Evaluation of motor neuron excitability by CMAP scanning with modulated current

It is important to have better evaluation and understanding of the motor neuron physiology, with the goal to early and objectively diagnose and treat patients with neurodegenerative pathologies. The Compound Muscle Action Potential (CMAP) scan is a non-invasive diagnosis technique for neurodegenerative pathologies, such as ALS, and enables a quick analysis of the muscle action potentials in response to motor nerve stimulation. This work aims to study the influence of different pulse modulated waveforms in peripheral nerve excitability by CMAP scan technique on healthy subjects. A total of 13 healthy subjects were submitted to the same test. The stimuli were applied in the medium nerve on the right wrist and electromyography signal collected on the Abductor Pollicis Brevis (APB) muscle surface on the right thumb. Stimulation was performed with an increasing intensities range from 4 to 30 mA, with varying steps, 3 stimuli per step. The procedure was repeated 4 times per subject, each repetition using a different single pulse stimulation waveform: monophasic square, monophasic triangular, monophasic quadratic and biphasic square. Results were retrieved from the averaging of the stimuli on each current intensity step. The square pulse needs less current intensity to generate the same response amplitude regarding the other waves and presents a more steep curve slope and this effect is gradually decreasing for the triangular and quadratic pulse,respectively, being the difference even more evident regarding the biphasic pulse. The control of the waveform stimulation pulse allows varying the stimulusresponse curve slope.

Modulation of electrical stimulation applied to human physiology and clinical diagnostic

The use, manipulation and application of electrical currents, as a controlled interference mechanism in the human body system, is currently a strong source of motivation to researchers in areas such as clinical, sports, neuroscience, amongst others. In electrical stimulation (ES), the current applied to tissue is traditionally controlled concerning stimulation amplitude, frequency and pulse-width. The main drawbacks of the transcutaneous ES are the rapid fatigue induction and the high discomfort induced by the non-selective activation of nervous fibers. There are, however, electrophysiological parameters whose response, like the response to different stimulation waveforms, polarity or a personalized charge control, is still unknown. The study of the following questions is of great importance: What is the physiological effect of the electric pulse parametrization concerning charge, waveform and polarity? Does the effect change with the clinical condition of the subjects? The parametrization influence on muscle recruitment can retard fatigue onset? Can parametrization enable fiber selectivity, optimizing the motor fibers recruitment rather than the nervous fibers, reducing contraction discomfort? Current hardware solutions lack flexibility at the level of stimulation control and physiological response assessment. To answer these questions, a miniaturized, portable and wireless controlled device with ES functions and full integration with a generic biosignals acquisition platform has been created. Hardware was also developed to provide complete freedom for controlling the applied current with respect to the waveform, polarity, frequency, amplitude, pulse-width and duration. The impact of the methodologies developed is successfully applied and evaluated in the contexts of fundamental electrophysiology, psycho-motor rehabilitation and neuromuscular disorders diagnosis. This PhD project was carried out in the Physics Department of Faculty of Sciences and Technology (FCT-UNL), in straight collaboration with PLUX - Wireless Biosignals S.A. company and co-funded by the Foundation for Science and Technology.

Estudo da vascularização dos nervos periféricos e da sua influência na regeneração nervosa : estudo experimental e no cadáver humano

RESUMO: Na clínica, a recuperação funcional que se segue a uma lesão nervosa raramente é atingida na sua totalidade. A reinervação, quer motora, quer sensitiva, ocorre geralmente com maior ou menor deficit. Interessa, então, identificar os factores que podem interferir na regeneração nervosa. O neurónio é a unidade anatómica fundamental do sistema nervoso periférico e é muito vulnerável à isquemia pela grande distância que existe entre o corpo neuronal e a extensão do axónio, que pode ser de apenas alguns milímetros ou até atingir um metro. É, por isso, fundamental o estudo da vascularização do nervo periférico e da sua influência na regeneração nervosa. O resultado deste estudo pode levar ao desenvolvimento de técnicas cirúrgicas que criem as condições que garantam, por sua vez, a revascularização precoce do nervo periférico em caso de lesão, ou mesmo em caso de doenças, nas quais a vascularização do nervo está alterada como, por exemplo, na neuropatia diabética. O estudo da vascularização do nervo periférico realizou-se através da investigação da vascularização do nervo mediano do cadáver humano, pela investigação da vascularização do nervo isquiático do rato Wistar e do Plexo Braquial (PB) do mesmo. A vascularização do PB do rato não é muito diferente daquela que é reportada na espécie humana, existindo uma homologia entre o rato e o Homem no que diz respeito à morfologia e à vascularização do PB. Através da comparação angiomorfológica entre o nervo isquiático do rato e o nervo mediano humano, concluíu-se que a microvascularização do nervo isquiático do rato e do mediano humano são muito semelhantes, o que suporta a utilização do rato como modelo experimental de lesões do nervo mediano humano. Para a avaliação da influência da vascularização na regeneração nervosa foi feita a análise da eficácia de enxerto de tubo de membrana amniótica humana imunologicamente inerte, de enxerto de veia jugular externa autóloga e de auto-enxerto de nervo, na reparação de um defeito de 10 milímetros no nervo isquiático do rato, na presença de um fornecimento vascular axial, comparando-se com os mesmos procedimentos em estudos realizados anteriormente, sem suprimento vascular. Os ratos foram avaliados funcionalmente através do estudo das pegadas, da electroneurografia e da força de flexão ao nível do tornozelo, e estruturalmente, através das avaliações histológicas e morfométricas, da taxa de recuperação do peso dos músculos gastrocnémio e solhear e da marcação axonal retrógrada com True Blue às 4, 8 e 12 semanas. Os nervos reconstruídos apresentaram uma arquitectura normal, incluindo a arquitectura vascular. A membrana amniótica foi bem tolerada, persistindo imunologicamente em torno do nervo até à 12.ª semana. Concluiu-se também que, na presença de um suprimento vascular axial local, a membrana amniótica humana e as veias autólogas são, pelo menos, tão eficazes como os auto-enxertos nervosos na reconstrução de defeitos nervosos de 10 milímetros.--------------------------------------ABSTRACT: At the clinic, the functional recovery that follows a nerve lesion is rarely achieved in full. The neuron is very vulnerable to ischemia that’s why it is essential to study the vascularization of the peripheral nerve and its influence on the nerve’s regeneration. The outcome of this study may lead to the development of surgical techniques that create the conditions which are necessary to ensure an early revascularization in case of a peripheral nerve injury. This study investigated the vascularization of the median nerve of the human cadaver and the vascularization of the sciatic nerve of the Wistar rat and his Brachial Plexus (BP) through animal experimentation. The mouse's BP vascularization is not so different from the one that is reported in the human species. An angiomorphological comparison between the mouse sciatic nerve and the human median nerve concluded that the microvascularizations are very similar, which supports the use of the mouse as an experimental model for the study of median nerve’s lesions. To evaluate the influence of vascularization in the nerve’s regeneration, it was made an assessment of the effectiveness of the human amniotic immuno-inert membrane grafts, of the autologous external jugular vein grafts and of the nerve auto-graft in the repair of a defect of 10 mm on the sciatic nerve of the rat, in the presence of an axial vascular supply, comparing these with the same procedures that were adopted in the previous studies, without vascular supply. The rats were functionally assessed and structurally evaluated (through histological and morphometric evaluations) at the 4.th, 8.th and 12.th weeks. The nerves reconstructed presented a normal architecture, including vascular architecture. The amniotic membrane was well-tolerated immunologically, persisting around the nerve until the 12.th week. As a result, it was also concluded that in the presence of a local axial vascular supply, the human amniotic membrane and the autologous veins are, at least, as effective as the nerve auto-grafts in the reconstruction of the nerve’s defects of 10 mm.

Unraveling intrinsic mechanisms of Nerve Regeneration

Unlike injury to the peripheral nervous system (PNS), where injured neurons can trigger a regenerative program that leads to axonal elongation and in some cases proper reinnervation, after injury to the central nervous system (CNS) neurons fail to produce the same response. The regenerative program includes the activation of several injury signals that will lead to the expression of genes associated with axonal regeneration. As a consequence, the spawned somatic response will ensure the supply of molecular components required for axonal elongation. The capacity of some neurons to trigger a regenerative response has led to investigate the mechanisms underlying neuronal regeneration. Thus, non-regenerative models (like injury to the CNS) and regenerative models (such as injury to the PNS) were used to understand the differences underlying those two responses to injury. To do so, the regenerative properties of dorsal root ganglion (DRG) neurons were addressed. This particular type of neurons possesses two branches, a central axon, that has a limited capacity to regenerate; and a peripheral axon, where regeneration can occur over long distances. In the first paradigm used to understand the neuronal regeneration mechanisms, we evaluated the activation of injury signals in a non-regenerative model. Injury signals include the positive injury signals, which are described as being enhancers of axonal regeneration by activating several transcription factors. The currently known positive injury signals are ERK, JNK and STAT3. To evaluate whether the lack of regeneration following injury to the central branch of DRG neurons was due to inactivation of these signals, activation of the transcription factors pELK-1, p-c-jun (downstream targets of ERK and JNK, respectively) and pSTAT3 were examined. Results have shown no impairment in the activation of these signals. As a consequence, we further proceed with evaluation of other candidates that could participate in axonal regeneration failure. By comparing the protein profiles that were triggered following either injury to the central branch of DRG neurons or injury to their peripheral branch, we were able to identify high levels of GSK3-β, ROCKII and HSP-40 after injury to the central branch of DRG neurons. While in vitro knockdown of HSP-40 in DRG neurons showed to be toxic for the cells, evaluation of pCRMP2 (a GSK3-β downstream target) and pMLC (a ROCKII downstream target), which are known to impair axonal regeneration, revealed high levels of both proteins following injury to the central branch when comparing with injury to their peripheral one. Altogether, these results suggest that activation of positive injury signals is not sufficient to elicit axonal regeneration; HSP-40 is likely to participate in the cell survival program; whereas GSK3-β and ROCKII activity may condition the regenerative capacity following injury to the nervous system.(...)

Blocking tumor exosome release using nanovectorization systems

Exosomes are small membrane vesicles secreted by most cell types, either normal or malignant and are found in most body fluids such as saliva, plasma and breast milk. In the past decade, the interest in these vesicles has been growing more and more since it was found that besides their beneficial functions such as the removal of cellular debris and unnecessary proteins during cell maturation process, they can also interact with other cells and transfer information between them, thus helping diseases like cancer to progress. The present work intended to use gold nanoparticles as vehicles for gene silencing in an attempt to reduce the tumor-derived exosome secretion, regulated by Rab27a protein, and also aimed to compare the exosome secretion between two breast cell lines, MCF7 and MDA. Changes in RAB27A gene expression were measured by Real-time Quantitative PCR and it was revealed a decreased in RAB27A gene expression, as expected. Exosomes were isolated and purified by two different methods, ultracentrifugation and the commercial kit ExoQuick™ Solution, and further characterized using Western Blot analysis. ExoQuick™ Solution was proven to be the most efficient method for exosome isolation and it was revealed that MDA cells secrete more exosomes. Furthermore, the isolated MCF7-derived exosomes were placed together with a normal bronchial/tracheal epithelial cell line (BTEC) for an additional assay, which aimed to observe the uptake of exosomes by other cells and the exosomes’ capability of promoting cell-cell communication. This observation was made based on alterations in the expression levels of c-Myc and miR-21 genes and the fact that they both have an increased expression in BTEC cells incubated with tumor-derived exosomes when compared to control cells (without incubation with the exosomes) lead us to the conclusion that the exosome uptake and exchange of information between the exosomes and the normal cells did occurred.