Enxerto com tubo de polietileno poroso preenchido com gordura autóloga no reparo de nervo periférico associado com protocolo de imersão em câmara hiperbárica

Toledo, Gustavo Lopes

16 July 2015

Os nervos periféricos são extensões do sistema nervoso central e responsável pela interação das atividades entre as extremidades, em suas funções sensitivas e motoras. São vulneráveis aos mesmos tipos de traumas que afetam outros tecidos: contusão, compressão, esmagamento, estiramento, avulsão e laceração. As lesões de nervos periféricos situam-se entre as mais incapacitantes que acometem indivíduos em idade produtiva, em face dos múltiplos aspectos concernentes às sequelas deste tipo de afecção. Desta forma, a interrupção de continuidade da estrutura do nervo, como no caso da neurotmese, por algum tipo de trauma, resulta na interrupção de transmissão dos impulsos nervosos e na desorganização de suas atividades funcionais. Por meio da utilização da microcirurgia foi possível desenvolver técnicas reparadoras que vão desde simples neurorrafia término-terminal até sofisticados procedimentos cirúrgicos com a utilização de enxertos de nervos, veias e artérias invertidas, tubos sintéticos de materiais variados, tais como silicone e polietileno. Outro aspecto que intriga pesquisadores de todo mundo é a utilização de fatores neurogênicos capazes de acelerar ou melhorar a regeneração de nervos periféricos. A gordura autóloga tem sido continuamente referenciada pela sua abundante oferta, no próprio sitio cirúrgico, apresentando resultados promissores, visto que a adventícia dos vasos é constituída por tecido conjuntivo frouxo, rico em adipócitos. Assim, em um trauma, os neuritos oriundos do coto proximal do nervo lesado, ficam diretamente em contato com esses adipócitos. Seguindo este raciocínio, e com base em trabalhos anteriores onde foi usada veia preenchida com músculo esquelético a fresco como enxerto, decidiu-se testar a possibilidade de crescimento axonal por meio de enxerto com tubo de polietileno preenchido por tecido adiposo autólogo associado a protocolo de imersão em câmara hiperbárica, por meio de um estudo Randomizado Controlado. Para tanto utilizou-se um tubo com 12 mm de comprimento por 0,25 mm de diâmetro, com poros de 80 μm de diâmetro, preenchido com tecido adiposo in natura retirado das adjacências do referido nervo, na tentativa de se recuperar o nervo isquiático. Os resultados morfométricos demonstraram que, os grupos experimentais com e sem preenchimento de gordura tiveram resultados, do ponto de vista morfométrico e funcional sem diferenças estatisticamente significantes, contudo, quando estes foram confrontados ao grupo controle final, apresentaram diferenças estatisticamente significantes. Já relevando a avaliação funcional, por meio do Catwalk, constatou-se que não houve diferença estatisticamente significante entre os grupos experimentais, mas teve diferença ao comparar com o grupo controle final, Diante das evidências encontradas e apoiados na literatura pode-se concluir que a câmara hiperbárica trouxe resultados positivos verificados pela aproximação dos resultados dos grupos experimentais tanto morfométrica como funcionalmente. / The peripheral nerves are extensions of the central nervous system and are responsible for the sensory and motor functions of the limbs. These nerves are vulnerable to the same types of traumas that affect other tissues: contusion, compression, crushing, stretching, avulsion, and laceration. Amongst the most disabling kinds of injuries that affect working-age individuals are those of the peripheral nerves; due to the multifaceted characteristics of the aftereffects of the injury. The break in continuity of the nerve structure due to trauma, as in the case of neurotmesis, results in the disruption of the transmission of nerve impulses and the disorganization of their functions. Through the use of microsurgery, it was possible to develop reconstructive techniques that range from a simple end-to-end neurorrhaphy to sophisticated surgical procedures that utilize nerve grafts, inverted veins and arteries, and synthetic rods of varied materials such as silicone or porous polyethylene. Another aspect that intrigues researchers around the world is the utilization of neurogenic factors capable of accelerating or improving the regeneration of peripheral nerves. Autologous fat has been a constant reference in this field of surgery due to its abundant supply at the surgical site itself. The results are promising, as the adventitia of vessels consists of loose connective tissue rich in adipocytes. Thus in a trauma, the neurites derived from the proximal stump of the damaged nerve are in direct contact with these adipocytes. Following this reasoning, and based on previous studies where veins grafted with fresh skeletal muscle were used, we decided to conduct a randomized controlled study to test the possibility of axonal growth by means of grating with a polyethylene rod filled with autologous adipocytes associated with immersion in a hyperbaric chamber. In an attempt to recover the sciatic nerve, a rod 12 mm in length, with a diameter of 0.25 mm, and with pores of 80 μm in diameter, filled with adipose tissue in natura removed from the surroundings of said nerve, was used. The morphometric results showed that the experimental groups with and without fat fillings had results that, from the morphometric and functional point of view, were of no statistically significant difference. However, when these results were compared with the final control group, statistically significant differences were noted. Highlighting the functional evaluation through the use of Catwalk, it was found that there were no statistically significant differences between the experimental groups, but there was indeed a difference in comparison to the final control group. In light of the evidence found and supported by literature, one can conclude that the use of the hyperbaric chamber brought positive results verified by the proximity of both the morphometric and functional results of the experimental groups.

Axon regeneration

Câmara hiperbárica

Hyperbaric chamber

Nervo isquiático de ratos

Porous polyethylene rods

Rat sciatic nerve

Regeneração axonal

Tubo de polietileno poroso

Molecular mechanisms of neural plasticity after spinal cord injury in the lamprey central nervous system

Lau, Billy You Bun

12 November 2013

Spinal cord injury induces anatomical plasticity throughout the nervous system, including distant locations in the brain. Several types of injury-induced plasticity have been identified, such as neurite sprouting, axon regeneration and synaptic remodeling. However, the molecular mechanisms involved in anatomical plasticity after injury are unclear, as is the extent to which injury-induced plasticity in the brain is conserved across vertebrate lineages. Here, I used lampreys to identify the molecular mechanisms in mediating anatomical plasticity, because lampreys undergo anatomical plasticity and functional recovery after a complete spinal cord transection. Due to their robust roles in neurite outgrowth during neuronal development, I examined synapsin and synaptotagmin for their potential involvement in anatomical plasticity after injury. I found increased synapsin I mRNA throughout the lamprey brain as well as increased protein levels of synapsin I, phospho-synapsin (Ser 9) and synaptotagmin in the lamprey hindbrain after injury, suggestive of anatomical plasticity. Anatomical plasticity was confirmed at the ultrastructural level, where I found increased neurite density in the lamprey hindbrain after injury. Other molecular mechanisms that promote anatomical plasticity have been previously identified, such as cyclic AMP (cAMP). However, the cellular mechanisms and the molecular targets of cAMP in mediating anatomical plasticity are unclear. My investigation of cAMP revealed that cAMP enhanced the number of regenerated axons beyond the lesion site in lampreys after injury. For the first time in a spinal cord injury model, I found cAMP prevented the death of axotomized neurons that normally have a high tendency to die after injury. In addition, cAMP promoted more regenerating axons to re-grow in straighter paths rather than turning rostrally towards the brain stem. At the molecular level, I found cAMP increased synaptotagmin protein level at the regenerating axon tips, suggestive of enhanced axon elongation. Taken together, my results show that neurite sprouting in the brain and the cAMP-enhanced axon regeneration are conserved responses in vertebrates after spinal cord injury. In addition, my results suggest that at least some developmental pathways are activated during injury-induced and cAMP-enhanced anatomical plasticity. Further understanding of these pathways will provide insights for improving recovery after spinal cord injury. / text

Axon regeneration

Axon tip

Cyclic AMP

Cell death

Neurite sprouting

Petromyzon marinus

Phospho-synapsin

SV2

Synapsin

Synaptotagmin

Enxerto com tubo de polietileno poroso preenchido com gordura autóloga no reparo de nervo periférico associado com protocolo de imersão em câmara hiperbárica

Gustavo Lopes Toledo

16 July 2015

Os nervos periféricos são extensões do sistema nervoso central e responsável pela interação das atividades entre as extremidades, em suas funções sensitivas e motoras. São vulneráveis aos mesmos tipos de traumas que afetam outros tecidos: contusão, compressão, esmagamento, estiramento, avulsão e laceração. As lesões de nervos periféricos situam-se entre as mais incapacitantes que acometem indivíduos em idade produtiva, em face dos múltiplos aspectos concernentes às sequelas deste tipo de afecção. Desta forma, a interrupção de continuidade da estrutura do nervo, como no caso da neurotmese, por algum tipo de trauma, resulta na interrupção de transmissão dos impulsos nervosos e na desorganização de suas atividades funcionais. Por meio da utilização da microcirurgia foi possível desenvolver técnicas reparadoras que vão desde simples neurorrafia término-terminal até sofisticados procedimentos cirúrgicos com a utilização de enxertos de nervos, veias e artérias invertidas, tubos sintéticos de materiais variados, tais como silicone e polietileno. Outro aspecto que intriga pesquisadores de todo mundo é a utilização de fatores neurogênicos capazes de acelerar ou melhorar a regeneração de nervos periféricos. A gordura autóloga tem sido continuamente referenciada pela sua abundante oferta, no próprio sitio cirúrgico, apresentando resultados promissores, visto que a adventícia dos vasos é constituída por tecido conjuntivo frouxo, rico em adipócitos. Assim, em um trauma, os neuritos oriundos do coto proximal do nervo lesado, ficam diretamente em contato com esses adipócitos. Seguindo este raciocínio, e com base em trabalhos anteriores onde foi usada veia preenchida com músculo esquelético a fresco como enxerto, decidiu-se testar a possibilidade de crescimento axonal por meio de enxerto com tubo de polietileno preenchido por tecido adiposo autólogo associado a protocolo de imersão em câmara hiperbárica, por meio de um estudo Randomizado Controlado. Para tanto utilizou-se um tubo com 12 mm de comprimento por 0,25 mm de diâmetro, com poros de 80 μm de diâmetro, preenchido com tecido adiposo in natura retirado das adjacências do referido nervo, na tentativa de se recuperar o nervo isquiático. Os resultados morfométricos demonstraram que, os grupos experimentais com e sem preenchimento de gordura tiveram resultados, do ponto de vista morfométrico e funcional sem diferenças estatisticamente significantes, contudo, quando estes foram confrontados ao grupo controle final, apresentaram diferenças estatisticamente significantes. Já relevando a avaliação funcional, por meio do Catwalk, constatou-se que não houve diferença estatisticamente significante entre os grupos experimentais, mas teve diferença ao comparar com o grupo controle final, Diante das evidências encontradas e apoiados na literatura pode-se concluir que a câmara hiperbárica trouxe resultados positivos verificados pela aproximação dos resultados dos grupos experimentais tanto morfométrica como funcionalmente. / The peripheral nerves are extensions of the central nervous system and are responsible for the sensory and motor functions of the limbs. These nerves are vulnerable to the same types of traumas that affect other tissues: contusion, compression, crushing, stretching, avulsion, and laceration. Amongst the most disabling kinds of injuries that affect working-age individuals are those of the peripheral nerves; due to the multifaceted characteristics of the aftereffects of the injury. The break in continuity of the nerve structure due to trauma, as in the case of neurotmesis, results in the disruption of the transmission of nerve impulses and the disorganization of their functions. Through the use of microsurgery, it was possible to develop reconstructive techniques that range from a simple end-to-end neurorrhaphy to sophisticated surgical procedures that utilize nerve grafts, inverted veins and arteries, and synthetic rods of varied materials such as silicone or porous polyethylene. Another aspect that intrigues researchers around the world is the utilization of neurogenic factors capable of accelerating or improving the regeneration of peripheral nerves. Autologous fat has been a constant reference in this field of surgery due to its abundant supply at the surgical site itself. The results are promising, as the adventitia of vessels consists of loose connective tissue rich in adipocytes. Thus in a trauma, the neurites derived from the proximal stump of the damaged nerve are in direct contact with these adipocytes. Following this reasoning, and based on previous studies where veins grafted with fresh skeletal muscle were used, we decided to conduct a randomized controlled study to test the possibility of axonal growth by means of grating with a polyethylene rod filled with autologous adipocytes associated with immersion in a hyperbaric chamber. In an attempt to recover the sciatic nerve, a rod 12 mm in length, with a diameter of 0.25 mm, and with pores of 80 μm in diameter, filled with adipose tissue in natura removed from the surroundings of said nerve, was used. The morphometric results showed that the experimental groups with and without fat fillings had results that, from the morphometric and functional point of view, were of no statistically significant difference. However, when these results were compared with the final control group, statistically significant differences were noted. Highlighting the functional evaluation through the use of Catwalk, it was found that there were no statistically significant differences between the experimental groups, but there was indeed a difference in comparison to the final control group. In light of the evidence found and supported by literature, one can conclude that the use of the hyperbaric chamber brought positive results verified by the proximity of both the morphometric and functional results of the experimental groups.

Câmara hiperbárica

Nervo isquiático de ratos

Regeneração axonal

Tubo de polietileno poroso

Axon regeneration

Hyperbaric chamber

Porous polyethylene rods

Rat sciatic nerve

Dualité fonctionnelle de LIGHT : Implication dans la Mort du Motoneurone et dans la Régénération Axonale / Functional duality of LIGHT : From axon regeneration to death signalling

Otsmane, Belkacem

04 May 2012

LIGHT, un membre de la famille du TNF, déclenche la mort des motoneurones et contribue à la progression de la dégénérescence des motoneurones chez les souris modèles de la sclérose latérale amyotrophique. Étonnement, nous montrons que LIGHT peut également stimuler la croissance axonale in vitro et est nécessaire à la régénération axonale des motoneurones in vivo lors d'une lésion nerveuse périphérique. La compréhension des mécanismes dictant la bivalence de son récepteur mène à l'étude des effets de la régionalisation du signal LIGHT. Les chambres microfluidiques en isolant les axones des corps cellulaires, nous ont permis d'étudier la résultante fonctionnelle d'une stimulation axonale et somatique par LIGHT. Nous montrons que LIGHT active différentiellement la mort, quand il agit au niveau somatique, ou la régénération axonale, quand il stimule l'axone. L'ensemble de ces résultats mène à de nouvelles approches où l'administration de LIGHT au niveau du nerf lésé et du muscle correspondant nous renseignera sur le potentiel thérapeutique de LIGHT lors d'une lésion du système nerveux. / LIGHT, a member of the TNF superfamily, triggers death of motoneurons and contribute to the progression of motoneuron degeneration in an ALS mouse model. Interestingly, we demonstrate that LIGHT can elicit neurite outgrowth in vitro and contribute to axon regeneration in vivo following nerve injury. To better understand mechanisms governing the opposite effects of LIGHT on motoneurons we asked whether a regional activation of LIGHT pathway could trigger these opposite responses. Toward this goal we used microfluidic chambers to isolate the soma from the axon of motoneurons. We shows that LIGHT activates differentially motoneurons death when it acts at the soma and axon outgrowth when it acts at the level of the axon. Together, these results lead us to evaluate new therapeutic approaches to nerve injury.

Light

Lymphotoxine béta récepteur

Régénération axonale

Sclérose latérale amyotrophique

Motoneurone

Compartimentalisation

Light

Lymphotoxin béta receptor

Axon regeneration

Amyotrophic lateral sclerosis

Motoneuron

Compartimentalisation

Dissecting the Roles of Macrophage Subpopulations Responding to Peripheral Nerve Injury in Conditioning-Lesion Enhanced Regeneration in vivo

Talsma, Aaron David

27 January 2023

No description available.

Immunology

Neurobiology

Neurosciences

conditioning lesion effect

conditioning lesion response

macrophage depletion

macrophage polarization

axon regeneration

peripheral nerve injury

CCR2

CCL2

CCR2-GFP