Conduction failure of action potentials in sensory sural nerves of undernourished rats.

In order to determine possible functional and morphometrical alterations produced by perinatal undernourishment on peripheral nerves, sensory sural nerves from control and undernourished rats of 30 and 90 postnatal days of age were dissected and divided in two segments, one for recording the compound action potential (CAP) and the other for histological examination. Nerves from undernourished animals showed maximal CAP responses of smaller amplitude and area, larger trial-to-trial variability in area, and a significant reduction in axonal myelin sheath thickness than nerves from control animals. It is suggested that perinatal undernourishment produces changes in axonal myelin sheath structure, resulting in severe alterations in the generation and propagation of action potentials (block and/or intermittent conduction) in sensory afferent fibers in the rat.

Effect of perinatal food deficiencies on the compound action potential evoked in sensory nerves of developing rats.

The aim of this study was to analyze the possible alterations produced by inadequate perinatal food intake, in quantity (undernutrition) or quality (malnutrition), on the generation and propagation of the compound action potential (CAP) evoked in sensory sural nerves, during the postnatal development of the rat. Low intensity stimulation (2-3 times the threshold of the most excitable nerve fibers; xT) of the sural nerve evoked an early potential (CAP-A component) which is due to activation of low-threshold, fast-conducting myelinated group A afferent fibers. Meanwhile, at higher stimulus intensity (20-30T) it produced a second, long-lasting potential (CAP-C component) probably due to activation of high-threshold, slow-conducting group Adelta or C afferent fibers. Compared to control nerves, the CAP-A component, but not the CAP-C component of undernourished and malnourished nerves showed significant changes in amplitude, area, electrical threshold and conduction velocity (except absolute refractory period) at several postnatal ages. Our results may suggest that a relative large number of myelinated group A afferent fibers in the sural nerve of undernourished and malnourished animals suffer severe alterations on their electrophysiological properties of generation and propagation of the action potential during the postnatal development of the rat.