Αποτελέσματα αναζήτησης - "ДИФФУЗИОННО-ТЕНЗОРНАЯ МРТ"

1

Academic Journal

Fractional anisotropy values of brain matter among healthy children: cohort study ; Показатели фракционной анизотропии вещества головного мозга у здоровых детей: когортное исследование

Συγγραφείς: N. V. Marchenko, D. Yu. Novokshonov, E. Yu. Shevchenko, M. A. Bedova, R. V. Aliev, D. L. Dubitsky, A. V. Klimkin, V. B. Voitenkov, N. V. Skripchenko, Н. В. Марченко, Д. Ю. Новокшонов, Е. Ю. Шевченко, М. А. Бедова, Р. В. Алиев, Д. Л. Дубицкий, А. В. Климкин, В. Б. Войтенков, Н. В. Скрипченко

Πηγή: Diagnostic radiology and radiotherapy; Том 13, № 3 (2022); 7-17 ; Лучевая диагностика и терапия; Том 13, № 3 (2022); 7-17 ; 2079-5343

Θεματικοί όροι: фракционная анизотропия, diffusion tensor MRI, children, brain, fractional anisotropy, диффузионно-тензорная МРТ, дети, головной мозг

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Relation: https://radiag.bmoc-spb.ru/jour/article/view/750/556; Basser P.J., Pajevic S., Pierpaoli C., Duda J., Aldroubi A. In vivo fiber tractography using DT-MRI data. // Magn. Reson. Med. 2000. Vol. 44, No. 4. Р. 625–632. doi:10.1002/1522-2594(200010)44:43.0.co;2-o.; Ceccarelli A., Rocca M.A., Fаlini A. Normal-appearing white and grey matter damage in MS. // J. Neurol. 2007. Vol. 254. Р. 513–518. https://doi.org/10.1007/s00415-006-0408-4.; Ahn S., Lee S.K. Diffusion tensor imaging: exploring the motor networks and clinical applications // Kоrean J. Radiol. 2011. Vol. 12. Р. 651–661. doi:10.3348/kjr.2011.12.6.651.; Kumar R., Chavez A.S., Macey P.M., Woo M.A., Harper R.M. Brain axial and radial diffusivity changes with age and gender in healthy adults // Brain Res. 2013. Vol. 28, No. 15. Р. 12–22. doi:10.1016/j.brainres.2013.03.028.; Vo Van P., Alison M., Morel B., Beck J., Bednarek N., Hertz-Pannier L., Loron G. Advanced Brain Imaging in Preterm Infants: A Narrative Review of Microstructural and Connectomic Disruption // Children (Basel). 2022. Vol. 9, No. 3. Р. 356. doi:10.3390/children9030356.; Li K., Sun Z., Han Y., Gao L., Yuan L., Zeng D. Fractional anisotropy alterations in individuals born preterm: a diffusion tensor imaging meta-analysis. // Dev Med Child Neurol. 2015. Vol. 57, No. 4. Р. 328–338. doi:10.1111/dmcn.12618.; Woodward L.J., Anderson P.J., Austin N.C., Howard K., Inder T.E. Neonatal MRI to predict neurodevelopmental outcomes in preterm infants // N. Engl. J. Med. 2006. Vol. 17. Р. 355. doi:10.1056/NEJMoa053792.; Мамедьяров А.М., Намазова-Баранова Л.С., Ермолина Ю.В., Аникин А.В., Маслова О.А., Каркашадзе М.З., Клочкова О.А. Возможности оценки моторных и сенсорных проводящих путей головного мозга с помощью диффузионно-тензорной трактографии у детей с детским церебральным параличом // Вестник Российской академии медицинских наук. 2014. № 9. C. 70–76. Mamed’yarov A.M., Namazova-Baranova L.S., Yermolina YU.V., Anikin A.V., Maslova O.A., Karkashadze M.Z., Klochkova O.A. Vozmozhnosti otsenki motornykh i sensornykh provodyashchikh putey golovnogo mozga s pomoshch’yu diffuzionno-tenzornoy traktografii u detey s detskim tserebral’nym paralichom // Vestnik Rossiyskoy akademii meditsinskikh nauk. 2014. No. 9. S. 70–76.; Nagy Z., Westerberg H., Klingberg T. Maturation of white matter is associated with the development of cognitive functions during childhood // J. Cogn. Neurosci. 2004. Sep. Vol. 16, No. 7. Р. 1227–1233. doi:10.1162/0898929041920441.; Barnea-Goraly N., Menon V., Eckert M., Tamm L., Bammer R., Karchemskiy A., Dant CC., Reiss AL. White matter development during childhood and adolescence: a cross-sectional diffusion tensor imaging study // Cereb Cortex. 2005 Dec. Vol. 15, No. 12. Р. 1848–1854. doi:10.1093/cercor/bhi062.; Ghosh N., Holshouser B., Oyoyo U., Barnes S., Tong K., Ashwal S. Combined Diffusion Tensor and Magnetic Resonance Spectroscopic Imaging Methodology for Automated Regional Brain Analysis: Application in a Normal Pediatric Population // Dev. Neurosci. 2017. Vol. 39, No. 5. Р. 413–429. doi:10.1159/000475545.; Pexman J.H., Barber P.A., Hill M.D., Sevick R.J., Demchuk A.M., Hudon M.E., Hu W.Y., Buchan A.M. Use of the Alberta Stroke Program Early CT Score (ASPECTS) for assessing CT scans in patients with acute stroke // AJNR Am. J. Neuroradiol. 2001. Vol. 22, No. 8. Р. 1534–1542.; Екушева Е.В., Вендрова М.И., Данилов А.Б., Вейн А.М. Вклад правого и левого полушарий головного мозга в полиморфизм и гетерогенность пирамидного синдрома // Журнал неврологии и психиатрии им. C.C.Корсакова. 2004. Т. 104, № 3. С. 8. Ekusheva E.V., Vendrova M.I., Danilov A.B., Vejn A.M. Vklad pravogo i levogo polusharij golovnogo mozga v polimorfizm i geterogennost’ piramidnogo sindroma // Zhurnal nevrologii i psihiatrii im. S.S.Korsakova. 2004. Vol. 104, No. 3. S. 8.

Διαθεσιμότητα: https://radiag.bmoc-spb.ru/jour/article/view/750
https://doi.org/10.22328/2079-5343-2022-13-3-7-17

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2

Academic Journal

MR-MORPHOMETRY AND DTI IN ASSESSING CHANGES OF CORPUS CALLOSUM IN CHILDREN WITH SPASTIC DIPLEGIA ; МР-МОРФОМЕТРИЯ И ДИФФУЗИОННО-ТЕНЗОРНАЯ МРТ В ОЦЕНКЕ ИЗМЕНЕНИЙ МОЗОЛИСТОГО ТЕЛА У ДЕТЕЙ СО СПАСТИЧЕСКОЙ ДИПЛЕГИЕЙ

Συγγραφείς: V. S. Lvov, A. V. Pozdniakov, D. O. Ivanov, T. A. Aleksandrov, T. V. Melashenko, L. M. Makarov, O. F. Pozdniakova, V. Yu. Aleksandrovich, В. С. Львов, А. В. Поздняков, Д. О. Иванов, Т. А. Александров, Т. В. Мелашенко, Л. М. Макаров, О. Ф. Позднякова, В. А. Александрович

Πηγή: Diagnostic radiology and radiotherapy; № 2 (2019); 66-71 ; Лучевая диагностика и терапия; № 2 (2019); 66-71 ; 2079-5343 ; 10.22328/2079-5343-2019-2

Θεματικοί όροι: диффузионно-тензорная МРТ, magnetic resonance imaging, voxel-based morphometry, diffusion tensor imaging, магнитно-резонансная томография, воксель-базированная морфометрия

Περιγραφή αρχείου: application/pdf

Relation: https://radiag.bmoc-spb.ru/jour/article/view/415/346; Пальчик А.Б., Федорова Л.А., Понятишин А.Е. Неврология недоношенных детей. М.: МЕДпресс-информ, 2014. 376 с.; Volpe J.J. Brain injury in premature infants: a complex amalgam of destructive and developmental disturbances // Lancet Neurol. 2009. № 8 (1). Р. 110–124.; Varghese В., Xavier R., Manoj V.C. et al. Magnetic resonance imaging spectrum of perinatal hypoxic-ischemic brain injury // Indian J. Radiol. Imaging. 2016. No. 26 (3). Р. 316–327.; Nosarti C., Rushe T.M., Woodruff P.W. et al. Corpus callosum size and very preterm birth: relationship to neuropsychological outcome // Brain. 2004. No. 9. Р. 2080–2089.; Cooke R.W., Abernethy L.J. Cranial magnetic resonance imaging and school performance in very low birthweight infants in adolescence // Arch. Dis. Child Fetal Neonatal Ed. 1999. Vol. 2. Р. 116–121.; Narberhaus A., Segarra D., Caldu X. et al. Corpus callosum and prefrontal functions in adolescents with history of very preterm birth // Neuropsychologia. 2008. No. 1. Р. 111–116.; Rademaker K.J., Lam J.N., van Haastert I. et al. Larger corpus callosum size with better motor performance in prematurely born children // Semin Perinatol. 2004. No. 4. Р. 279–287.; Зыкин П.А., Ялфимов А.Н., Александров Т.А. и др. Особенности развития мозолистого тела мозга детей по данным МРТ // Педиатр. 2018. Т. 9, № 1. С. 37–48.; Mullen K.M., Vohr B.R., Katz K.H. et al. Preterm birth results in alterations in neural connectivity at age 16 years // Neuroimage. 2011. Nо. 54. Р. 2563–2570.; Andrews J.S., Ben-Shachar M., Yeatman J.D. et al. Reading performance correlates with white-matter properties in preterm and term children // Developmental Medicine & Child Neurology. 2010. Nо. 52. E94–100.; De Bruine F.T.D., Van Wezel-Meijler G., Leijser L.M. et al. Tractography and 2-year Follow-Up in Preterm Infants // Developmental Medicine & Child Neurology. 2013. Nо. 55. P. 427–433.; Allin M, Nosarti C., Narberhaus A. et al. Growth of the corpus callosum in adolescents born preterm // Arch. Pediatr. Adolesc. Med. 2007. Nо. 12. Р. 1183–1189.; Taylor H.G., Filipek P.A., Juranek J. et al. Brain volumes in adolescents with very low birthweight: effects on brain structure and associations with neuropsychological outcomes // Dev. Neuropsychol. 2011. No. 1. Р. 96–117.

Διαθεσιμότητα: https://radiag.bmoc-spb.ru/jour/article/view/415
https://doi.org/10.22328/2079-5343-2019-10-2-66-71

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3

Academic Journal

DTI FOR DIAGNOSING HYPOXICISCHEMIC BRAIN INJURE IN PRETERM NEONATES ; ДИФФУЗИОННО-ТЕНЗОРНАЯ МРТ В ДИАГНОСТИКЕ ПЕРИНАТАЛЬНОГО ГИПОКСИЧЕСКИ-ИШЕМИЧЕСКОГО ПОРАЖЕНИЯ ГОЛОВНОГО МОЗГА У НЕДОНОШЕННЫХ НОВОРОЖДЕННЫХ

Συγγραφείς: V. S. Lvov, A. V. Pozdniakov, D. O. Ivanov, T. V. Melashenko, L. M. Makarov, O. F. Pozdniakova, В. С. Львов, А. В. Поздняков, Д. О. Иванов, Т. В. Мелашенко, Л. М. Макаров, О. Ф. Позднякова

Πηγή: Diagnostic radiology and radiotherapy; № 3 (2019); 53-59 ; Лучевая диагностика и терапия; № 3 (2019); 53-59 ; 2079-5343 ; 10.22328/2079-5343-2019-3

Θεματικοί όροι: диффузионно-тензорная МРТ, periventricular leicomalacia, peri-intraventricular hemorrhage, magnetic resonance imaging, diffusion tensor imaging, перивентрикулярная лейкомаляция, пери-интравентрикулярное кровоизлияние, магнитно-резонансная томография

Περιγραφή αρχείου: application/pdf

Relation: https://radiag.bmoc-spb.ru/jour/article/view/432/357; Varghese В., Xavier R., Manoj V.C. et al. Magnetic resonance imaging spectrum of perinatal hypoxic-ischemic brain injury // Indian J. Radiol. Imaging. 2016. No. 26 (3). Р. 316–327.; Tkach J.A., Merhar S.L., Kline-Fath B.M., Pratt R.G., Loew W.M., Daniels B.R., Dumoulin C.L. MRI in the neonatal ICU: initial experience using a smallfootprint 1.5-T system // Am. J. Roentgenol. 2014. Vol. 202 (1). W95-W105.; Мелашенко Т.В. Критерии церебральной зрелости у недоношенных новорожденных по результатам нейровизуализации // Лучевая диагностика и терапия. 2014. № 3 (5). С. 31–36. [Melashenko T.V. Criteria for cerebral maturity in preterm infants according to the results of neuroimaging // Radiology and radiation therapy, 2014, No. 3 (5), рр. 31–36 (In Russ.)].; Zacharia Z., Zimine S., Lovblad K.O., Warfield S., Thoeny H., Ozdoba C., Bossi E., Kreis R., Boesch C., Schroth G., Hüppi P.S. Early Assessment of Brain Maturation by MR Imaging Segmentation in Neonates and Premature Infants // Am. J. Neuroradiology. 2006. No. 27. Р. 972–977.; Childs A.-M., Ramenghi L.A., Cornette L., Tanner S.F., Arthur R.J., Martinez D., Levene M.I. Cerebral Maturation in Premature Infants: Quantitative Assessment Using MR Imaging // Am. J. Neuroradiology. 2001. No. 22. Р. 1577–1582.; Мелашенко Т.В., Тащилкина Ю.А., Тащилкин А.И. Сравнительный анализ темпов миелинизации головного мозга по данным МРТ у недоношенных новорожденных с гипоксически-ишемической энцефалопатией // Вестник рентгенологии и радиологии. 2013. № 1. Р. 19–24. [Melashenko T.V., Tashchilkina Yu.A., Tashchilkin A.I. Comparative analysis of myelination according to MRI data in preterm infants with hypoxic-ischemic encephalopathy. Journal of Roentgenology and Radiology, 2013, No. 1, рр. 19–24 (In Russ.)].; Murakami A., Morimoto M., Yamada K., Kizu O., Nishimura A., Nishimura T., Sugimoto T. Fiber-tracking techniques can predict the degree of neurologic impairment for periventricular leukomalacia // Pediatrics. 2008. Vol. 122. P. 500–506.; Rose J., Mirmiran М., Butler E.E., Lin C.Y., Barnes P.D., Kermoian R., Stevenson D.K. Neonatal microstructural development of the internal capsule on diffusion tensor imaging correlates with severity of gait and motor deficits // Dev. Med. Child. Neurol. 2007. No. 49. P. 745–750.; De Bruine F.T.D., Van Wezel-Meijler G., Leijser L.M., Steggerda S.J., Van Den Berg-Huysmans A.A., Rijken M., Van Buchem M.A., Van Der Grond J. Tractography and 2-year Follow-Up in Preterm Infants // Developmental Medicine & Child Neurology. 2013. No. 55. P. 427–433.; Ермолина Ю.В. Особенности структурных и функциональных изменений головного мозга у детей со спастическими формами церебрального паралича: дис. … канд. мед. наук. 14.01.08, 14.01.11. М., 2016. 128 с. [Ermolina Yu.V. Features of the structural and functional changes in the brain in children with spastic cerebral palsy. Dissertation for the degree of candidate of medical sciences. 14.01.08, 14.01.11. Moscow, 2016, 128 p. (In Russ.)].; Kinney H.C., Armstrong D.L. Perinatal neuropathology // Graham D.I., Lantos P.E., eds. Greenfield’s Neuropathology. Vol. 7. London, Arnold, 2002.; Kinney H.C., Brody B.A., Kloman A.S., Gilles F.H. Sequence of central nervous system myelination in human infancy. II. Patterns of myelination in autopsied infants // J. Neuropathol. Exp. Neurol. 1988. Vol. 47. Р. 217–234.; Volpe J.J. Brain injury in premature infants: a complex amalgam of destructive and developmental disturbances // Lancet Neurol. 2009. № 8 (1). Р. 110–124.

Διαθεσιμότητα: https://radiag.bmoc-spb.ru/jour/article/view/432
https://doi.org/10.22328/2079-5343-2019-10-3-53-59

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4

Academic Journal

Theoretical substantiation of neuroprotective therapy in glaucoma as an involution-dependent pathology ; Теоретическое обоснование нейропротекторной терапии при глаукоме как инволюционно зависимой патологии

Συγγραφείς: V. P. Erichev, L. A. Panyushkina, В. П. Еричев, Л. А. Панюшкина

Πηγή: National Journal glaucoma; Том 17, № 3 (2018); 86-96 ; Национальный журнал Глаукома; Том 17, № 3 (2018); 86-96 ; 2311-6862 ; 2078-4104

Θεματικοί όροι: митохондриальная дисфункция, Alzheimer’s disease, Parkinson’s disease, neurodegeneration, neuroprotection, apoptosis, oxidative stress, exitotoxicity, diffusion-tensor MRI, mitochondrial dysfunction, болезнь Альцгеймера, болезнь Паркинсона, нейродегенерация, нейропротекция, апоптоз, оксидативный стресс, эксайтотоксичность, диффузионно-тензорная МРТ

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Relation: https://www.glaucomajournal.ru/jour/article/view/224/232; Quigley H.A., Broman A.T. The number of people with glaucoma worldwide in 2010 and 2020. Br J Ophthalmol. 2006; 90(3):262-267. doi:10.1136/bjo.2005.081224.; Peters D., Bengtsson B., Heijl A. Lifetime risk of blindness in open angle glaucoma. Am J Ophthalmol. 2013; 156:724–730. doi:10.1111/aos.12203.; Malihi M., Moura Filho E.R., Hodge D.O., Sit A.J. Long-term trends in glaucoma-related blindness in Olmsted County, Minnesota. Ophthal mology. 2014; 121:134–141. doi:10.1016/j.ophtha.2013.09.003.; Broman A.T., Quigley H.A., West S.K., Katz J. et al. Estimating the rate of progressive visual field damage in those with open-angle glauco ma, from cross-sectional data. Invest Ophthalmol Vis Sci. 2008; 49(1): 66–76. doi:10.1167/iovs.07-0866.; Musch D.C., Gillespie B.W., Lichter P.R., Niziol L.M. et al. Visual field progression in the Collaborative Initial Glaucoma Treatment Study the impact of treatment and other baseline factors. Ophthalmology. 2009; 116(2):200-207. doi:10.1016/j.ophtha.2008.08.051.; Kingwell K. Alzheimer disease: Alzheimer disease biomarkers in healthy individuals can predict cognitive decline several years later. Nat Rev Neurol. 2013; 9(6):300. doi:10.1038/nrneurol.2013.81.; Shapira A.H.V., Olanow C.W. Neuroprotection in Parkinson’s disease: mysteries, myths, and misconceptions. JAMA. 2004; 291(3):358–364. doi:10.1001/jama.291.3.358.; Khan A.O. Genetics of primary open angle glaucoma. Curr Opin Oph thalmol. 2011; 22(5):347–355. doi:10.1097/icu.0b013e32834922d2.; Weber A.J., Chen H., Hubbard W.C., Kaufman P.L. Experimental glau coma and cell size, density, and number in the primate lateral genicu late nucleus. Invest Ophthalmol Vis Sci. 2000; 41(6):1370–1379.; Yücel Y.H., Zhang Q., Weinreb R.N., Kaufman P.L. et al. Effects of retinal ganglion cell loss on magno-, parvo-, koniocellular pathways in the lateral geniculate nucleus and visual cortex in glaucoma. Prog Retin Eye Res. 2003; 22(4):465–481. doi:10.1016/s1350-9462 (03)00026-0.; Chaturvedi N., Hedley-Whyte E.T., Dreyer E.B. Lateral geniculate nucleus in glaucoma. Am J Ophthalmol. 1993; 116(2):182–188. doi:10.1016/s0002-9394 (14) 71283-8.; Gupta N. Human glaucoma and neural degeneration in intracranial optic nerve, lateral geniculate nucleus, and visual cortex. Br J Oph thalmol. 2006; 90(6):674-678. doi:10.1136/bjo.2005.086769.; Алексеев В.Н., Газизова И.Р., Никитин Д.Н., Тубаджи Е., Ринджибал А.М., Фарзад З. Первичная открытоугольная глаукома и дегенеративные изменения в центральных отделах зрительного анализатора. Офтальмологические ведомости. 2012; 5(3):23-28.; Еричев В.П., Туманов В.П., Панюшкина Л.А., Федоров А.А. Сравнительный анализ морфологических изменений в зрительных центрах при первичной глаукоме и болезни Альцгемера. 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