ABSTRACT
The brain cortex is the structure that is typically injured in traumatic brain injury (TBI) and is anatomically connected with other brain regions, including the striatum and hypothalamus, which are associated in part with motor function and the regulation of body temperature, respectively. We investigated whether a TBI extending to the striatum could affect peripheral and core temperatures as an indicator of autonomic thermoregulatory function. Moreover, it is unknown whether thermal modulation is accompanied by hypothalamic and cortical monoamine changes in rats with motor function recovery. The animals were allocated into three groups: the sham group (sham), a TBI group with a cortical contusion alone (TBI alone), and a TBI group with an injury extending to the dorsal striatum (TBI + striatal injury). Body temperature and motor deficits were evaluated for 20 days post-injury. On the 3rd and 20th days, rats were euthanized to measure the serotonin (5-HT), noradrenaline (NA), and dopamine (DA) levels using high-performance liquid chromatography (HPLC). We observed that TBI with an injury extending to the dorsal striatum increased core and peripheral temperatures. These changes were accompanied by a sustained motor deficit lasting for 14 days. Furthermore, there were notable increases in NA and 5-HT levels in the brain cortex and hypothalamus both 3 and 20 days after injury. In contrast, rats with TBI alone showed no changes in peripheral temperatures and achieved motor function recovery by the 7th day post-injury. In conclusion, our results suggest that TBI with an injury extending to the dorsal striatum elevates both core and peripheral temperatures, causing a delay in functional recovery and increasing hypothalamic monoamine levels. The aftereffects can be attributed to the injury site and changes to the autonomic thermoregulatory functions.
ABSTRACT
Norepinephrine plays an important role in motor functional recovery after a brain injury caused by ferrous chloride. Inhibition of norepinephrine release by clonidine is correlated with motor deficits after motor cortex injury. The aim of this study was to analyze the role of α2-adrenergic receptors in the restoration of motor deficits in recovering rats after brain damage. The rats were randomly assigned to the sham and injury groups and then treated with the following pharmacological agents at 3 hours before and 8 hours, 3 days, and 20 days after ferrous chloride-induced cortical injury: saline, clonidine, efaroxan (a selective antagonist of α2-adrenergic receptors) and clonidine + efaroxan. The sensorimotor score, the immunohistochemical staining for α2A-adrenergic receptors, and norepinephrine levels were evaluated. Eight hours post-injury, the sensorimotor score and norepinephrine levels in the locus coeruleus of the injured rats decreased, and these effects were maintained 3 days post-injury. However, 20 days later, clonidine administration diminished norepinephrine levels in the pons compared with the sham group. This effect was accompanied by sensorimotor deficits. These effects were blocked by efaroxan. In conclusion, an increase in α2-adrenergic receptor levels was observed after injury. Clonidine restores motor deficits in rats recovering from cortical injury, an effect that was prevented by efaroxan. The underlying mechanisms involve the stimulation of hypersensitive α2-adrenergic receptors and inhibition of norepinephrine activity in the locus coeruleus. The results of this study suggest that α2 receptor agonists might restore deficits or impede rehabilitation in patients with brain injury, and therefore pharmacological therapies need to be prescribed cautiously to these patients.
ABSTRACT
Cerebrovascular accident (CVA) is one of the leading causes of death and disability worldwide, as well as a major financial burden for health care systems. CVA rodent models provide experimental support to determine possible in vivo therapies to reduce brain injury and consequent sequelae. This study analyzed nociceptive, motor, cognitive and mood functions in mice submitted to distal middle cerebral artery (DMCA) occlusion. Male C57BL mice (n = 8) were randomly allocated to control or DMCA groups. Motor function was evaluated with the tests: grip force, rotarod and open field; and nociceptive threshold with von Frey and hot plate assessments. Cognitive function was evaluated with the inhibitory avoidance test, and mood with the tail suspension test. Evaluations were conducted on the seventh- and twenty-eighth-day post DMCA occlusion to assess medium- and long-term effects of the injury, respectively. DMCA occlusion significantly decreases muscle strength and spontaneous locomotion (p < 0.05) both medium- and long term; as well as increases immobility in the tail-suspension test (p < 0.05), suggesting a depressive-type behavior. However, DMCA occlusion did not affect nociceptive threshold nor cognitive functions (p > 0.05). These results suggest that, medium- and long-term effects of DMCA occlusion include motor function impairments, but no sensory dysfunction. Additionally, the injury affected mood but did not hinder cognitive function.
ABSTRACT
Abstract Introduction Systemic administration of pentylenetetrazole (PTZ) causes brain damage (BD), and triggers a series of morphological and neurochemical changes, which in turn bring about behavioral, cognitive, and motor deficits. Serotonin (5-HT), dopamine (DA), and noradrenaline (NA) levels are controlled by various brain structures and these levels are related to motor activity; however, the concentration of these neurotransmitters during the postictal process remains unknown. Objective We investigated the concentration of 5-HT, NA and DA in the hippocampus, cerebellum, and cortex on motor deficit during the postictal stage. Method Eighteen male Wistar rats (300 g) assigned to two groups: control (n = 9, saline solution) and experimental (n = 9, PTZ) were used. Myoclonic shakes were counted and motor behavior assessments were recorded during three hours post PTZ injection (90 mg/kg). The cortex, cerebellum, and hippocampus of each rat were dissected to determine the 5-HT, DA, and NA concentration by high performance liquid chromatography. Results PTZ induced a significant increase in total 5-HT and DA levels in the hippocampus and cortex; in the cerebellum there was a significant increase in the concentration of 5-HT and NA. The presence of myoclonic shakes as well as a marked motor deficit in the experimental group were significantly different in comparison to the control. Discussion and conclusion 5-HT modifies the concentration of other monoamines directly involved in motor aspects such as NA and DA in the hippocampus, cerebellum, and cortex during the postictal process.
Resumen Introducción La administración sistémica de pentilentetrazol (PTZ) causa daño cerebral y desencadena una serie de cambios morfológicos y neuroquímicos que a su vez provocan déficits conductuales, cognitivos y motores. Los niveles de serotonina (5-HT), dopamina (DA) y noradrenalina (NA) son modulados por varias estructuras cerebrales y sus concentraciones se relacionan con la actividad motora; sin embargo, se desconoce la concentración de estos neurotransmisores durante el proceso postictal. Objetivo Evaluar la manera en que la concentración de 5-HT, NA y DA en el hipocampo, el cerebelo y la corteza influye en el déficit motor durante la etapa postictal. Método Se utilizaron 18 ratas macho Wistar (300 g), divididas en dos grupos: control (n = 9, solución salina) y experimental (n = 9, PTZ). Se registraron las sacudidas mioclónicas y se evaluó el comportamiento motor durante tres horas después de la inyección de PTZ (90 mg/kg). Se extrajeron la corteza, el cerebelo y el hipocampo de cada rata para determinar la concentración de 5-HT, DA y NA mediante cromatografía líquida de alta resolución. Resultados La administración de PTZ indujo un aumento significativo en los niveles totales de 5-HT y DA en el hipocampo y la corteza; en el cerebelo hubo un aumento significativo en la concentración de 5-HT y NA. Se encontró una diferencia significativa entre el grupo experimental y control con respecto a las sacudidas mioclónicas; asimismo, los animales del grupo experimental mostraron un marcado déficit motor. Discusión y conclusión La 5-HT modula la concentración de otras monoaminas involucradas directamente en aspectos motores tal como NA y DA en el hipocampo, el cerebelo y la corteza durante el proceso postictal.
ABSTRACT
OBJECTIVES: This review article aimed to present a clinical approach, emphasizing the diagnostic investigation, to children and adolescents who present in the emergency room with acute-onset muscle weakness. SOURCES: A systematic search was performed in PubMed database during April and May 2017, using the following search terms in various combinations: "acute," "weakness," "motor deficit," "flaccid paralysis," "child," "pediatric," and "emergency". The articles chosen for this review were published over the past ten years, from 1997 through 2017. This study assessed the pediatric age range, from 0 to 18 years. SUMMARY OF THE DATA: Acute motor deficit is a fairly common presentation in the pediatric emergency room. Patients may be categorized as having localized or diffuse motor impairment, and a precise description of clinical features is essential in order to allow a complete differential diagnosis. The two most common causes of acute flaccid paralysis in the pediatric emergency room are Guillain-Barré syndrome and transverse myelitis; notwithstanding, other etiologies should be considered, such as acute disseminated encephalomyelitis, infectious myelitis, myasthenia gravis, stroke, alternating hemiplegia of childhood, periodic paralyses, brainstem encephalitis, and functional muscle weakness. Algorithms for acute localized or diffuse weakness investigation in the emergency setting are also presented. CONCLUSIONS: The clinical skills to obtain a complete history and to perform a detailed physical examination are emphasized. An organized, logical, and stepwise diagnostic and therapeutic management is essential to eventually restore patient's well-being and full health.
Subject(s)
Emergency Service, Hospital , Muscle Weakness/diagnosis , Muscle Weakness/etiology , Acute Disease , Child , Diagnosis, Differential , Humans , Physical ExaminationABSTRACT
Traumatic brain injury (TBI) is one of the most common types of brain injuries that cause death or persistent neurological disturbances in survivors. Most of the promising experimental drugs were not effective in clinical trials; therefore, the development of TBI drugs represents a huge unmet need. Guanosine, an endogenous neuroprotective nucleoside, has not been evaluated in TBI to the best of our knowledge. Therefore, the present study evaluated the effect of guanosine on TBI-induced neurological damage. Our findings showed that a single dose of guanosine (7.5 mg/kg, intraperitoneally (i.p.) injected 40 min after fluid percussion injury (FPI) in rats protected against locomotor and exploratory impairments 8 h after injury. The treatment also protected against neurochemical damage to the ipsilateral cortex, glutamate uptake, Na+/K+-ATPase, glutamine synthetase activity, and alterations in mitochondrial function. The inflammatory response and brain edema were also reduced by this nucleoside. In addition, guanosine protected against neuronal death and caspase 3 activation. Therefore, this study suggests that guanosine plays a neuroprotective role in TBI and can be exploited as a new pharmacological strategy.
Subject(s)
Brain Injuries, Traumatic/prevention & control , Guanosine/therapeutic use , Inflammation Mediators/antagonists & inhibitors , Mitochondria/drug effects , Neurons/drug effects , Neuroprotective Agents/therapeutic use , Animals , Brain Injuries, Traumatic/metabolism , Brain Injuries, Traumatic/pathology , Cell Count/methods , Cerebral Cortex/drug effects , Cerebral Cortex/metabolism , Cerebral Cortex/pathology , Guanosine/pharmacology , Inflammation/metabolism , Inflammation/pathology , Inflammation/prevention & control , Inflammation Mediators/metabolism , Male , Mitochondria/metabolism , Mitochondria/pathology , Neurons/metabolism , Neurons/pathology , Neuroprotective Agents/pharmacology , Rats , Rats, WistarABSTRACT
Abstract Objectives: This review article aimed to present a clinical approach, emphasizing the diagnostic investigation, to children and adolescents who present in the emergency room with acute-onset muscle weakness. Sources: A systematic search was performed in PubMed database during April and May 2017, using the following search terms in various combinations: "acute," "weakness," "motor deficit," "flaccid paralysis," "child," "pediatric," and "emergency". The articles chosen for this review were published over the past ten years, from 1997 through 2017. This study assessed the pediatric age range, from 0 to 18 years. Summary of the data: Acute motor deficit is a fairly common presentation in the pediatric emergency room. Patients may be categorized as having localized or diffuse motor impairment, and a precise description of clinical features is essential in order to allow a complete differential diagnosis. The two most common causes of acute flaccid paralysis in the pediatric emergency room are Guillain-Barré syndrome and transverse myelitis; notwithstanding, other etiologies should be considered, such as acute disseminated encephalomyelitis, infectious myelitis, myasthenia gravis, stroke, alternating hemiplegia of childhood, periodic paralyses, brainstem encephalitis, and functional muscle weakness. Algorithms for acute localized or diffuse weakness investigation in the emergency setting are also presented. Conclusions: The clinical skills to obtain a complete history and to perform a detailed physical examination are emphasized. An organized, logical, and stepwise diagnostic and therapeutic management is essential to eventually restore patient's well-being and full health.
Resumo Objetivos: Apresentar uma abordagem clínica, enfatizar a investigação diagnóstica, voltada para crianças e adolescentes no pronto-socorro com fraqueza muscular de surgimento agudo. Fontes: Foi feita uma pesquisa sistemática na base de dados PubMed entre abril e maio de 2017, com os seguintes termos de pesquisa em várias combinações: "agudo", "fraqueza", "déficit motor", "paralisia flácida", "criança", "pediátrico" e "emergência". Os trabalhos escolhidos para esta revisão foram publicados nos últimos dez anos, de 1997 a 2017. Este trabalho aborda a faixa etária pediátrica, até 18 anos. Resumo dos dados: O déficit motor agudo é uma causa razoavelmente comum para crianças e adolescentes procurarem o pronto-socorro. Os pacientes podem ser classificados como com deficiência motora localizada ou difusa e uma descrição precisa das características clínicas é essencial para possibilitar um diagnóstico diferenciado completo. As duas causas mais comuns de paralisia flácida aguda no pronto-socorro pediátrico são síndrome de Guillain-Barré e mielite transversa, independentemente de outras etiologias serem consideradas, como encefalomielite disseminada aguda, mielite infecciosa, miastenia grave, derrame, hemiplegia alternante da infância, paralisia periódica, encefalite do tronco encefálico e fraqueza muscular funcional. Os algoritmos da investigação de fraqueza aguda localizada ou difusa na configuração de emergência também são apresentados. Conclusões: São enfatizadas as habilidades clínicas para obter um histórico completo e fazer um exame físico detalhado. Um manejo diagnóstico e terapêutico organizado, lógico e por etapas é essencial para eventualmente restaurar o bem-estar e a saúde total do paciente.