BACKGROUND: We have previously reported that adult enteric glia (EG) facilitate the growth of transected dorsal root axons into the uninjured spinal cord to form functional connections with their targets. OBJECTIVE...BACKGROUND: We have previously reported that adult enteric glia (EG) facilitate the growth of transected dorsal root axons into the uninjured spinal cord to form functional connections with their targets. OBJECTIVE: The present study investigated the effects of EG on spinal cord function, tissue injury, and axonal regeneration following transplantation into injured rat spinal cords, according to histological and functional outcomes. DESIGN, TIME AND SETTING: A randomized controlled animal experiment was performed at McMaster University, Canada from January 2006 to March 2008. MATERIALS: EG were isolated from rat intestine, METHODS: One week following spinal cord crush, female Wistar rats were injected with an EG suspension (2 μL, 1 × 10^5/μL, n = 10) or with the same volume of fresh culture medium alone (control animals, n = 11). The third group did not receive any injection following laminectomy and served as the sham-operated controls (n = 5). MAIN OUTCOME MEASURES: Behavior was tested prior to transplantation and weekly following transplantation, with nine behavioral examinations in total. Open field, hind limb placement response foot orientation response, and inclined plane test were utilized. Immediately following the final behavioral examination, spinal cord T9 to L1 segments were harvested for immunohistochemical and hematoxylin-eosin staining to determine astroglial scarring, axonal regeneration and spinal cord lesion size. RESULTS: Rats with EG transplantation exhibited significantly better locomotor function with reduced tissue damage, compared with the control rats. Cystic cavities were present 2 months after injury in spinal cords from both control groups. In contrast, rats injected with EG did not present with cystic lesions. In addition, the injury site consisted of cellular material and nerve fibers, and axonal regeneration was apparent, with dense labeling of neurofilament-positive axons within the injury site. Moreover, regenerating axons were intimately associated with transplanted EG. CONCLUSION: These data indicated that EG enhanced functional improvement, which was associated with reduced tissue damage and axonal regeneration following transplantation into injured spinal cords.展开更多
Occupational exposure to whole-body vibration is associated with the develop-ment of musculoskeletal,neurological,and other ailments.Low back pain and other spine disorders are prevalent among those exposed to whole-b...Occupational exposure to whole-body vibration is associated with the develop-ment of musculoskeletal,neurological,and other ailments.Low back pain and other spine disorders are prevalent among those exposed to whole-body vibration in occupational and military settings.Although standards for limiting exposure to whole-body vibration have been in place for decades,there is a lack of understanding of whole-body vibration-associated risks among safety and healthcare profession-als.Consequently,disorders associated with whole-body vibration exposure remain prevalent in the workforce and military.The relationship between whole-body vibra-tion and low back pain in humans has been established largely through cohort stud-ies,for which vibration inputs that lead to symptoms are rarely,if ever,quantified.This gap in knowledge highlights the need for the development of relevant in vivo,ex vivo,and in vitro models to study such pathologies.The parameters of vibrational stimuli(eg,frequency and direction)play critical roles in such pathologies,but the specific cause-and-effect relationships between whole-body vibration and spinal pa-thologies remain mostly unknown.This paper provides a summary of whole-body vibration parameters;reviews in vivo,ex vivo,and in vitro models for spinal patholo-gies resulting from whole-body vibration;and offers suggestions to address the gaps in translating injury biomechanics data to inform clinical practice.展开更多
基金Neurological Technologies and Canadian Spinal Research Organization
文摘BACKGROUND: We have previously reported that adult enteric glia (EG) facilitate the growth of transected dorsal root axons into the uninjured spinal cord to form functional connections with their targets. OBJECTIVE: The present study investigated the effects of EG on spinal cord function, tissue injury, and axonal regeneration following transplantation into injured rat spinal cords, according to histological and functional outcomes. DESIGN, TIME AND SETTING: A randomized controlled animal experiment was performed at McMaster University, Canada from January 2006 to March 2008. MATERIALS: EG were isolated from rat intestine, METHODS: One week following spinal cord crush, female Wistar rats were injected with an EG suspension (2 μL, 1 × 10^5/μL, n = 10) or with the same volume of fresh culture medium alone (control animals, n = 11). The third group did not receive any injection following laminectomy and served as the sham-operated controls (n = 5). MAIN OUTCOME MEASURES: Behavior was tested prior to transplantation and weekly following transplantation, with nine behavioral examinations in total. Open field, hind limb placement response foot orientation response, and inclined plane test were utilized. Immediately following the final behavioral examination, spinal cord T9 to L1 segments were harvested for immunohistochemical and hematoxylin-eosin staining to determine astroglial scarring, axonal regeneration and spinal cord lesion size. RESULTS: Rats with EG transplantation exhibited significantly better locomotor function with reduced tissue damage, compared with the control rats. Cystic cavities were present 2 months after injury in spinal cords from both control groups. In contrast, rats injected with EG did not present with cystic lesions. In addition, the injury site consisted of cellular material and nerve fibers, and axonal regeneration was apparent, with dense labeling of neurofilament-positive axons within the injury site. Moreover, regenerating axons were intimately associated with transplanted EG. CONCLUSION: These data indicated that EG enhanced functional improvement, which was associated with reduced tissue damage and axonal regeneration following transplantation into injured spinal cords.
基金Engineer Research and Development Center,Grant/Award Number:W912HZ-17-C-0021。
文摘Occupational exposure to whole-body vibration is associated with the develop-ment of musculoskeletal,neurological,and other ailments.Low back pain and other spine disorders are prevalent among those exposed to whole-body vibration in occupational and military settings.Although standards for limiting exposure to whole-body vibration have been in place for decades,there is a lack of understanding of whole-body vibration-associated risks among safety and healthcare profession-als.Consequently,disorders associated with whole-body vibration exposure remain prevalent in the workforce and military.The relationship between whole-body vibra-tion and low back pain in humans has been established largely through cohort stud-ies,for which vibration inputs that lead to symptoms are rarely,if ever,quantified.This gap in knowledge highlights the need for the development of relevant in vivo,ex vivo,and in vitro models to study such pathologies.The parameters of vibrational stimuli(eg,frequency and direction)play critical roles in such pathologies,but the specific cause-and-effect relationships between whole-body vibration and spinal pa-thologies remain mostly unknown.This paper provides a summary of whole-body vibration parameters;reviews in vivo,ex vivo,and in vitro models for spinal patholo-gies resulting from whole-body vibration;and offers suggestions to address the gaps in translating injury biomechanics data to inform clinical practice.
