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Index by author

March 01, 2019; Volume 40,Issue 3

  1. Patel, S.H.

    1. FELLOWS' JOURNAL CLUBAdult Brain
      Neuroimaging-Based Classification Algorithm for Predicting 1p/19q-Codeletion Status in IDH-Mutant Lower Grade Gliomas
      P.P. Batchala, T.J.E. Muttikkal, J.H. Donahue, J.T. Patrie, D. Schiff, C.E. Fadul, E.K. Mrachek, M.-B. Lopes, R. Jain and S.H. Patel
      American Journal of Neuroradiology March 2019, 40 (3) 426-432; DOI: https://doi.org/10.3174/ajnr.A5957

      One hundred two IDH-mutant lower grade gliomas with preoperative MR imaging and known 1p/19q status from The Cancer Genome Atlas composed a training dataset. Two neuroradiologists in consensus analyzed the training dataset for various imaging features: tumor or cyst texture, margins, cortical infiltration, T2-FLAIR mismatch, tumor cyst, T2* susceptibility, hydrocephalus, midline shift, maximum dimension, primary lobe, necrosis, enhancement, edema, and gliomatosis. Statistical analysis of the training data produced a multivariate classification model for codeletion prediction based on a subset of MR imaging features and patient age. Training dataset analysis produced a 2-step classification algorithm with 86.3% codeletion prediction accuracy, based on the following: 1) the presence of the T2-FLAIR mismatch sign, which was 100% predictive of noncodeleted lowergrade gliomas; and 2)a logistic regression model based on texture, patient age, T2* susceptibility, primary lobe, and hydrocephalus. Independent validation ofthe classification algorithm rendered codeletion prediction accuracies of 81.1% and 79.2% in 2 independent readers.

  2. Patrie, J.T.

    1. FELLOWS' JOURNAL CLUBAdult Brain
      Neuroimaging-Based Classification Algorithm for Predicting 1p/19q-Codeletion Status in IDH-Mutant Lower Grade Gliomas
      P.P. Batchala, T.J.E. Muttikkal, J.H. Donahue, J.T. Patrie, D. Schiff, C.E. Fadul, E.K. Mrachek, M.-B. Lopes, R. Jain and S.H. Patel
      American Journal of Neuroradiology March 2019, 40 (3) 426-432; DOI: https://doi.org/10.3174/ajnr.A5957

      One hundred two IDH-mutant lower grade gliomas with preoperative MR imaging and known 1p/19q status from The Cancer Genome Atlas composed a training dataset. Two neuroradiologists in consensus analyzed the training dataset for various imaging features: tumor or cyst texture, margins, cortical infiltration, T2-FLAIR mismatch, tumor cyst, T2* susceptibility, hydrocephalus, midline shift, maximum dimension, primary lobe, necrosis, enhancement, edema, and gliomatosis. Statistical analysis of the training data produced a multivariate classification model for codeletion prediction based on a subset of MR imaging features and patient age. Training dataset analysis produced a 2-step classification algorithm with 86.3% codeletion prediction accuracy, based on the following: 1) the presence of the T2-FLAIR mismatch sign, which was 100% predictive of noncodeleted lowergrade gliomas; and 2)a logistic regression model based on texture, patient age, T2* susceptibility, primary lobe, and hydrocephalus. Independent validation ofthe classification algorithm rendered codeletion prediction accuracies of 81.1% and 79.2% in 2 independent readers.

  3. Perrini, P.

    1. Neurointervention
      Flow-Diversion Treatment of Unruptured Saccular Anterior Communicating Artery Aneurysms: A Systematic Review and Meta-Analysis
      F. Cagnazzo, N. Limbucci, S. Nappini, L. Renieri, A. Rosi, A. Laiso, D. Tiziano di Carlo, P. Perrini and S. Mangiafico
      American Journal of Neuroradiology March 2019, 40 (3) 497-502; DOI: https://doi.org/10.3174/ajnr.A5967

  4. Pfeiffer, H.

    1. Pediatric Neuroimaging
      Open Access
      Understanding Subdural Collections in Pediatric Abusive Head Trauma
      D. Wittschieber, B. Karger, H. Pfeiffer and M.L. Hahnemann
      American Journal of Neuroradiology March 2019, 40 (3) 388-395; DOI: https://doi.org/10.3174/ajnr.A5855

  5. Piergallini, L.

    1. Neurointervention
      Comparison of Pipeline Embolization Device Sizing Based on Conventional 2D Measurements and Virtual Simulation Using the Sim&Size Software: An Agreement Study
      J.M. Ospel, G. Gascou, V. Costalat, L. Piergallini, K.A. Blackham and D.W. Zumofen
      American Journal of Neuroradiology March 2019, 40 (3) 524-530; DOI: https://doi.org/10.3174/ajnr.A5973

  6. Pierot, L.

    1. Neurointervention
      Open Access
      Aneurysm Characteristics, Study Population, and Endovascular Techniques for the Treatment of Intracranial Aneurysms in a Large, Prospective, Multicenter Cohort: Results of the Analysis of Recanalization after Endovascular Treatment of Intracranial Aneurysm Study
      M. Gawlitza, S. Soize, C. Barbe, A. le Clainche, P. White, L. Spelle and L. Pierot ARETA Study Group
      American Journal of Neuroradiology March 2019, 40 (3) 517-523; DOI: https://doi.org/10.3174/ajnr.A5991

  7. Pinho, M.

    1. FELLOWS' JOURNAL CLUBAdult Brain
      Open Access
      Disorder in Pixel-Level Edge Directions on T1WI Is Associated with the Degree of Radiation Necrosis in Primary and Metastatic Brain Tumors: Preliminary Findings
      P. Prasanna, L. Rogers, T.C. Lam, M. Cohen, A. Siddalingappa, L. Wolansky, M. Pinho, A. Gupta, K.J. Hatanpaa, A. Madabhushi and P. Tiwari
      American Journal of Neuroradiology March 2019, 40 (3) 412-417; DOI: https://doi.org/10.3174/ajnr.A5958

      The authors sought to investigate whether co-occurrence of local anisotropic gradient orientations (COLLAGE) measurements from posttreatment gadolinium-contrast T1WI could distinguish varying extents of cerebral radiation necrosis and recurrent tumor classes in a lesion across primary and metastatic brain tumors. On 75 gadolinium-contrast T1WI studies obtained from patients with primary and metastatic brain tumors and nasopharyngeal carcinoma, the extent of cerebral radiation necrosis and recurrent tumor in every brain lesion was histopathologically defined by a neuropathologist as the following: 1) “pure” cerebral radiation necrosis; 2) “mixed” pathology with coexistence of cerebral radiation necrosis and recurrent tumors; 3) “predominant” (>80%) cerebral radiation necrosis; 4) predominant (>80%) recurrent tumor; and 5) pure tumor. COLLAGE features were extracted from the expert-annotated ROIs on MR imaging. COLLAGE features exhibited decreased skewness for patients with pure and predominant cerebral radiation necrosis and were statistically significantly different from those in patients with predominant recurrent tumors, which had highly skewed COLLAGE values.

  8. Pollard, S.H.

    1. Pediatric Neuroimaging
      Infant Midnasal Stenosis: Reliability of Nasal Metrics
      M.E. Graham, K.M. Loveridge, S.H. Pollard, K.R. Moore and J.R. Skirko
      American Journal of Neuroradiology March 2019, 40 (3) 562-567; DOI: https://doi.org/10.3174/ajnr.A5980

  9. Pop, R.

    1. Neurointervention
      Predictors and Clinical Impact of Delayed Stent Thrombosis after Thrombectomy for Acute Stroke with Tandem Lesions
      R. Pop, I. Zinchenko, V. Quenardelle, D. Mihoc, M. Manisor, J.S. Richter, F. Severac, M. Simu, S. Chibbaro, O. Rouyer, V. Wolff and R. Beaujeux
      American Journal of Neuroradiology March 2019, 40 (3) 533-539; DOI: https://doi.org/10.3174/ajnr.A5976

  10. Porter-umphrey, A.B.

    1. FELLOWS' JOURNAL CLUBAdult Brain
      Open Access
      Accurate Patient-Specific Machine Learning Models of Glioblastoma Invasion Using Transfer Learning
      L.S. Hu, H. Yoon, J.M. Eschbacher, L.C. Baxter, A.C. Dueck, A. Nespodzany, K.A. Smith, P. Nakaji, Y. Xu, L. Wang, J.P. Karis, A.J. Hawkins-Daarud, K.W. Singleton, P.R. Jackson, B.J. Anderies, B.R. Bendok, R.S. Zimmerman, C. Quarles, A.B. Porter-Umphrey, M.M. Mrugala, A. Sharma, J.M. Hoxworth, M.G. Sattur, N. Sanai, P.E. Koulemberis, C. Krishna, J.R. Mitchell, T. Wu, N.L. Tran, K.R. Swanson and J. Li
      American Journal of Neuroradiology March 2019, 40 (3) 418-425; DOI: https://doi.org/10.3174/ajnr.A5981

      The authors evaluated tumor cell density using a transfer learning method that generates individualized patient models, grounded in the wealth of population data, while also detecting and adjusting for interpatient variabilities based on each patient's own histologic data. They collected 82 image-recorded biopsy samples, from 18 patients with primary GBM. With multivariate modeling, transfer learning improved performance (r = 0.88) compared with one-model-fits-all (r = 0.39). They conclude that transfer learning significantly improves predictive modeling performance for quantifying tumor cell density in glioblastoma.

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