Using Optogenetics and Fictive Locomotion to Investigate the Effects of Inhibiting Renshaw Cells on Normal Locomotion in P3 Mice

Niss, Frida

January 2016

The circuit of recurring inhibition between motor neurons and Renshaw cells in the spinal cord has been known for around 70 years, though no determined function has been outlined as of yet. Renshaw cells are thought to be part of the central pattern generator in the spinal cord establishing them as an important part of the animal’s locomotive properties. In this study we aimed to investigate the role of Renshaw cells in locomotion with the help of optogenetics and electrophysiology. Halorhodopsin was inserted into the genome of mice and driven to expression with Cre recombinase in Renshaw cells. The spinal cord of P3 mice was extracted and by inducing fictive locomotion with appropriate neurotransmitters we could inhibit the Renshaw cells in action with a green laser, opening the halorhodopsin channels for Cl- ions. In previous experiments where the ability of Renshaw cells to release inhibitory neurotransmitters was inactivated, no effect was observed in either behavioral experiments or electrophysiological experiments. In a system where the effect of Renshaw cells was knocked out acutely with optogenetics there was no discernible change in fictive locomotion cycle length, frequency or amplitude. Nor was there an effect on alternation. The access of light to the Renshaw cells area might have been limited during the experiment considering the angle of light delivery and strength of the laser. Furthermore, the maturity of Renshaw cells at P3, the exclusive ability of the marker used to target Renshaw cells and the observed nature of neonatal inhibitory neurons acting as excitatory neurons could all be called into question about whether they contributed to these results or not.

Optogenetics

Fictive locomotion

Spinal cords

Renshaw cells

Ventral root recording

X-irradiation and Drug Effects on Ventral Root Potentials in Cat Spinal Cords

Crow, Robert V.

08 1900

The purpose of the present study was sixfold: 1. To study the effects of x-irradiation on spinal cord activity. 2. To study the effects of CNS drugs on spinal cord function as reflected by changes in the ventral root potentials. 3. To ascertain whether one can alter the observed spinal response to ionizing radiation by applying CNS drugs prior to, during, and following x-irradiation of a given spinal cord segment. 4. To shed some light on the role of higher brain centers on spinal reflexes. 5. To shed some light on the loci of radiation insult to the spinal cord. 6. To establish evidence for a possible drug-irradiation interaction in mammals.

x-irradiation

drug effects

ventral root potential

cat spinal cords

The role of protein convertases in bigdynorphin and dynorphin A metabolic pathway

Ruiz Orduna, Alberto

12 1900

Les dynorphines sont des neuropeptides importants avec un rôle central dans la nociception et l’atténuation de la douleur. De nombreux mécanismes régulent les concentrations de dynorphine endogènes, y compris la protéolyse. Les Proprotéines convertases (PC) sont largement exprimées dans le système nerveux central et clivent spécifiquement le C-terminale de couple acides aminés basiques, ou un résidu basique unique. Le contrôle protéolytique des concentrations endogènes de Big Dynorphine (BDyn) et dynorphine A (Dyn A) a un effet important sur la perception de la douleur et le rôle de PC reste à être déterminée. L'objectif de cette étude était de décrypter le rôle de PC1 et PC2 dans le contrôle protéolytique de BDyn et Dyn A avec l'aide de fractions cellulaires de la moelle épinière de type sauvage (WT), PC1 -/+ et PC2 -/+ de souris et par la spectrométrie de masse. Nos résultats démontrent clairement que PC1 et PC2 sont impliquées dans la protéolyse de BDyn et Dyn A avec un rôle plus significatif pour PC1. Le traitement en C-terminal de BDyn génère des fragments peptidiques spécifiques incluant dynorphine 1-19, dynorphine 1-13, dynorphine 1-11 et dynorphine 1-7 et Dyn A génère les fragments dynorphine 1-13, dynorphine 1-11 et dynorphine 1-7. Ils sont tous des fragments de peptides associés à PC1 ou PC2. En plus, la protéolyse de BDyn conduit à la formation de Dyn A et Leu-Enk, deux peptides opioïdes importants. La vitesse de formation des deux est réduite de manière significative dans les fractions cellulaires de la moelle épinière de souris mutantes. En conséquence, l'inhibition même partielle de PC1 ou PC2 peut altérer le système opioïde endogène. / Dynorphins are important neuropeptides with a central role in nociception and pain alleviation. Many mechanisms regulate endogenous dynorphin concentrations, including proteolysis. Proprotein convertases (PCs) are widely expressed in the central nervous system and specifically cleave at C-terminal of either a pair of basic amino acids, or a single basic residue. The proteolysis control of endogenous Big Dynorphin (BDyn) and Dynorphin A (Dyn A) levels has a profound impact on pain perception and the role of PCs remain unclear. The objective of this study was to decipher the role of PC1 and PC2 in the proteolysis control of BDyn and Dyn A levels using cellular fractions of spinal cords from wild type (WT), PC1-/+ and PC2-/+ animals and mass spectrometry. Our results clearly demonstrate that both PC1 and PC2 are involved in the proteolysis regulation of BDyn and Dyn A with a more important role for PC1. C-terminal processing of BDyn generates specific peptide fragments Dynorphin 1-19, Dynorphin 1-13, Dynorphin 1-11 and Dynorphin 1-7 and C-terminal processing of Dyn A generates Dynorphin 1-13, Dynorphin 1-11 and Dynorphin 1-7, all these peptide fragments are associated with PC1 or PC2 processing. Moreover, proteolysis of BDyn leads to the formation of Dyn A and Leu-Enk, two important opioid peptides. The rate of formation of both is significantly reduced in cellular fractions of spinal cord mutant mice. As a consequence, even partial inhibition of PC1 or PC2 may impair the endogenous opioid system.

Dynorphines

Dynorphine A

Proprotéines convertases

Protéolyse

Peptides opioïdes

Moelle épinière

Spectrométrie de masse

Douleur

Synapse

Dynorphins

Dynorphin A

Proprotein convertases

Proteolysis

Opioid peptides

Spinal cords

Mass spectrometry

Pain

Synapse

Efeito cognitivo da estimulação magnética transcraniana profunda no tratamento de pacientes com dor neuropática central: um ensaio clínico aleatorizado, duplamente encoberto, controlado por placebo / Cognitive effect of deep transcranial magnetic stimulation in the treatment of patients with central neuropathic pain: a randomized, double-blind, placebo-controlled trial

Selingardi, Priscila Mara Lorencini

31 October 2018

Estimulação Magnética Transcraniana profunda (EMTp) modula estruturas corticais mais profundas, como a Ínsula Posterior Superior (IPS) e o Córtex Cingulado Anterior (CCA) e tem sido usada para tratar condições não anteriormente sensíveis à EMT superficial. No entanto, até o momento, nenhum estudo avaliou os efeitos da EMTp na cognição após várias sessões de estimulação de maneira abrangente, especialmente em pacientes com disfunção cognitiva basal devido a lesões estruturais da SNC. Apresentamos resultados secundários de um estudo randomizado paralelo de três braços sobre os efeitos da EMTp ativa de 10Hz para o CCA ou IPS contra EMTp simulada na avaliação neuropsicológica de 98 pacientes com dor neuropática central submetidos a um curso de 12 semanas (16 sessões) de tratamento. Vários canais cognitivos foram avaliados em um desenho cego (atenção, controle inibitório, velocidade de processamento, flexibilidade mental, fluência verbal-fonêmica e semântica, memória operacional e episódica, cognição global e percepção visual) no início e após o último dia de estimulação. Nós observamos que não há efeitos do córtex Insular Posterior Superior (IPS) ou do Cíngulado Anterior (CCA) comparado com EMTp simulada na dor clínica, apesar do achado antinociceptivo significativo nos limiares térmicos após EMTp- IPS e um efeito ansiolítico significativo de EMTp- CCA comparado com estimulação simulada. Não encontramos efeitos significativos da estimulação ativa para o IPS ou para o CCA em comparação com a estimulação simulada em qualquer um dos domínios cognitivos. Os autores concluíram que a EMTp CCA/IPS de alta frequência e repetidas sessões de longa duração é segura em pacientes com lesões do SNC que apresentam lesões cerebrais estruturais e comprometimento cognitivo significantes / Deep-TMS (dTMS) modulates deeper cortical structures such as the posterior superior insular (PSI) and the anterior cingulate cortices (ACC) and has been used to treat conditions not previously responsive to superficial-TMS. However, to date no study has assessed the effects of dTMS on cognition after several sessions of stimulation in a comprehensive manner, especially in patients with baseline cognitive dysfunction due to SNC structural lesions. We present secondary outcome results form a three-arm parallel randomized trial on the effects of active10Hz dTMS to either the ACC or PSI against sham dTMS on neuropsychological assessment of 98 central neuropathic pain patients undergoing a 12-week (16 sessions) course of treatment. Several cognitive channels were assessed in a blinded design (attention, inhibitory control, processing speed, mental flexibility, verbal fluency-phonemic and semantic, working and episodic memory, global cognition and visual perception) at baseline and after the last day of stimulation. We observed that there were no effects of either posterior insular (PSI) or anterior cingulate cortex (ACC) compared to sham dTMS on clinical pain, despite the finding of a significant anti-nociceptive on thermal thresholds after PSI d- TMS and a significant anxiolytic effect of ACC d-TMS compared to sham stimulation. We found no significant effects of active stimulation to either the PSI or to the ACC compared to sham stimulation in any of the cognitive domains. Long-term repetitive-session high frequency ACC/PSI- dTMS is safe in patients with structural SNC lesions who have baseline significant structural brain lesions and cognitive impairment

Acidente vascular cerebral

Anterior cingulate cortex

Cognição

Cognition

Córtex cingulado anterior

Dor neuropática

Estimulação magnética transcraniana

Insula

Ínsula

Memória

Memory

Neuropathic pain

Spinal cords injury

Stroke

Transcranial magnetic stimulation

Traumatismos da medula espinal