Characterization of Parvalbumin and Nxph1 Expression in Lumbar Dorsal Root Ganglia by In Situ Hybridization

Al-Anbari, Bahir Rami

22 May 2020

No description available.

Nanoscience

Proprioception

proprioceptors

mechanoreceptors

movement sensing

peripheral nerve injury

proprioceptive genetic markers

Parvalbumin

Nxph1

Development of Evidence-based Clinical Practice Guidelines for the Prevention of Peripheral Neurological Injury During Robotic-assisted Prostatectomies for Patients in the Steep Trendelenburg Position

Wolpert, Tyler

January 2024

No description available.

Nursing

C-Bouton Coverage of Alpha-motoneurons Following PeripheralNerve Injury

Shermadou, Esra Salah

15 August 2013

No description available.

Neurosciences

Neurobiology

peripheral nerve injury

C-boutons

cholinergic terminals

alpha-motoneurons

synaptic stripping

glia

microglia

astrocytes

Sensorimotor Recovery, Functional and Structural Brain Plasticity, and the Development of Chronic Pain Following Upper Limb Peripheral Nerve Transection and Microsurgical Repair

Taylor, Keri S.

16 March 2011

Following peripheral nerve transection and microsurgical repair (PNIr) most patients retain significant sensorimotor impairments, a proportion of which also develop chronic neuropathic pain. Individual psychological factors may contribute to the development, intensity and duration of chronic pain. Furthermore, a large body of evidence has indentified beneficial and maladaptive cortical plasticity following disease or injury. The general aim of this thesis was to determine the extent of sensory and motor recovery, functional and structural brain changes, and the impact of chronic neuropathic pain on sensorimotor outcomes following upper limb PNIr. Towards this main aim a sensorimotor psychophysical assessment (that included psychological assessments), nerve conduction testing, and an MRI session that examined brain function and structure was performed in patients with peripipheral nerve injury induced neuropathic pain (PNI-P) and those with no neuropathic pain (PNI-NP). Nerve conduction testing demonstrated that all patients had incomplete peripheral nerve regeneration, and that PNI-P patients had worse sensory nerve regeneration. Psychophysical assessment confirmed that all PNIr patients had significant sensorimotor deficits. Additionally, deficits on tests of vibration detection, sensorimotor integration, and fine dexterity were significantly greater in PNI-P patients. Psychological measures clearly distinguished PNI-P from PNI-NP and healthy controls (HC). Vibrotactile stimulation of the deafferented territory in PNI-NP patients results in reduced BOLD activation within the primary and secondary somatosensory cortices. Interestingly, the regions of reduced BOLD corresponded with gray matter thinning which was negatively correlated with behavioural measures of sensory recovery. Structural abnormalities were also identified in the right insula. PNI-P patients had thinning within the right middle insula and a corresponding decrease in white matter pathways projecting into/out of that region. PNI-P patients also had white matter abnormalities in pathways feeding into/out of the contralesional primary somatosensory cortex and thalamus. In conclusion, PNIr is clearly associated with sensorimotor impairments and brain plasticity. Furthermore, neuropathic pain is associated with worse peripheral nerve regeneration, sensorimotor deficits, different psychological profiles, and structural alterations in brain regions involved in pain perception and somatosensation. These results provide insight into peripheral regeneration, the development of chronic pain, brain plasticity and structure-function-behavioural relationships following nerve injury and have important therapeutic implications.

peripheral nerve injury

plasticity

functional MRI

diffusion tensor imaging

cortical thickness analysis

psychophysics

chronic neuropathic pain

0317

Sensorimotor Recovery, Functional and Structural Brain Plasticity, and the Development of Chronic Pain Following Upper Limb Peripheral Nerve Transection and Microsurgical Repair

Taylor, Keri S.

16 March 2011

Following peripheral nerve transection and microsurgical repair (PNIr) most patients retain significant sensorimotor impairments, a proportion of which also develop chronic neuropathic pain. Individual psychological factors may contribute to the development, intensity and duration of chronic pain. Furthermore, a large body of evidence has indentified beneficial and maladaptive cortical plasticity following disease or injury. The general aim of this thesis was to determine the extent of sensory and motor recovery, functional and structural brain changes, and the impact of chronic neuropathic pain on sensorimotor outcomes following upper limb PNIr. Towards this main aim a sensorimotor psychophysical assessment (that included psychological assessments), nerve conduction testing, and an MRI session that examined brain function and structure was performed in patients with peripipheral nerve injury induced neuropathic pain (PNI-P) and those with no neuropathic pain (PNI-NP). Nerve conduction testing demonstrated that all patients had incomplete peripheral nerve regeneration, and that PNI-P patients had worse sensory nerve regeneration. Psychophysical assessment confirmed that all PNIr patients had significant sensorimotor deficits. Additionally, deficits on tests of vibration detection, sensorimotor integration, and fine dexterity were significantly greater in PNI-P patients. Psychological measures clearly distinguished PNI-P from PNI-NP and healthy controls (HC). Vibrotactile stimulation of the deafferented territory in PNI-NP patients results in reduced BOLD activation within the primary and secondary somatosensory cortices. Interestingly, the regions of reduced BOLD corresponded with gray matter thinning which was negatively correlated with behavioural measures of sensory recovery. Structural abnormalities were also identified in the right insula. PNI-P patients had thinning within the right middle insula and a corresponding decrease in white matter pathways projecting into/out of that region. PNI-P patients also had white matter abnormalities in pathways feeding into/out of the contralesional primary somatosensory cortex and thalamus. In conclusion, PNIr is clearly associated with sensorimotor impairments and brain plasticity. Furthermore, neuropathic pain is associated with worse peripheral nerve regeneration, sensorimotor deficits, different psychological profiles, and structural alterations in brain regions involved in pain perception and somatosensation. These results provide insight into peripheral regeneration, the development of chronic pain, brain plasticity and structure-function-behavioural relationships following nerve injury and have important therapeutic implications.

peripheral nerve injury

plasticity

functional MRI

diffusion tensor imaging

cortical thickness analysis

psychophysics

chronic neuropathic pain

0317

Characterization of Schwann cells stimulated by DC electric fields

Spencer J Bunn (7038200)

02 August 2019

<p>Schwann cells (SCs) are PNS glia with numerous neuron-supporting functions, including myelination of axons. Although lesser discussed, SCs also fulfill many important roles after peripheral nerve injury (PNI) contributing significantly to the PNS regeneration process. Clusters of congregated SCs (Bands of Bungner) precede axon regeneration and facilitate the growth of extending axons to their distal targets which is particularly important in the lesion area of severed nerves. While this phenomenon occurs naturally, recovery from PNI can still be inadequate, especially in nerve transection or large gap injuries. Current treatments for nerve transection injuries are limited to coaptation of the nerve via sutures or nerve grafts. However, poor functional outcomes or donor site morbidity remain unaddressed problems. At the cellular level, axon pathfinding and extension relies heavily on the interaction between SCs and axonal growth cones. Depletion or removal of SCs at the lesion has been implicated to poor functional outcomes. With their pivotal role throughout nerve regeneration, we theorize axon regeneration can be improved by augmenting the SC population at the site of injury by encouraging migration to the lesion and via expression of morphological phenotypes that imitate the Bands of Bungner. </p> <p>DC electric fields (EFs) have been well studied in the past as a method to modulate cell orientation and migration and within the context of the nervous system, have been used to promote regeneration in lesioned spinal cords. However, very little work has investigated the effects of electrical stimulation on glia, such as SCs. Existing literature is lacking with regards to various aspects of SC responses, including direction of alignment. We hypothesize electrical stimulation can modulate SC behavior to reinforce/replicate behaviors observed within Bands of Bungner, which may be developed into a treatment for victims suffering peripheral nerve injury. </p> <p>We begin the current study with a thorough investigation into electric field modulated SC behavior. Using conventional 2D cell culture we demonstrate SC sensitivity to EFs by analyzing alignment, morphology and migration data. We employed EFs within the physiologic range. Waveforms used were constant DC as well as a 50% duty cycle DC and an oscillating DC. The latter two may prove more appropriate <i>in vivo</i> due to reduced accumulation of cytotoxic byproducts generated at the electrode interfaces. </p> <p>Our results highlight the sensitivity of SCs to DC electric fields of varying waveforms. SCs showed a strong propensity to align perpendicular to the field and display some cathodal migration in 2D cultures. Additional studies with variable cell density revealed cell-cell interaction further enhanced the alignment response. To more closely replicate the nerve microenvironment, a 3D cell culture model of PNI was created. Embedded in matrices, we found SCs displayed weaker migratory and alignment responses compared to 2D results. The direction of galvanotaxis was reversed, with SCs migrating toward the anode. Both alignment and migratory responses have potential applications for PNI. The galvanotactic behavior of SCs could be used to boost the SC population, increasing the number of Bands of Bungner. Cell alignment would be particularly advantageous at the lesion where axon regeneration is most difficult without the physical guidance of endoneurial tubes.</p> <p>This study characterizes SC behavior in applied EFs using conventional 2D and 3D cell culture techniques. We found SCs are sensitive to electric stimulation, supporting the idea that applied EFs could be used to indirectly promote regeneration in damaged peripheral nerve by modulating SC response after injury. Potential applications include generating an EF across damaged nerves to align SCs, especially in the lesioned area, using EFs to induce SC migration to the lesion to increase the number of cells guiding severed axons, and pre-aligning SCs in synthetic nerve grafts.</p>

Medical Devices

Electric fields

Galvanotaxis

Perpendicular

Alignment

Schwann Cell

Peripheral Nerve Injury

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

Neuroprotection and axonal regeneration after peripheral nerve injury

Welin, Dag

January 2010

Following microsurgical reconstruction of injured peripheral nerves, severed axons are able to undergo spontaneous regeneration. However, the functional result is always unsatisfactory with poor sensory recovery and reduced motor function. One contributing factor is the retrograde neuronal death, which occurs in the dorsal root ganglia (DRG) and in the spinal cord. An additional clinical problem is the loss of nerve tissue that often occurs in the trauma zone and which requires “bridges” to reconnect separated nerve ends. The present thesis investigates the extent of retrograde degeneration in spinal motoneurons and cutaneous and muscular afferent DRG neurons after permanent axotomy and following treatment with N-acetyl-cysteine (NAC). In addition, it examines the survival and growth-promoting effects of nerve reconstructions performed by primary repair and peripheral nerve grafting in combination with NAC treatment. In adult rats, cutaneous sural and muscular medial gastrocnemius DRG neurons and spinal motoneurons were retrogradely labeled with fluorescent tracers from the homonymous transected nerves. Survival of labeled neurons was assessed at different time points after nerve transection, ventral root avulsion and ventral rhizotomy. Axonal regeneration was evaluated using fluorescent tracers after sciatic axotomy and immediate nerve repair. Intraperitoneal or intrathecal treatment with NAC was initiated immediately after nerve injury or was delayed for 1-2 weeks. Counts of labeled gastrocnemius DRG neurons did not reveal any significant retrograde cell death after nerve transection. Sural axotomy induced a delayed loss of DRG cells, which amounted to 43- 48% at 8-24 weeks postoperatively. Proximal transection of the sciatic nerve at 1 week after initial axonal injury did not further increase retrograde DRG degeneration, nor did it affect survival of corresponding motoneurons. In contrast, rhizotomy and ventral root avulsion induced marked 26- 53% cell loss among spinal motoneurons. Primary repair or peripheral nerve grafting supported regeneration of 53-60% of the motoneurons and 47-49% of the muscular gastrocnemius DRG neurons at 13 weeks postoperatively. For the cutaneous sural DRG neurons, primary repair or peripheral nerve grafting increased survival by 19-30% and promoted regeneration of 46-66% of the cells. Regenerating sural and medial gastrocnemius DRG neurons upregulate transcription of peripherin and activating transcription factor 3. The gene expression of the structural neurofilament proteins of high molecular weight was significantly downregulated following injury in both regenerating and non-regenerating sensory neurons. Treatment with NAC was neuroprotective for spinal motoneurons after ventral rhizotomy and avulsion, and sural DRG neurons after sciatic nerve injury. However, combined treatment with nerve graft and NAC had significant additive effect on neuronal survival and also increased the number of sensory neurons regenerating across the graft. In contrast, NAC treatment neither affected the number of regenerating motoneurons nor the number of myelinated axons in the nerve graft and in the distal nerve stump. In summary, the present results demonstrate that cutaneous sural sensory neurons are more sensitive to peripheral nerve injury than muscular gastrocnemius DRG cells. Moreover, the retrograde loss of cutaneous DRG cells taking place despite immediate nerve repair would still limit recovery of cutaneous sensory functions. Experimental data also show that NAC provides a highly significant degree of neuroprotection in animal models of adult nerve injury and could be combined with nerve grafting to further attenuate retrograde neuronal death and to promote functional regeneration.

Hand surgery

Handkirurgi

Anatomy

Anatomi

Mechanisms controlling the cell body response to axon injury in dorsal root ganglion neurons

Bani Hammad, Rasheed Ahmed

22 June 2010

Successful axon regeneration appears to depend on the development of an injury response. Dorsal root ganglion neurons exemplify the necessity of this injury response in a unique way. Peripheral nerve transection leads to development of an injury response and successful regeneration whereas central root transection does neither. The injury response may involve extracellular and intracellular pathways. To investigate the extraneuronal influences, we performed nerve transection of either the central or peripheral axon branches and studied the expression of GAP-43, a key growth associated protein, and the transcription factors ATF3, c-Jun, and STAT3. Our results show that the responses to peripheral versus central nerve transection are fundamentally different. Peripheral but not central nerve transection increases GAP-43, ATF3, and c-Jun expression. STAT3, however, is upregulated as a result of central but not peripheral nerve transection. To investigate potential intracellular signalling pathways, we applied FGF-2, an extracellular mitogen, or an analog of cAMP, an intracellular second messenger to the cut end of the peripheral axon. Our results indicate that FGF-2 and cAMP act as activators of GAP-43 expression. On the other hand, FGF-2 and cAMP act to downregulate the expression of ATF3. FGF-2 upregulates c-Jun and the activated form of STAT3. Paradoxically, the regulation of GAP-43 expression by cAMP or by FGF-2 in vivo shows opposing results from the previously reported in vitro studies. Our present results suggest that the peripheral nerve injury response may be governed by at least three different signalling pathways.

STAT3

ATF3

cAMP

GAP-43

transcription factors

peripheral nerve injury

transection

dorsal root ganglion

sensory neurons

FGF-2

c-Jun

Mechanisms controlling the cell body response to axon injury in dorsal root ganglion neurons

Bani Hammad, Rasheed Ahmed

22 June 2010

Successful axon regeneration appears to depend on the development of an injury response. Dorsal root ganglion neurons exemplify the necessity of this injury response in a unique way. Peripheral nerve transection leads to development of an injury response and successful regeneration whereas central root transection does neither. The injury response may involve extracellular and intracellular pathways. To investigate the extraneuronal influences, we performed nerve transection of either the central or peripheral axon branches and studied the expression of GAP-43, a key growth associated protein, and the transcription factors ATF3, c-Jun, and STAT3. Our results show that the responses to peripheral versus central nerve transection are fundamentally different. Peripheral but not central nerve transection increases GAP-43, ATF3, and c-Jun expression. STAT3, however, is upregulated as a result of central but not peripheral nerve transection. To investigate potential intracellular signalling pathways, we applied FGF-2, an extracellular mitogen, or an analog of cAMP, an intracellular second messenger to the cut end of the peripheral axon. Our results indicate that FGF-2 and cAMP act as activators of GAP-43 expression. On the other hand, FGF-2 and cAMP act to downregulate the expression of ATF3. FGF-2 upregulates c-Jun and the activated form of STAT3. Paradoxically, the regulation of GAP-43 expression by cAMP or by FGF-2 in vivo shows opposing results from the previously reported in vitro studies. Our present results suggest that the peripheral nerve injury response may be governed by at least three different signalling pathways.

STAT3

ATF3

cAMP

GAP-43

transcription factors

peripheral nerve injury

transection

dorsal root ganglion

sensory neurons

FGF-2

c-Jun