RESUMO

BACKGROUND: Calcium channel blockers such as conotoxins have shown a great potential to reduce brain and spinal cord injury. MVIIC neuroprotective effects analyzed in in vitro models of brain and spinal cord ischemia suggest a potential role of this toxin in preventing injury after spinal cord trauma. However, previous clinical studies with MVIIC demonstrated that clinical side effects might limit the usefulness of this drug and there is no research on its systemic effects. Therefore, the present study aimed to investigate the potential toxic effects of MVIIC on organs and to evaluate clinical and blood profiles of rats submitted to spinal cord injury and treated with this marine toxin. Rats were treated with placebo or MVIIC (at doses of 15, 30, 60 or 120 pmol) intralesionally following spinal cord injury. Seven days after the toxin administration, kidney, brain, lung, heart, liver, adrenal, muscles, pancreas, spleen, stomach, and intestine were histopathologically investigated. In addition, blood samples collected from the rats were tested for any hematologic or biochemical changes. RESULTS: The clinical, hematologic and biochemical evaluation revealed no significant abnormalities in all groups, even in high doses. There was no significant alteration in organs, except for degenerative changes in kidneys at a dose of 120 pmol. CONCLUSIONS: These findings suggest that MVIIC at 15, 30 and 60 pmol are safe for intralesional administration after spinal cord injury and could be further investigated in relation to its neuroprotective effects. However, 120 pmol doses of MVIIC may provoke adverse effects on kidney tissue.

RESUMO

O bloqueio dos canais para cálcio dependentes de voltagem é uma estratégia importante no tratamento do trauma medular, pois previne o influxo exacerbado do cálcio que participa ativamente em processos neurodegenerativos agudos, resultando em neuroproteção com melhora das funções neurológica. Dentre esses bloqueadores, as toxinas de caramujos marinhos são peptídeos com adequada estabilidade estrutural, estudadas pelas ações específicas em canais iônicos e receptores que interferem diretamente na liberação de neurotransmissores e na neuromodulação dos neurônios motores e sensitivos da medula espinal. Elas já são utilizadas no tratamento de desordens neurológicas e mostram-se promissoras no desenvolvimento de novas terapias para o trauma medular. Portanto, objetivou-se discorrer sobre a fisiopatologia do trauma medular e a possível utilização terapêutica das toxinas de caramujo marinho, atuantes nos principais canais para cálcio dependentes de voltagem.(AU)

Blocking voltage dependent calcium channels is an important strategy in acute spinal trauma treatment, because it prevents the exacerbated calcium influx which participates actively in acute neurodegenerative processes, resulting in neuroprotection with improvement of neurological and electrophysiological functions. The cone snail toxins are peptides with adequate structural stability, which have been studied by specific actions on ion channels and receptors that directly interfering in the release of neurotransmitters and neuromodulation of sensory and motor neurons of the spinal cord. They are already used in the treatment of neurological disorders and appear to be promising in the development of new therapies for spinal trauma. Therefore, it was aimed to discuss the pathophysiology of spinal cord trauma, and possible therapeutic use of marine snail toxins that acts in voltage-dependent calcium channels.(AU)

Assuntos

RESUMO

O bloqueio dos canais para cálcio dependentes de voltagem é uma estratégia importante no tratamento do trauma medular, pois previne o influxo exacerbado do cálcio que participa ativamente em processos neurodegenerativos agudos, resultando em neuroproteção com melhora das funções neurológica. Dentre esses bloqueadores, as toxinas de caramujos marinhos são peptídeos com adequada estabilidade estrutural, estudadas pelas ações específicas em canais iônicos e receptores que interferem diretamente na liberação de neurotransmissores e na neuromodulação dos neurônios motores e sensitivos da medula espinal. Elas já são utilizadas no tratamento de desordens neurológicas e mostram-se promissoras no desenvolvimento de novas terapias para o trauma medular. Portanto, objetivou-se discorrer sobre a fisiopatologia do trauma medular e a possível utilização terapêutica das toxinas de caramujo marinho, atuantes nos principais canais para cálcio dependentes de voltagem.

Blocking voltage dependent calcium channels is an important strategy in acute spinal trauma treatment, because it prevents the exacerbated calcium influx which participates actively in acute neurodegenerative processes, resulting in neuroprotection with improvement of neurological and electrophysiological functions. The cone snail toxins are peptides with adequate structural stability, which have been studied by specific actions on ion channels and receptors that directly interfering in the release of neurotransmitters and neuromodulation of sensory and motor neurons of the spinal cord. They are already used in the treatment of neurological disorders and appear to be promising in the development of new therapies for spinal trauma. Therefore, it was aimed to discuss the pathophysiology of spinal cord trauma, and possible therapeutic use of marine snail toxins that acts in voltage-dependent calcium channels.

RESUMO

Calcium channel blockers such as conotoxins have shown a great potential to reduce brain and spinal cord injury. MVIIC neuroprotective effects analyzed in in vitro models of brain and spinal cord ischemia suggest a potential role of this toxin in preventing injury after spinal cord trauma. However, previous clinical studies with MVIIC demonstrated that clinical side effects might limit the usefulness of this drug and there is no research on its systemic effects. Therefore, the present study aimed to investigate the potential toxic effects of MVIIC on organs and to evaluate clinical and blood profiles of rats submitted to spinal cord injury and treated with this marine toxin. Rats were treated with placebo or MVIIC (at doses of 15, 30, 60 or 120 pmol) intralesionally following spinal cord injury. Seven days after the toxin administration, kidney, brain, lung, heart, liver, adrenal, muscles, pancreas, spleen, stomach, and intestine were histopathologically investigated. In addition, blood samples collected from the rats were tested for any hematologic or biochemical changes.

Assuntos

RESUMO

Calcium channel blockers such as conotoxins have shown a great potential to reduce brain and spinal cord injury. MVIIC neuroprotective effects analyzed in in vitro models of brain and spinal cord ischemia suggest a potential role of this toxin in preventing injury after spinal cord trauma. However, previous clinical studies with MVIIC demonstrated that clinical side effects might limit the usefulness of this drug and there is no research on its systemic effects. Therefore, the present study aimed to investigate the potential toxic effects of MVIIC on organs and to evaluate clinical and blood profiles of rats submitted to spinal cord injury and treated with this marine toxin. Rats were treated with placebo or MVIIC (at doses of 15, 30, 60 or 120 pmol) intralesionally following spinal cord injury. Seven days after the toxin administration, kidney, brain, lung, heart, liver, adrenal, muscles, pancreas, spleen, stomach, and intestine were histopathologically investigated. In addition, blood samples collected from the rats were tested for any hematologic or biochemical changes.

Assuntos

RESUMO

Calcium channel blockers such as conotoxins have shown a great potential to reduce brain and spinal cord injury. MVIIC neuroprotective effects analyzed in in vitro models of brain and spinal cord ischemia suggest a potential role of this toxin in preventing injury after spinal cord trauma. However, previous clinical studies with MVIIC demonstrated that clinical side effects might limit the usefulness of this drug and there is no research on its systemic effects. Therefore, the present study aimed to investigate the potential toxic effects of MVIIC on organs and to evaluate clinical and blood profiles of rats submitted to spinal cord injury and treated with this marine toxin. Rats were treated with placebo or MVIIC (at doses of 15, 30, 60 or 120 pmol) intralesionally following spinal cord injury. Seven days after the toxin administration, kidney, brain, lung, heart, liver, adrenal, muscles, pancreas, spleen, stomach, and intestine were histopathologically investigated. In addition, blood samples collected from the rats were tested for any hematologic or biochemical changes.(AU)

Assuntos