peripheral nerve injury

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Enhanced BDNF and ROS in Mucosa of Lower Motor Neuron Lesioned Dog Bladder Following Somatic Motor Nerve Transfer

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AUTHORS

Nagat Frara, Kais Jawawdeh, Dania Giaddui, Istvan P. Tamas, Ryan P. Gares, Elizabeth R. McGonagle, Brendan A. Hilliard, Mikhail A. Kolpakov, Lewis Bright-Rowe, Alan S. Braverman, Justin M. Brown, Michael R. Ruggieri, Sr., Mary F. Barbe

ABSTRACT

Neurotrophic factors and reactive oxygen species (ROS) modulate neuronal plasticity. In a model of a lower motor neuron lesioned bladder, somatic nerve transfer was used as a reinnervation strategy. Levels of neurotrophins, ROS, and TNF-α in bladder mucosa and muscle layers collected from three groups of adult female dogs: (1) Decentralized, via bilateral transection of coccygeal and sacral spinal roots, lumbar 7 dorsal roots, and hypogastric nerves, then 6–21 mo recovery; (2) reinnervated (ObNT-Reinn), after similar decentralization for 12 mo, then bilateral obturator-to-vesical nerve transfer and 8–12 mo recovery; and (3) Controls. In mucosa, BDNF and ROS levels were highest in ObNT-Reinn bladders, GDNF and TNF-α levels were restored to Control levels in ObNT-Reinn bladders (lowest in Decentralized). NT-3 and ARTN were lower in ObNT-Reinn and Decentralized bladders versus Controls. In muscle, ROS was lower in ObNT-Reinn muscle versus Controls. BDNF mucosa levels correlated with bladder axonal density and detrusor layer thickness; and GDNF mucosal correlated with bladder contraction after vesical or transferred obturator nerve electrical stimulation, as did BDNF and GDNF muscle levels. The increased BDNF and GDNF in bladders that underwent somatic nerve transfer with subsequent recovery suggest that BDNF and GDNF may help promote the reestablishment of bladder innervation.

Ultrastructural effects of nerve growth factor and betamethasone on nerve regeneration after experimental nerve injury

AUTHORS

Leman Sencar, Mustafa Güven, Dilek Şaker, Tuğçe Sapmaz, Abdullah Tuli, and Sait Polat

ABSTRACT

Peripheral nerve injuries (PNI) are an important health problem in the world. In this study, the effects of nerve growth factor (NGF) and betamethasone on nerve regeneration after sciatic nerve crush injury were examined by footprint analysis, electron microscopic, histomorphometric, and biochemical methods. Fifty Wistar rats were divided into five groups as intact control, experimental control, NGF, betamethasone, and NGF+betamethasone combined treatment groups. After the injury, betamethasone was subcutaneously injected into the lesion area of the treatment groups three times during the first day. NGF was subcutaneously injected into the lesion area of treatment groups for 14 days. Footprint analysis was made on 7, 14, 21, 28, and 35 days and after 6 weeks, tissue samples were obtained from all groups. In the experimental control group, there were severe degenerative changes in most of the axons and myelin sheaths of the nerve fibers. Moreover, an increase of MDA levels and a decrease in SOD activities were found in this group. On the other hand, malondialdehyde (MDA) levels decreased, superoxide dismutase (SOD) activities increased and significant motor functional recovery were found in the combined treatment group. The number of axons, axon diameters, and myelin thickness were significantly greater in the combined treatment group when compared with experimental control and other treatment groups. It was thought that nerve regenerative effects of NGF and anti-inflammatory and/or anti-edematous effects of betamethasone could induce functional recovery in the combined treatment group. In conclusion, combined therapy of NGF and betamethasone may be an effective approach for the treatment of PNI.