Unterschiedliche Wirkungen der TNF-alpha-Rezeptoren auf De- und Regeneration peripherer NervenEine Studie an TNF-alpha-Rezeptor-Knockoutmäusen in zwei verschiedenen Tiermodellen für Nervenläsionen / Different effects of TNF-alpha-receptors on de- and regeneration of the peripheral nerveA study in TNF-alpha-receptor-knockout-mice in two different models of nerve injury

Stallforth, Sabine

January 2007

Noch immer ist die Behandlung von Neuropathien mit den gängigen therapeutischen Mitteln für viele Patienten sehr unbefriedigend. Als erfolgsversprechender therapeutischer Ansatz werden zur Zeit Wege erforscht, welche direkt in die molekularen Entstehungsmechanismen pathologischer Veränderungen und regenerationsfördernder Mechanismen eingreifen, um dadurch eine Heilung von Nervenschäden zu ermöglichen. Bisher sind die Erkenntnisse über diese Mechanismen nicht vollständig genug, um daraus eine sichere Behandlungsmöglichkeit abzuleiten. Wegweisende Erkenntnisse deuten sich allerdings durch Studien von unterschiedlichen Vertretern des Zytokinnetzwerkes an - darunter auch TNF-alpha - welche als molekulare Ursache neuropathischer Veränderungen diskutiert werden. In dieser Studie wurde an Knockoutmäusen der Einfluss des jeweiligen TNF-alpha-Rezeptors auf morphologische Veränderungen nach CCI (Chronic constriction injury) und Crush-Verletzung des N. ischiadicus untersucht. Nach 3,7,15 und 36 Tagen (CCI) bzw. 3,7 und 28 Tagen (Crush) wurden in Methylenblau gefärbten Semidünnschnitten intakte und degenerierte Nervenfasern, Makrophagen, Angioproliferation, Ödembildung udn Veränderung des Anteils nicht neuronaler Zellen lichtmikroskopisch beurteilt. Zusätzlich wurden Mac-1+ Makrophagen immunzytochemisch erfasst. Die Ergebnisse zeigten in beiden Modellen und bei beiden Knockouttypen eine starke axonale Schädigung, die von einer großen endoneuroalen Makrophagenansammlung begleitet war. Bei TNF-R1-/- Mäusen war eine stärkere und verlängerte Degeneration mit entsprechend höheren Makrophagenzahlen sichtbar. In den Immunzytochemischen Färbungen wiesen die TNF-R1-/- Mäuse hingegen den geringsten Makropahgenanteil auf.Trotz der starken Schädigung war die anschließende Regeneration im Gegensatz zu WT und TNF-R2-/- Mäusen besser. Die Ödembildung war bei den TNF-R2-/- nach CCI besonders stark ausgeprägt und von einer schlechten Regeneration gefolgt. Während die gefundenen Daten auf eine Beteiligung beider Rezeptoren während degenerativer Prozesse hindeuten, scheint insbesondere TNF-R2 regenerationsfördernde Effekte zu vermitteln. / Current Treatment of neuropathic disorders is still dissatisfactory for many patients. A promising approach is the investigation of agents that directly interfere with molecular development of pathologic changes and regeneration. Up to now, consolidated findings of the underlying mechanisms are not yet sufficent to allow therapeutic intervention. Pathbreaking findings come from studies investigating different agents of the cytokine network - as e.g. TNF-alpha - that are discussed as molecular cause of neuropathic changes. This study investigated the influence of both TNF-alpha-receptors on morphologic changes after CCI (chronic constriction injury) and crush-injury of the sciatic nerve of TNF-R-knockoutmice. After 3,7,15 and 36 days (CCI), and 3,7 and 28 respectively (Crush),intact and degenerating nerve fibers, macrophages, angioproliferation, development of edema and changes in the amount of non-neuronal cells were acquired by light microscopy of toluidin-stained semithin sections. Additionally Mac-1+ macrophages were acquired via immuncytochemically stained sections. The results showed strong axonal damage in both knockout-types accompanied by large amounts of endoneurial macrophages. TNF-R1-/-mice showed a longer degeneration phase including respectively higher amounts of macrophages. In contrast the TNF-R1-/-mice revealed the fewest amount of macrophages in immunocytochemical sections. Despite the strong damage better nerve regeneration was observed compared to WT and TNF-R2-/-mice. Formation of edema was pronounced in TNF-R2-/- after CCI and followed by poorly regeneration. Whereas these findings point to a participation of both receptors in degeneration, TNF-R2 seems to support regeneration.

peripheral nerve

TNF

TNF-R1

TNF-R2

TNF-receptors

knockout

Crush

CCI

sciatic nerve injury

Cytokines

regeneration

degeneration

ddc:610

Effects of electrical stimulation and testosterone on regeneration-associated gene expression and functional recovery in a rat model of sciatic nerve crush injury

Meadows, Rena Marie

January 2014

Indiana University-Purdue University Indianapolis (IUPUI) / Although peripheral motoneurons are phenotypically endowed with robust regenerative capacity, functional recovery is often suboptimal following peripheral nerve injury (PNI). Research to date indicates that the greatest success in achieving full functional recovery will require the use of a combinatorial approach that can simultaneously target different aspects of the post-injury response. In general, the concept of a combinatorial approach to neural repair has been established in the scientific literature but has yet to be successfully applied in the clinical situation. Emerging evidence from animal studies supports the use of electrical stimulation (ES) and testosterone as one type of combinatorial treatment after crush injury to the facial nerve (CN VII). With the facial nerve injury model, we have previously demonstrated that ES and testosterone target different stages of the regeneration process and enhance functional recovery after facial nerve crush injury. What is currently unknown, but critical to determine, is the impact of a combinatorial treatment strategy of ES and testosterone on functional recovery after crush injury to the sciatic nerve, a mixed sensory and motor spinal nerve which is one of the most serious PNI clinical problems. The results of the present study indicate that either treatment alone or in combination positively impact motor recovery. With regard to molecular effects,single and combinatorial treatments differentially alter the expression of regeneration-associated genes following sciatic nerve crush injury relative to facial nerve injury. Thus, our data indicate that not all injuries equally respond to treatment. Furthermore, the results support the importance of treatment strategy development in an injury-dependent manner and based upon the functional characteristics of spinal vs. cranial nerves.

motoneuron

sciatic nerve injury

testosterone

electrical stimulation

Nerves -- Regeneration -- Research

Testosterone -- Research

Facial nerve -- Wounds and injuries

Sciatic nerve -- Wounds and injuries

Spinal nerves -- Research

Nerves, Cranial -- Research

Electromyography -- Research

Gene expression