American Journal of Neuroradiology: 41 (9)

Index by author

September 01, 2020; Volume 41,Issue 9

Braun, M.
1. Interventional
  
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  Shape Modification is Common in Woven EndoBridge–Treated Intracranial Aneurysms: A Longitudinal Quantitative Analysis Study
  J. Rosskopf, M. Braun, J. Dreyhaupt, M. Beer, B.L. Schmitz and Y. Ozpeynirci
  
  American Journal of Neuroradiology September 2020, 41 (9) 1652-1656; DOI: https://doi.org/10.3174/ajnr.A6669
Brinjikji, W.
1. Adult Brain
  
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  Lack of Baseline Intracranial Aneurysm Wall Enhancement Predicts Future Stability: A Systematic Review and Meta-Analysis of Longitudinal Studies
  A.S. Larson, V.T. Lehman, G. Lanzino and W. Brinjikji
  
  American Journal of Neuroradiology September 2020, 41 (9) 1606-1610; DOI: https://doi.org/10.3174/ajnr.A6690
Brunetti, A.
1. LETTER
  
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  The Development of Subcortical Gray Matter Atrophy in Multiple Sclerosis: One Size Does Not Fit All
  G. Pontillo, M. Petracca, S. Cocozza and A. Brunetti
  
  American Journal of Neuroradiology September 2020, 41 (9) E80-E81; DOI: https://doi.org/10.3174/ajnr.A6698
Buch, K.
1. Adult Brain
  
  Open Access
  Leukoencephalopathy Associated with Severe COVID-19 Infection: Sequela of Hypoxemia?
  M. Lang, K. Buch, M.D. Li, W.A. Mehan, A.L. Lang, T.M. Leslie-Mazwi and S.P. Rincon
  
  American Journal of Neuroradiology September 2020, 41 (9) 1641-1645; DOI: https://doi.org/10.3174/ajnr.A6671
Bunch, P.M.
1. Pediatrics
  
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  Internal Auditory Canal Diverticula among Pediatric Patients: Prevalence and Assessment for Hearing Loss and Anatomic Associations
  P.M. Bunch, M.E. Zapadka, C.M. Lack, E.P. Kiell, D.J. Kirse and J.R. Sachs
  
  American Journal of Neuroradiology September 2020, 41 (9) 1712-1717; DOI: https://doi.org/10.3174/ajnr.A6691
Burns, M.R.
1. Adult Brain
  
  Open Access
  Neuroimaging Advances in Deep Brain Stimulation: Review of Indications, Anatomy, and Brain Connectomics
  E.H. Middlebrooks, R.A. Domingo, T. Vivas-Buitrago, L. Okromelidze, T. Tsuboi, J.K. Wong, R.S. Eisinger, L. Almeida, M.R. Burns, A. Horn, R.J. Uitti, R.E. Wharen, V.M. Holanda and S.S. Grewal
  
  American Journal of Neuroradiology September 2020, 41 (9) 1558-1568; DOI: https://doi.org/10.3174/ajnr.A6693
Cagnazzo, F.
1. FELLOWS' JOURNAL CLUBInterventional
  
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  Predictors of Favorable Outcome after Endovascular Thrombectomy in MRI: Selected Patients with Acute Basilar Artery Occlusion
  M. Mahmoudi, C. Dargazanli, F. Cagnazzo, I. Derraz, C. Arquizan, A. Wacogne, J. Labreuche, A. Bonafe, D. Sablot, P.H. Lefevre, G. Gascou, N. Gaillard, C. Scott, V. Costalat and I. Mourand
  
  American Journal of Neuroradiology September 2020, 41 (9) 1670-1676; DOI: https://doi.org/10.3174/ajnr.A6741
  
  The authors analyzed consecutive MR imaging–selected patients with acute basilar artery occlusions endovascularly treated within the first 24 hours after symptom onset. Successful and complete reperfusion was defined as modified TICI scores 2b–3 and 3, respectively. Outcome at 90 days was analyzed. One hundred ten patients were included. In 10 patients, endovascular treatment was aborted for failed proximal/distal access. Overall, successful reperfusion was achieved in 81.8% of cases. At 90 days, favorable outcome was 31.8%, with a mortality rate of 40.9%; the prevalence of symptomatic intracranial hemorrhage within 24 hours was 2.7%. The median time from symptom onset to groin puncture was 410 minutes. In this series of MR imaging–selected patients with acute basilar artery occlusions, complete reperfusion was the strongest predictor of a good outcome. Lower pretreatment NIHSS, the presence of posterior communicating artery collateral flow, the absence of atrial fibrillation, and intravenous thrombolysis administration were associated with favorable outcome.
Cahir-mcfarland, E.
1. Adult Brain
  
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  Patterning Chronic Active Demyelination in Slowly Expanding/Evolving White Matter MS Lesions
  C. Elliott, D.L. Arnold, H. Chen, C. Ke, L. Zhu, I. Chang, E. Cahir-McFarland, E. Fisher, B. Zhu, S. Gheuens, M. Scaramozza, V. Beynon, N. Franchimont, D.P. Bradley and S. Belachew
  
  American Journal of Neuroradiology September 2020, 41 (9) 1584-1591; DOI: https://doi.org/10.3174/ajnr.A6742
Calvez, R.
1. FELLOWS' JOURNAL CLUBPediatrics
  
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  Focal Areas of High Signal Intensity in Children with Neurofibromatosis Type 1: Expected Evolution on MRI
  S. Calvez, R. Levy, R. Calvez, C.-J. Roux, D. Grévent, Y. Purcell, K. Beccaria, T. Blauwblomme, J. Grill, C. Dufour, F. Bourdeaut, F. Doz, M.P. Robert, N. Boddaert and V. Dangouloff-Ros
  
  American Journal of Neuroradiology September 2020, 41 (9) 1733-1739; DOI: https://doi.org/10.3174/ajnr.A6740
  
  The authors retrospectively examined the MRI of children diagnosed with neurofibromatosis type 1 using the National Institutes of Health Consensus Criteria (1987), with imaging follow-up of at least 4 years. They recorded the number, size, and surface area of focal areas of high signal intensity according to their anatomic distribution on T2WI/T2-FLAIR sequences. A generalized mixed model was used to analyze the evolution of focal areas of high signal intensity according to age, and separate analyses were performed for girls and boys. Thirty-nine patients with a median follow-up of 7 years were analyzed. Focal areas of high signal intensity were found in 100% of patients, preferentially in the infratentorial white matter (35% cerebellum, 30% brain stem) and in the capsular lenticular region (22%). They measured 15mm in 95% of cases. The areas appeared from the age of 1 year; increased in number, size, and surface area to a peak at the age of 7; and then spontaneously regressed by 17 years of age. The authors conclude that the study suggests that the evolution of focal areas of high signal intensity is not related to puberty and has a peak at the age of 7 years.
Calvez, S.
1. FELLOWS' JOURNAL CLUBPediatrics
  
  You have access
  Focal Areas of High Signal Intensity in Children with Neurofibromatosis Type 1: Expected Evolution on MRI
  S. Calvez, R. Levy, R. Calvez, C.-J. Roux, D. Grévent, Y. Purcell, K. Beccaria, T. Blauwblomme, J. Grill, C. Dufour, F. Bourdeaut, F. Doz, M.P. Robert, N. Boddaert and V. Dangouloff-Ros
  
  American Journal of Neuroradiology September 2020, 41 (9) 1733-1739; DOI: https://doi.org/10.3174/ajnr.A6740
  
  The authors retrospectively examined the MRI of children diagnosed with neurofibromatosis type 1 using the National Institutes of Health Consensus Criteria (1987), with imaging follow-up of at least 4 years. They recorded the number, size, and surface area of focal areas of high signal intensity according to their anatomic distribution on T2WI/T2-FLAIR sequences. A generalized mixed model was used to analyze the evolution of focal areas of high signal intensity according to age, and separate analyses were performed for girls and boys. Thirty-nine patients with a median follow-up of 7 years were analyzed. Focal areas of high signal intensity were found in 100% of patients, preferentially in the infratentorial white matter (35% cerebellum, 30% brain stem) and in the capsular lenticular region (22%). They measured 15mm in 95% of cases. The areas appeared from the age of 1 year; increased in number, size, and surface area to a peak at the age of 7; and then spontaneously regressed by 17 years of age. The authors conclude that the study suggests that the evolution of focal areas of high signal intensity is not related to puberty and has a peak at the age of 7 years.

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American Journal of Neuroradiology

Index by author

Braun, M.

Brinjikji, W.

Brunetti, A.

Buch, K.

Bunch, P.M.

Burns, M.R.

Cagnazzo, F.

Cahir-mcfarland, E.

Calvez, R.

Calvez, S.

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