Isolated arterial mucoid intimal thickening lesion in early post-transplant kidney allograft biopsies.

INTRODUCTION: Thrombotic microangiopathy (TMA) on kidney biopsy shows a variable combination of features: arterial mucoid intimal thickening, acellular closure of glomerular capillary loops, fragmented red blood cells, fibrin thrombi, and arterial fibrinoid necrosis. However, some early post-transplant kidney biopsies show only arterial mucoid intimal thickening. We aimed to elucidate the importance of this finding. METHODS: We identified 19 biopsies showing isolated arterial mucoid intimal thickening and compared them with 22 bona fide TMA biopsies identified based on the pathological findings (excluding rejection) (2011-2020). Additionally, delayed graft function (DGF) (n = 237), and no DGF (control, n = 1314) groups were included for survival analysis. RESULTS: Seven of 19 cases with isolated arterial mucoid intimal thickening showed peripheral blood schistocytes but no other systemic features of TMA. Eight patients underwent adjustments in maintenance immunosuppression (mainly calcineurin inhibitors). None of the cases progressed to full-blown TMA on consecutive biopsies. The overall and death-censored graft survival rates in this group were comparable to the DGF group, but significantly better than the TMA group (P = .005 and .04, respectively). CONCLUSIONS: Isolated arterial mucoid intimal thickening in early post-transplant biopsies may be an early/mild form of TMA, probably requiring adjustment in immunosuppressive regimen. Careful exclusion of known causes of TMA, and donor-derived arterial injury are important.

Exosomes: mediators of neurodegeneration, neuroprotection and therapeutics.

Exosomes have emerged as prominent mediators of neurodegenerative diseases where they have been shown to carry disease particles such as beta amyloid and prions from their cells of origin to other cells. Their simple structure and ability to cross the blood-brain barrier allow great opportunity to design a "makeup" with drugs and genetic elements, such as siRNA or miRNA, and use them as delivery vehicles for neurotherapeutics. Their role in neuroprotection is evident by the fact that they are involved in the regeneration of peripheral nerves and repair of neuronal injuries. This review is focused on the role of exosomes in mediating neurodegeneration and neuroprotection.