1 < M2) and between ICP and M2 (M2 > ICP).Conclusion: M2 results in positive values of CrCP, higher than ICP, and are physiologically interpretable. [ABSTRACT FROM AUTHOR]

Published

2016

18. 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