Preclinical use of longitudinal MRI for screening the efficacy of S-nitrosoglutathione in treating spinal cord injury.

PURPOSE: To evaluate the therapeutic efficacy of S-nitrosoglutathione (GSNO) in spinal cord injury (SCI) using in vivo MRI in combination with neuorobehavioral testing and postmortem tissue analysis. MATERIALS AND METHODS: Sixteen female rats were mildly injured at the vertebral T10 level and randomized into control (n = 8) and GSNO-treatment (n = 8) groups. GSNO was delivered at 0.05 mg/kg dose in saline by means of tail vein at 1 hr postinjury and then given orally on the following days. On postinjury days 1, 3, 7, and 28, the rats were tested behaviorally, then scanned using sagittal T2-weighted MRI for the quantification of lesion, edema, and hemorrhagic regions at the injury site. Excised cords were analyzed using histology and immunohistochemistry. RESULTS: Treatment with GSNO was feasible in rats with SCI. On the average, the GSNO group at each scan day 1, 3, 7, and 28 exhibited better functional recovery as indicated by the behavioral performance of 52%, 33%, 19%, and 18%, and had smaller lesions of -4%, -16%, -20%, and -17% compared with the controls, respectively. Edema trend was parallel to the lesion volumes in both groups. Ex vivo data demonstrated that GSNO plays a role in neuronal tissue preservation and sparing. CONCLUSION: The data collectively provided the preliminary evidence that the injured rats responded favorably to GSNO treatment. Longitudinal MRI provides critical quantitative information regarding the changes in lesion properties, which helps evaluating the efficacy of an exogenous intervention in SCI.

Loss of primary cilia upregulates renal hypertrophic signaling and promotes cystogenesis.

Primary cilia dysfunction alters renal tubular cell proliferation and differentiation and associates with accelerated cyst formation in polycystic kidney disease. However, the mechanism leading from primary ciliary dysfunction to renal cyst formation is unknown. We hypothesize that primary cilia prevent renal cyst formation by suppressing pathologic tubular cell hypertrophy and proliferation. Unilateral nephrectomy initiates tubular cell hypertrophy and proliferation in the contralateral kidney and provides a tool to examine primary cilia regulation of renal hypertrophy. Conditional knockout of the primary cilia ift88 gene leads to delayed, adult-onset renal cystic disease, which provides a window of opportunity to conduct unilateral nephrectomy and examine downstream kinetics of renal hypertrophy and cyst formation. In wild-type animals, unilateral nephrectomy activated the mTOR pathway and produced appropriate structural and functional hypertrophy without renal cyst formation. However, in ift88 conditional knockout animals, unilateral nephrectomy triggered increased renal hypertrophy and accelerated renal cyst formation, leading to renal dysfunction. mTOR signaling also increased compared with wild-type animals, suggesting a mechanistic cascade starting with primary ciliary dysfunction, leading to excessive mTOR signaling and renal hypertrophic signaling and culminating in cyst formation. These data suggest that events initiating hypertrophic signaling, such as structural or functional loss of renal mass, may accelerate progression of adult polycystic kidney disease toward end-stage renal disease.

Evaluating regional blood spinal cord barrier dysfunction following spinal cord injury using longitudinal dynamic contrast-enhanced MRI.

BACKGROUND: In vivo preclinical imaging of spinal cord injury (SCI) in rodent models provides clinically relevant information in translational research. This paper uses multimodal magnetic resonance imaging (MRI) to investigate neurovascular pathology and changes in blood spinal cord barrier (BSCB) permeability following SCI in a mouse model of SCI. METHODS: C57BL/6 female mice (n = 5) were subjected to contusive injury at the thoracic T11 level and scanned on post injury days 1 and 3 using anatomical, dynamic contrast-enhanced (DCE-MRI) and diffusion tensor imaging (DTI). The injured cords were evaluated postmortem with histopathological stains specific to neurovascular changes. A computational model was implemented to map local changes in barrier function from the contrast enhancement. The area and volume of spinal cord tissue with dysfunctional barrier were determined using semi-automatic segmentation. RESULTS: Quantitative maps derived from the acquired DCE-MRI data depicted the degree of BSCB permeability variations in injured spinal cords. At the injury sites, the damaged barriers occupied about 70% of the total cross section and 48% of the total volume on day 1, but the corresponding measurements were reduced to 55% and 25%, respectively on day 3. These changes implied spatio-temporal remodeling of microvasculature and its architecture in injured SC. Diffusion computations included longitudinal and transverse diffusivities and fractional anisotropy index. Comparison of permeability and diffusion measurements indicated regions of injured cords with dysfunctional barriers had structural changes in the form of greater axonal loss and demyelination, as supported by histopathologic assessments. CONCLUSION: The results from this study collectively demonstrated the feasibility of quantitatively mapping regional BSCB dysfunction in injured cord in mouse and obtaining complementary information about its structural integrity using in vivo DCE-MRI and DTI protocols. This capability is expected to play an important role in characterizing the neurovascular changes and reorganization following SCI in longitudinal preclinical experiments, but with potential clinical implications.