Search

Your search keyword '"Fleck, Brian W."' showing total 25 results
Start Over Author "Fleck, Brian W." Publication Year Range Last 10 years
25 results on '"Fleck, Brian W."'

1. P Score: A Reference Image-Based Clinical Grading Scale for Vascular Change in Retinopathy of Prematurity

Author

Chiang, Michael F., Quinn, Graham E., Fielder, Alistair R., Ostmo, Susan R., Chan, R. V. Paul, Berrocal, Audina, Binenbaum, Gil, Blair, Michael, Campbell, J. Peter, Capone, Antonio, Jr., Chen, Yi, Dai, Shuan, Ells, Anna, Fleck, Brian W., Good, William V., Hartnett, M. Elizabeth, Holmstrom, Gerd, Kusaka, Shunji, Kychenthal, Andrés, Lepore, Domenico, Lorenz, Birgit, Martinez-Castellanos, Maria Ana, O¨zdek, Şengu¨l, Ademola-Popoola, Dupe, Reynolds, James D., Shah, Parag K., Shapiro, Michael, Stahl, Andreas, Toth, Cynthia, Vinekar, Anand, Visser, Linda, Wallace, David K., Wu, Wei-Chi, Zhao, Peiquan, Zin, Andrea, Baran, Francine, Barry, Gerard, Bhatt, Amit, Davitt, Bradley, de Alba Campomanes, Alejandra, Eldib, Amgad, Geddie, Brooke E., Haider, Kathryn, Jensen, Anne, Khitri, Monica, Pihlblad, Matthew, Repka, Michael, Robbins, Shira, Rodriguez, Sarah, Coyner, Aaron S., He, Jocelyn, Ying, Gui-shuang, and Ostmo, Susan

Published
2024
Full Text
View/download PDF

7. UK screening and treatment of retinopathy of prematurity Updated 2022 Guidelines

Author

Wilkinson, A.R., primary, Adams, G.G.W., additional, Fleck, B.W., additional, Nieto-Hernandez, R., additional, Adams, Gillian, additional, Anderson, Josie, additional, Allen, Louise, additional, Bezalel, Debbie, additional, Biswas, Susmito, additional, Fielder, Alistair, additional, Flanagan, Julie, additional, Fleck, Brian W., additional, Foot, Barny, additional, Husain, Shahid, additional, Jackson, Charlotte, additional, Lahorgue, Eleanor, additional, Mactier, Helen, additional, McElroy, Helen, additional, Narayanan, Sankara, additional, Nieto-Hernandez, Rosa, additional, Oddie, Sam, additional, Parsi, Catherine, additional, Patel, C.K., additional, Pilling, Rachel, additional, Ray, Sagarika, additional, Shafiq, Ayad, additional, Soe, Aung, additional, Da Camara, Nishanthi Talawila, additional, and Wilkinson, Andrew R., additional

Published
2023
Full Text
View/download PDF

10. International Classification of Retinopathy of Prematurity, Third Edition

Author

Chiang, Michael F., primary, Quinn, Graham E., additional, Fielder, Alistair R., additional, Ostmo, Susan R., additional, Paul Chan, R.V., additional, Berrocal, Audina, additional, Binenbaum, Gil, additional, Blair, Michael, additional, Peter Campbell, J., additional, Capone, Antonio, additional, Chen, Yi, additional, Dai, Shuan, additional, Ells, Anna, additional, Fleck, Brian W., additional, Good, William V., additional, Hartnett, M. Elizabeth, additional, Holmstrom, Gerd, additional, Kusaka, Shunji, additional, Kychenthal, Andrés, additional, Lepore, Domenico, additional, Lorenz, Birgit, additional, Martinez-Castellanos, Maria Ana, additional, Özdek, Şengül, additional, Ademola-Popoola, Dupe, additional, Reynolds, James D., additional, Shah, Parag K., additional, Shapiro, Michael, additional, Stahl, Andreas, additional, Toth, Cynthia, additional, Vinekar, Anand, additional, Visser, Linda, additional, Wallace, David K., additional, Wu, Wei-Chi, additional, Zhao, Peiquan, additional, and Zin, Andrea, additional

Published
2021
Full Text
View/download PDF

12. International Classification of Retinopathy of Prematurity, Third Edition

Author

Chiang, Michael F., Quinn, Graham E., Fielder, Alistair R., Ostmo, Susan R., Chan, R. V. Paul, Berrocal, Audina, Binenbaum, Gil, Blair, Michael, Campbell, J. Peter, Capone, Antonio, Chen, Yi, Dai, Shuan, Ells, Anna, Fleck, Brian W., Good, William V., Hartnett, M. Elizabeth, Holmström, Gerd, Kusaka, Shunji, Kychenthal, Andres, Lepore, Domenico, Lorenz, Birgit, Martinez-Castellanos, Maria Ana, Ozdek, Sengul, Ademola-Popoola, Dupe, Reynolds, James D., Shah, Parag K., Shapiro, Michael, Stahl, Andreas, Toth, Cynthia, Vinekar, Anand, Visser, Linda, Wallace, David K., Wu, Wei-Chi, Zhao, Peiquan, Zin, Andrea, Chiang, Michael F., Quinn, Graham E., Fielder, Alistair R., Ostmo, Susan R., Chan, R. V. Paul, Berrocal, Audina, Binenbaum, Gil, Blair, Michael, Campbell, J. Peter, Capone, Antonio, Chen, Yi, Dai, Shuan, Ells, Anna, Fleck, Brian W., Good, William V., Hartnett, M. Elizabeth, Holmström, Gerd, Kusaka, Shunji, Kychenthal, Andres, Lepore, Domenico, Lorenz, Birgit, Martinez-Castellanos, Maria Ana, Ozdek, Sengul, Ademola-Popoola, Dupe, Reynolds, James D., Shah, Parag K., Shapiro, Michael, Stahl, Andreas, Toth, Cynthia, Vinekar, Anand, Visser, Linda, Wallace, David K., Wu, Wei-Chi, Zhao, Peiquan, and Zin, Andrea

Abstract

Purpose: The International Classification of Retinopathy of Prematurity is a consensus statement that creates a standard nomenclature for classification of retinopathy of prematurity (ROP). It was initially published in 1984, expanded in 1987, and revisited in 2005. This article presents a third revision, the International Classification of Retinopathy of Prematurity, Third Edition (ICROP3), which is now required because of challenges such as: (1) concerns about subjectivity in critical elements of disease classification; (2) innovations in ophthalmic imaging; (3) novel pharmacologic therapies (e.g., antievascular endothelial growth factor agents) with unique regression and reactivation features after treatment compared with ablative therapies; and (4) recognition that patterns of ROP in some regions of the world do not fit neatly into the current classification system. Design: Review of evidence-based literature, along with expert consensus opinion. Participants: International ROP expert committee assembled in March 2019 representing 17 countries and comprising 14 pediatric ophthalmologists and 20 retinal specialists, as well as 12 women and 22 men. Methods: The committee was initially divided into 3 subcommittees-acute phase, regression or reactivation, and imaging-each of which used iterative videoconferences and an online message board to identify key challenges and approaches. Subsequently, the entire committee used iterative videoconferences, 2 in-person multiday meetings, and an online message board to develop consensus on classification. Main Outcome Measures: Consensus statement. Results: The ICROP3 retains current definitions such as zone (location of disease), stage (appearance of disease at the avascular-vascular junction), and circumferential extent of disease. Major updates in the ICROP3 include refined classification metrics (e.g., posterior zone II, notch, subcategorization of stage 5, and recognition that a continuous spectrum of vascular abnormalit

Published
2021
Full Text
View/download PDF

15. Retinal Haemorrhages in Childhood Encephalopathies: Review of a Prospective Research Programme.

Author

Minns, Robert A., Jones, Patricia A., Fleck, Brian W., and Mulvihill, Alan O.

Subjects
HEAD injury complications, INTENSIVE care units, STATISTICS, SCIENTIFIC observation, CHILD abuse, EYE hemorrhage, PATIENTS, CEREBRAL anoxia-ischemia, PEDIATRICS, MANN Whitney U Test, HOSPITAL admission & discharge, INTRACRANIAL pressure, DOCUMENTATION, T-test (Statistics), SYMPTOMS, KAPLAN-Meier estimator, DATA analysis software, DATA analysis, LOGISTIC regression analysis, LONGITUDINAL method, CHILDREN
Abstract

One important cause of retinal haemorrhages (RHs) in children is abusive head trauma (AHT). Our programme of research was conducted on children admitted to hospital over a seven‐year period who had RHs as part of their clinical presentation. This paper summarises important findings from previous publications. As a prerequisite, two basic studies were necessary: (i) a method of reporting the precise location of the RH in the retina; and (ii) defining a simple clinical classification of RHs based on the appearance of the retinal layer involved. Because raised intracranial pressure (RICP) is a frequent secondary brain insult following serious adult head injury, causing hypoxic‐ischaemic injury with a resultant poor outcome, it was considered whether such RICP might also cause RHs in children. Detailed, state‐of‐the‐art monitoring methods were used to investigate this relationship along with retinal imaging. Methodical documentation of the type, area and lifespan of RHs meant that it was possible to address the question of predicting AHT from RH numbers and characteristics, and to describe not only the duration of different layer haemorrhages, but also a previously unreported observation that some RHs transiently enlarge over two to three days before resolving normally. 'One important cause of retinal haemorrhages (RHs) in children is abusive head trauma' Key Practitioner Messages: A new retinal zone classification for research and legal purposes has been developed, as well as a simplified five‐point working classification of RHs, based on existing fundoscopic descriptions.In this cohort study, a young age and a high 'dot‐blot' count (>25 intraretinal haemorrhages) are strong predictors of AHT.There is a complex association between the burden of intracranial pressure insult and RHs.Time to resolution of different RHs has been calculated using two‐dimensional RH area pixel counts from sequential retinal imaging. Two patterns of resolution are reported. [ABSTRACT FROM AUTHOR]

Published
2022
Full Text
View/download PDF

16. Detection and characterisation of visual field defects using Saccadic Vector Optokinetic Perimetry in children with brain tumours

Author

Murray, Ian C, Schmoll, Conrad, Perperidis, Antonios, Brash, Harry M, McTrusty, Alice D, Cameron, Lorraine A, Wilkinson, Alastair G, Mulvihill, Alan O, Fleck, Brian W, and Minns, Robert A

Subjects
Male, Adolescent, genetic structures, Brain Neoplasms, Vision Disorders, Sensitivity and Specificity, Article, Child, Preschool, Saccades, Journal Article, Humans, Visual Field Tests, Female, Visual Fields, Child
Abstract

PURPOSE: To determine the ability of Saccadic Vector Optokinetic Perimetry (SVOP) to detect and characterise visual field defects in children with brain tumours using eye-tracking technology, as current techniques for assessment of visual fields in young children can be subjective and lack useful detail.METHODS: Case-series study of children receiving treatment and follow-up for brain tumours at the Royal Hospital for Sick Children in Edinburgh from April 2008 to August 2013. Patients underwent SVOP testing and the results were compared with clinically expected visual field patterns determined by a consensus panel after review of clinical findings, neuroimaging, and where possible other forms of visual field assessment.RESULTS: Sixteen patients participated in this study (mean age of 7.2 years; range 2.9-15 years; 7 male, 9 female). Twelve children (75%) successfully performed SVOP testing. SVOP had a sensitivity of 100% and a specificity of 50% (positive predictive value of 80% and negative predictive value of 100%). In the true positive and true negative SVOP results, the characteristics of the SVOP plots showed agreement with the expected visual field. Six patients were able to perform both SVOP and Goldmann perimetry, these demonstrated similar visual fields in every case.CONCLUSION: SVOP is a highly sensitive test that may prove to be extremely useful for assessing the visual field in young children with brain tumours, as it is able to characterise the central 30° of visual field in greater detail than previously possible with older techniques.

Published
2018

17. Genetic Analysis of 'PAX6-Negative' Individuals with Aniridia or Gillespie Syndrome

Author

Ansari, Morad, Rainger, Jacqueline, Hanson, Isabel M, Williamson, Kathleen A, Sharkey, Freddie, Harewood, Louise, Sandilands, Angela, Clayton-Smith, Jill, Dollfus, Helene, Bitoun, Pierre, Meire, Francoise, Fantes, Judy, Franco, Brunella, Lorenz, Birgit, Taylor, David S, Stewart, Fiona, Willoughby, Colin E, McEntagart, Meriel, Khaw, Peng Tee, Clericuzio, Carol, Van Maldergem, Lionel, Williams, Denise, Newbury-Ecob, Ruth, Traboulsi, Elias I, Silva, Eduardo D, Madlom, Mukhlis M, Goudie, David R, Fleck, Brian W, Wieczorek, Dagmar, Kohlhase, Juergen, McTrusty, Alice D, Gardiner, Carol, Yale, Christopher, Moore, Anthony T, Russell-Eggitt, Isabelle, Islam, Lily, Lees, Melissa, Beales, Philip L, Tuft, Stephen J, Solano, Juan B, Splitt, Miranda, Hertz, Jens Michael, Prescott, Trine E, Shears, Deborah J, Nischal, Ken K, Doco-Fenzy, Martine, Prieur, Fabienne, Temple, I Karen, Lachlan, Katherine L, Damante, Giuseppe, Morrison, Danny A, van Heyningen, Veronica, FitzPatrick, David R, Ansari, Morad, Rainger, Jacqueline, Hanson, Isabel M., Williamson, Kathleen A., Sharkey, Freddie, Harewood, Louise, Sandilands, Angela, Clayton Smith, Jill, Dollfus, Helene, Bitoun, Pierre, Meire, Francoise, Fantes, Judy, Franco, Brunella, Lorenz, Birgit, Taylor, David S., Stewart, Fiona, Willoughby, Colin E., Mcentagart, Meriel, Khaw, Peng Tee, Clericuzio, Carol, Van Maldergem, Lionel, Williams, Denise, Newbury Ecob, Ruth, Traboulsi, Elias I., Silva, Eduardo D., Madlom, Mukhlis M., Goudie, David R., Fleck, Brian W., Wieczorek, Dagmar, Kohlhase, Juergen, Mctrusty, Alice D., Gardiner, Carol, Yale, Christopher, Moore, Anthony T., Russell Eggitt, Isabelle, Islam, Lily, Lees, Melissa, Beales, Philip L., Tuft, Stephen J., Solano, Juan B., Splitt, Miranda, Hertz, Jens Michael, Prescott, Trine E., Shears, Deborah J., Nischal, Ken K., Doco Fenzy, Martine, Prieur, Fabienne, Temple, I. Karen, Lachlan, Katherine L., Damante, Giuseppe, Morrison, Danny A., Van Heyningen, Veronica, and Fitzpatrick, David R.

Subjects
Male, Genetics and Molecular Biology (all), Eye Diseases, PAX6 Transcription Factor, Mutagenesis and Gene Deletion Techniques, Gene Identification and Analysis, Iris, lcsh:Medicine, Artificial Gene Amplification and Extension, Polymerase Chain Reaction, Biochemistry, axenfeld-rieger syndrome gtpase-activating protein linear skin defects cerebellar-ataxia mental-retardation pax6 gene missense mutations impaired accommodation pitx2 mutations phenotype Science & Technology - Other Topics, Medicine and Health Sciences, Pair 11, lcsh:Science, Aniridia, Comparative Genomic Hybridization, Medicine (all), GTPase-Activating Proteins, Forkhead Transcription Factors, Genomics, Deletion Mutation, Female, Anatomy, Research Article, Human, congenital, hereditary, and neonatal diseases and abnormalities, Cerebellar Ataxia, Ocular Anatomy, Research and Analysis Methods, Human Genomics, Chromosomes, Histone Deacetylases, Ocular System, Intellectual Disability, Genetics, Humans, Genetic Testing, Molecular Biology Techniques, Molecular Biology, Mutation Detection, Homeodomain Proteins, Chromosomes, Human, X, Biochemistry, Genetics and Molecular Biology (all), Chromosomes, Human, Pair 11, lcsh:R, Biology and Life Sciences, Glaucoma, Mutation, Transcription Factors, Agricultural and Biological Sciences (all), eye diseases, Ophthalmology, Mutational Analysis, Genetic Loci, lcsh:Q, sense organs
Abstract

We report molecular genetic analysis of 42 affected individuals referred with a diagnosis of aniridia who previously screened as negative for intragenic PAX6 mutations. Of these 42, the diagnoses were 31 individuals with aniridia and 11 individuals referred with a diagnosis of Gillespie syndrome (iris hypoplasia, ataxia and mild to moderate developmental delay). Array-based comparative genomic hybridization identified six whole gene deletions: four encompassing PAX6 and two encompassing FOXC1. Six deletions with plausible cis-regulatory effects were identified: five that were 3′ (telomeric) to PAX6 and one within a gene desert 5′ (telomeric) to PITX2. Sequence analysis of the FOXC1 and PITX2 coding regions identified two plausibly pathogenic de novo FOXC1 missense mutations (p.Pro79Thr and p. Leu101Pro). No intragenic mutations were detected in PITX2. FISH mapping in an individual with Gillespie-like syndrome with an apparently balanced X;11 reciprocal translocation revealed disruption of a gene at each breakpoint: ARHGAP6 on the X chromosome and PHF21A on chromosome 11. In the other individuals with Gillespie syndrome no mutations were identified in either of these genes, or in HCCS which lies close to the Xp breakpoint. Disruption of PHF21A has previously been implicated in the causation of intellectual disability (but not aniridia). Plausibly causative mutations were identified in 15 out of 42 individuals (12/32 aniridia; 3/11 Gillespie syndrome). Fourteen of these mutations presented in the known aniridia genes; PAX6, FOXC1 and PITX2. The large number of individuals in the cohort with no mutation identified suggests greater locus heterogeneity may exist in both isolated and syndromic aniridia than was previously appreciated.

Published
2016

18. Feasibility, Accuracy, and Repeatability of Suprathreshold Saccadic Vector Optokinetic Perimetry

Author

Murray, Ian C., Cameron, Lorraine A., McTrusty, Alice D., Perperidis, Antonios, Brash, Harry M., Fleck, Brian W., and Minns, Robert A.

Subjects
perimetry, SVOP, saccadic eye movements, visual fields, Articles
Abstract

Purpose To evaluate feasibility, accuracy, and repeatability of suprathreshold Saccadic Vector Optokinetic Perimetry (SVOP) by comparison with Humphrey Field Analyzer (HFA) perimetry. Methods The subjects included children with suspected field defects (n = 10, age 5–15 years), adults with field defects (n = 33, age 39–78 years), healthy children (n = 12, age 6–14 years), and healthy adults (n = 30, age 16–61 years). The test protocol comprised repeat suprathreshold SVOP and HFA testing with the C-40 test pattern. Feasibility was assessed by protocol completeness. Sensitivity, specificity, and accuracy of SVOP was established by comparison with reliable HFA tests in two ways: (1) visual field pattern results (normal/abnormal), and (2) individual test point outcomes (seen/unseen). Repeatability of each test type was assessed using Cohen's kappa coefficient. Results Of subjects, 82% completed a full protocol. Poor reliability of HFA testing in child patients limited the robustness of comparisons in this group. Sensitivity, specificity, and accuracy across all groups when analyzing the visual field pattern results was 90.9%, 88.5%, and 89.0%, respectively, and was 69.1%, 96.9%, and 95.0%, respectively, when analyzing the individual test points. Cohen's kappa coefficient for repeatability of SVOP and HFA was excellent (0.87 and 0.88, respectively) when assessing visual field pattern results, and substantial (0.62 and 0.74, respectively) when assessing test point outcomes. Conclusions SVOP was accurate in this group of adults. Further studies are required to assess SVOP in child patient groups. Translational Relevance SVOP technology is still in its infancy but is used in a number of centers. It will undergo iterative improvements and this study provides a benchmark for future iterations.

Published
2016

19. Comparison of Threshold Saccadic Vector Optokinetic Perimetry (SVOP) and Standard Automated Perimetry (SAP) in Glaucoma. Part II: Patterns of Visual Field Loss and Acceptability

Author

McTrusty, Alice D., primary, Cameron, Lorraine A., additional, Perperidis, Antonios, additional, Brash, Harry M., additional, Tatham, Andrew J., additional, Agarwal, Pankaj K., additional, Murray, Ian C., additional, Fleck, Brian W., additional, and Minns, Robert A., additional

Published
2017
Full Text
View/download PDF

21. Outcomes of two trials of oxygen-saturation targets in preterm infants

Author

Tarnow-Mordi, William O, Stenson, Ben, Kirby, Adrienne, Juszczak, Edmund, Donoghoe, Mark, Deshpande, Sanjeev, Morley, Colin J, King, Andrew, Doyle, Lex W, Fleck, Brian W, Davis, Peter, Halliday, Henry L, Hague, Wendy, Cairns, Pamela, Darlow, Brian A, Fielder, Alistair R, Gebski, Val, Marlow, Neil, Simmer, Karen, Tin, Win, Ghadge, Alpana, Williams, Cathy, Keech, Anthony, Wardle, Stephen P, Kecskes, Zsuzsoka, Kluckow, Martin, Gole, Glen, Evans, Nicholas, Malcolm, Girvan, Luig, Melissa, Wright, Ian M. R, Stack, Jacqueline, Tan, Kenneth, Pritchard, Margo, Gray, Peter H, Morris, Scott, Headley, Bevan, Dargaville, Peter, Simes, R John, Brocklehurst, Peter, Tarnow-Mordi, William O, Stenson, Ben, Kirby, Adrienne, Juszczak, Edmund, Donoghoe, Mark, Deshpande, Sanjeev, Morley, Colin J, King, Andrew, Doyle, Lex W, Fleck, Brian W, Davis, Peter, Halliday, Henry L, Hague, Wendy, Cairns, Pamela, Darlow, Brian A, Fielder, Alistair R, Gebski, Val, Marlow, Neil, Simmer, Karen, Tin, Win, Ghadge, Alpana, Williams, Cathy, Keech, Anthony, Wardle, Stephen P, Kecskes, Zsuzsoka, Kluckow, Martin, Gole, Glen, Evans, Nicholas, Malcolm, Girvan, Luig, Melissa, Wright, Ian M. R, Stack, Jacqueline, Tan, Kenneth, Pritchard, Margo, Gray, Peter H, Morris, Scott, Headley, Bevan, Dargaville, Peter, Simes, R John, and Brocklehurst, Peter

Abstract

BACKGROUND The safest ranges of oxygen saturation in preterm infants have been the subject of debate. METHODS In two trials, conducted in Australia and the United Kingdom, infants born before 28 weeks' gestation were randomly assigned to either a lower (85 to 89%) or a higher (91 to 95%) oxygen-saturation range. During enrollment, the oximeters were revised to correct a calibration-algorithm artifact. The primary outcome was death or disability at a corrected gestational age of 2 years; this outcome was evaluated among infants whose oxygen saturation was measured with any study oximeter in the Australian trial and those whose oxygen saturation was measured with a revised oximeter in the U.K. trial. RESULTS After 1135 infants in Australia and 973 infants in the United Kingdom had been enrolled in the trial, an interim analysis showed increased mortality at a corrected gestational age of 36 weeks, and enrollment was stopped. Death or disability in the Australian trial (with all oximeters included) occurred in 247 of 549 infants (45.0%) in the lower-target group versus 217 of 545 infants (39.8%) in the higher-target group (adjusted relative risk, 1.12; 95% confidence interval [CI], 0.98 to 1.27; P = 0.10); death or disability in the U.K. trial (with only revised oximeters included) occurred in 185 of 366 infants (50.5%) in the lower-target group versus 164 of 357 infants (45.9%) in the higher-target group (adjusted relative risk, 1.10; 95% CI, 0.97 to 1.24; P = 0.15). In post hoc combined, unadjusted analyses that included all oximeters, death or disability occurred in 492 of 1022 infants (48.1%) in the lower-target group versus 437 of 1013 infants (43.1%) in the higher-target group (relative risk, 1.11; 95% CI, 1.01 to 1.23; P = 0.02), and death occurred in 222 of 1045 infants (21.2%) in the lower-target group versus 185 of 1045 infants (17.7%) in the higher-target group (relative risk, 1.20; 95% CI, 1.01 to 1.43; P = 0.04). In the group in which revised oximeters wer

Published
2016

23. Outcomes of Two Trials of Oxygen-Saturation Targets in Preterm Infants.

Author

BOOST-II Australia and United Kingdom Collaborative Groups, Tarnow-Mordi, William, Stenson, Ben, Kirby, Adrienne, Juszczak, Edmund, Donoghoe, Mark, Deshpande, Sanjeev, Morley, Colin, King, Andrew, Doyle, Lex W, Fleck, Brian W, Davis, Peter G, Halliday, Henry L, Hague, Wendy, Cairns, Pamela, Darlow, Brian A, Fielder, Alistair R, Gebski, Val, Marlow, Neil, and Simmer, Karen

Subjects
*CLINICAL trials, *OXYGEN therapy for premature infants, *HEALTH outcome assessment, *EVALUATION of medical care, *NEONATAL mortality, *COMPARATIVE studies, *DEVELOPMENTAL disabilities, *PREMATURE infants, *INFANT mortality, *RESEARCH methodology, *MEDICAL cooperation, *OXIMETRY, *OXYGEN, *OXYGEN therapy, *RESEARCH, *RESEARCH funding, *EVALUATION research, *RANDOMIZED controlled trials, *RELATIVE medical risk
Abstract

Background: The safest ranges of oxygen saturation in preterm infants have been the subject of debate.Methods: In two trials, conducted in Australia and the United Kingdom, infants born before 28 weeks' gestation were randomly assigned to either a lower (85 to 89%) or a higher (91 to 95%) oxygen-saturation range. During enrollment, the oximeters were revised to correct a calibration-algorithm artifact. The primary outcome was death or disability at a corrected gestational age of 2 years; this outcome was evaluated among infants whose oxygen saturation was measured with any study oximeter in the Australian trial and those whose oxygen saturation was measured with a revised oximeter in the U.K. trial.Results: After 1135 infants in Australia and 973 infants in the United Kingdom had been enrolled in the trial, an interim analysis showed increased mortality at a corrected gestational age of 36 weeks, and enrollment was stopped. Death or disability in the Australian trial (with all oximeters included) occurred in 247 of 549 infants (45.0%) in the lower-target group versus 217 of 545 infants (39.8%) in the higher-target group (adjusted relative risk, 1.12; 95% confidence interval [CI], 0.98 to 1.27; P=0.10); death or disability in the U.K. trial (with only revised oximeters included) occurred in 185 of 366 infants (50.5%) in the lower-target group versus 164 of 357 infants (45.9%) in the higher-target group (adjusted relative risk, 1.10; 95% CI, 0.97 to 1.24; P=0.15). In post hoc combined, unadjusted analyses that included all oximeters, death or disability occurred in 492 of 1022 infants (48.1%) in the lower-target group versus 437 of 1013 infants (43.1%) in the higher-target group (relative risk, 1.11; 95% CI, 1.01 to 1.23; P=0.02), and death occurred in 222 of 1045 infants (21.2%) in the lower-target group versus 185 of 1045 infants (17.7%) in the higher-target group (relative risk, 1.20; 95% CI, 1.01 to 1.43; P=0.04). In the group in which revised oximeters were used, death or disability occurred in 287 of 580 infants (49.5%) in the lower-target group versus 248 of 563 infants (44.0%) in the higher-target group (relative risk, 1.12; 95% CI, 0.99 to 1.27; P=0.07), and death occurred in 144 of 587 infants (24.5%) versus 99 of 586 infants (16.9%) (relative risk, 1.45; 95% CI, 1.16 to 1.82; P=0.001).Conclusions: Use of an oxygen-saturation target range of 85 to 89% versus 91 to 95% resulted in nonsignificantly higher rates of death or disability at 2 years in each trial but in significantly increased risks of this combined outcome and of death alone in post hoc combined analyses. (Funded by the Australian National Health and Medical Research Council and others; BOOST-II Current Controlled Trials number, ISRCTN00842661, and Australian New Zealand Clinical Trials Registry number, ACTRN12605000055606.). [ABSTRACT FROM AUTHOR]

Published
2016
Full Text
View/download PDF

24. Ranibizumab Population Pharmacokinetics and Free VEGF Pharmacodynamics in Preterm Infants With Retinopathy of Prematurity in the RAINBOW Trial.

Author

Fidler M, Fleck BW, Stahl A, Marlow N, Chastain JE, Li J, Lepore D, Reynolds JD, Chiang MF, and Fielder AR

Subjects
Angiogenesis Inhibitors therapeutic use, Humans, Infant, Infant, Newborn, Infant, Premature, Vascular Endothelial Growth Factor A therapeutic use, Ranibizumab therapeutic use, Retinopathy of Prematurity drug therapy
Abstract

Purpose: To develop a population pharmacokinetic (PK) model for intravitreal ranibizumab in infants with retinopathy of prematurity (ROP) and assess plasma free vascular endothelial growth factor (VEGF) pharmacodynamics (PD)., Methods: The RAnibizumab compared with laser therapy for the treatment of INfants BOrn prematurely With retinopathy of prematurity (RAINBOW) trial enrolled 225 infants to receive a bilateral intravitreal injection of ranibizumab 0.1 mg, ranibizumab 0.2 mg, or laser in a 1:1:1 ratio and included sparse sampling of blood for population PK and PD analysis. An adult PK model using infant body weight as a fixed allometric covariate was re-estimated using the ranibizumab concentrations in the preterm population. Different variability, assumptions, and covariate relationships were explored. Model-based individual predicted concentrations of ranibizumab were plotted against observed free VEGF concentrations., Results: Elimination of ranibizumab had a median half-life of 5.6 days from the eye and 0.3 days from serum, resulting in an apparent serum half-life of 5.6 days. Time to reach maximum concentration was rapid (median: 1.3 days). Maximum concentration (median 24.3 ng/mL with ranibizumab 0.2 mg) was higher than that reported in adults. No differences in plasma free VEGF concentrations were apparent between the groups or over time. Plotted individual predicted concentrations of ranibizumab against observed free VEGF concentrations showed no relationship., Conclusions: In preterm infants with ROP, elimination of ranibizumab from the eye was the rate-limiting step and was faster compared with adults. No reduction in plasma free VEGF was observed. The five-year clinical safety follow-up from RAINBOW is ongoing., Translational Relevance: Our population PK and VEGF PD findings suggest a favorable ocular efficacy: systemic safety profile for ranibizumab in preterm infants., Competing Interests: Disclosure: M. Fidler, Novartis (E); B.W. Fleck, Novartis (C); A. Stahl, Novartis (R), Allergan (C), Bayer (C), Novartis (C); N. Marlow, Novartis (C); J.E. Chastain, Novartis (E); J. Li, Novartis (E); D. Lepore, Novartis (C); J.D. Reynolds, Novartis (C); M.F. Chiang, Novartis (C), InTeleretina, LLC (I), Research to Prevent Blindness (R), NIH grant P30EY10572 (R); A.R. Fielder, Bayer (C), Novartis (C), (Copyright 2020 The Authors.)

Published
2020
Full Text
View/download PDF

25. Outcomes of Two Trials of Oxygen-Saturation Targets in Preterm Infants.

Author

Tarnow-Mordi W, Stenson B, Kirby A, Juszczak E, Donoghoe M, Deshpande S, Morley C, King A, Doyle LW, Fleck BW, Davis PG, Halliday HL, Hague W, Cairns P, Darlow BA, Fielder AR, Gebski V, Marlow N, Simmer K, Tin W, Ghadge A, Williams C, Keech A, Wardle SP, Kecskes Z, Kluckow M, Gole G, Evans N, Malcolm G, Luig M, Wright I, Stack J, Tan K, Pritchard M, Gray PH, Morris S, Headley B, Dargaville P, Simes RJ, and Brocklehurst P

Subjects
Australia, Child, Preschool, Female, Humans, Infant, Infant, Newborn, Male, Oximetry, Oxygen Inhalation Therapy adverse effects, Risk, United Kingdom, Developmental Disabilities epidemiology, Infant Mortality, Infant, Extremely Premature blood, Oxygen blood, Oxygen Inhalation Therapy methods
Abstract

Background: The safest ranges of oxygen saturation in preterm infants have been the subject of debate., Methods: In two trials, conducted in Australia and the United Kingdom, infants born before 28 weeks' gestation were randomly assigned to either a lower (85 to 89%) or a higher (91 to 95%) oxygen-saturation range. During enrollment, the oximeters were revised to correct a calibration-algorithm artifact. The primary outcome was death or disability at a corrected gestational age of 2 years; this outcome was evaluated among infants whose oxygen saturation was measured with any study oximeter in the Australian trial and those whose oxygen saturation was measured with a revised oximeter in the U.K. trial., Results: After 1135 infants in Australia and 973 infants in the United Kingdom had been enrolled in the trial, an interim analysis showed increased mortality at a corrected gestational age of 36 weeks, and enrollment was stopped. Death or disability in the Australian trial (with all oximeters included) occurred in 247 of 549 infants (45.0%) in the lower-target group versus 217 of 545 infants (39.8%) in the higher-target group (adjusted relative risk, 1.12; 95% confidence interval [CI], 0.98 to 1.27; P=0.10); death or disability in the U.K. trial (with only revised oximeters included) occurred in 185 of 366 infants (50.5%) in the lower-target group versus 164 of 357 infants (45.9%) in the higher-target group (adjusted relative risk, 1.10; 95% CI, 0.97 to 1.24; P=0.15). In post hoc combined, unadjusted analyses that included all oximeters, death or disability occurred in 492 of 1022 infants (48.1%) in the lower-target group versus 437 of 1013 infants (43.1%) in the higher-target group (relative risk, 1.11; 95% CI, 1.01 to 1.23; P=0.02), and death occurred in 222 of 1045 infants (21.2%) in the lower-target group versus 185 of 1045 infants (17.7%) in the higher-target group (relative risk, 1.20; 95% CI, 1.01 to 1.43; P=0.04). In the group in which revised oximeters were used, death or disability occurred in 287 of 580 infants (49.5%) in the lower-target group versus 248 of 563 infants (44.0%) in the higher-target group (relative risk, 1.12; 95% CI, 0.99 to 1.27; P=0.07), and death occurred in 144 of 587 infants (24.5%) versus 99 of 586 infants (16.9%) (relative risk, 1.45; 95% CI, 1.16 to 1.82; P=0.001)., Conclusions: Use of an oxygen-saturation target range of 85 to 89% versus 91 to 95% resulted in nonsignificantly higher rates of death or disability at 2 years in each trial but in significantly increased risks of this combined outcome and of death alone in post hoc combined analyses. (Funded by the Australian National Health and Medical Research Council and others; BOOST-II Current Controlled Trials number, ISRCTN00842661, and Australian New Zealand Clinical Trials Registry number, ACTRN12605000055606.).

Published
2016
Full Text
View/download PDF

Catalog

Books, media, physical & digital resources
See catalog results