The corticospinal tract (CST) is a major neural tract for mo- tor function in the human brain. In addition, CST is mainly concerned with execution of movement of the hand (Jang, 2014). However, few studies are rep...The corticospinal tract (CST) is a major neural tract for mo- tor function in the human brain. In addition, CST is mainly concerned with execution of movement of the hand (Jang, 2014). However, few studies are reported on the mecha- nism underlying CST recovery after traumatic brain injury (Seo and Jang, 2015). In this study, we report on a case that showed recovery of an injured CST by traumatic axonal injury (TAI) at subcortical white matter, as detected on fol- low-up diffusion tensor tractography (DTT).展开更多
Subcortical ischemic white matter injury(SIWMI),pathological correlate of white matter hyperintensities or leukoaraiosis on magnetic resonance imaging,is a common cause of cognitive decline in elderly.Despite its high...Subcortical ischemic white matter injury(SIWMI),pathological correlate of white matter hyperintensities or leukoaraiosis on magnetic resonance imaging,is a common cause of cognitive decline in elderly.Despite its high prevalence,it remains unknown how various components of the white matter degenerate in response to chronic ischemia.This incomplete knowledge is in part due to a lack of adequate animal model.The current review introduces various SIWMI animal models and aims to scrutinize their advantages and disadvantages primarily in regard to the pathological manifestations of white matter components.The SIWMI animal models are categorized into 1)chemically induced SIWMI models,2)vascular occlusive SIWMI models,and 3)SIWMI models with comorbid vascular risk factors.Chemically induced models display consistent lesions in predetermined areas of the white matter,but the abrupt evolution of lesions does not appropriately reflect the progressive pathological processes in human white matter hyperintensities.Vascular occlusive SIWMI models often do not exhibit white matter lesions that are sufficiently unequivocal to be quantified.When combined with comorbid vascular risk factors(specifically hypertension),however,they can produce progressive and definitive white matter lesions including diffuse rarefaction,demyelination,loss of oligodendrocytes,and glial activation,which are by far the closest to those found in human white matter hyperintensities lesions.However,considerable surgical mortality and unpredictable natural deaths during a follow-up period would necessitate further refinements in these models.In the meantime,in vitro SIWMI models that recapitulate myelinated white matter track may be utilized to study molecular mechanisms of the ischemic white matter injury.Appropriate in vivo and in vitro SIWMI models will contribute in a complementary manner to making a breakthrough in developing effective treatment to prevent progression of white matter hyperintensities.展开更多
基金supported by the National Research Foundation(NRF) of Korea Grant funded by the Korean Government(MSIP)(No.2015R1A2A2A01004073)
文摘The corticospinal tract (CST) is a major neural tract for mo- tor function in the human brain. In addition, CST is mainly concerned with execution of movement of the hand (Jang, 2014). However, few studies are reported on the mecha- nism underlying CST recovery after traumatic brain injury (Seo and Jang, 2015). In this study, we report on a case that showed recovery of an injured CST by traumatic axonal injury (TAI) at subcortical white matter, as detected on fol- low-up diffusion tensor tractography (DTT).
基金This work was supported by the National Research Foundation of Korea(NRF)grants funded by the Korea government(MSIT,Ministry of Science and ICT)(NRF-2018M3A9E8023853(to JYC)NRF-2018R1C1B6006145(to JYC)NRF-2018R1A2A1A05020292(to BGK)and NRF-2019R1A5A2026045(to JYC and BGK).
文摘Subcortical ischemic white matter injury(SIWMI),pathological correlate of white matter hyperintensities or leukoaraiosis on magnetic resonance imaging,is a common cause of cognitive decline in elderly.Despite its high prevalence,it remains unknown how various components of the white matter degenerate in response to chronic ischemia.This incomplete knowledge is in part due to a lack of adequate animal model.The current review introduces various SIWMI animal models and aims to scrutinize their advantages and disadvantages primarily in regard to the pathological manifestations of white matter components.The SIWMI animal models are categorized into 1)chemically induced SIWMI models,2)vascular occlusive SIWMI models,and 3)SIWMI models with comorbid vascular risk factors.Chemically induced models display consistent lesions in predetermined areas of the white matter,but the abrupt evolution of lesions does not appropriately reflect the progressive pathological processes in human white matter hyperintensities.Vascular occlusive SIWMI models often do not exhibit white matter lesions that are sufficiently unequivocal to be quantified.When combined with comorbid vascular risk factors(specifically hypertension),however,they can produce progressive and definitive white matter lesions including diffuse rarefaction,demyelination,loss of oligodendrocytes,and glial activation,which are by far the closest to those found in human white matter hyperintensities lesions.However,considerable surgical mortality and unpredictable natural deaths during a follow-up period would necessitate further refinements in these models.In the meantime,in vitro SIWMI models that recapitulate myelinated white matter track may be utilized to study molecular mechanisms of the ischemic white matter injury.Appropriate in vivo and in vitro SIWMI models will contribute in a complementary manner to making a breakthrough in developing effective treatment to prevent progression of white matter hyperintensities.