The effect of combined fluid percussion and entorhinal cortical lesions on long-term potentiation

Abstract

Among the pathological processes initiated by traumatic brain injury are excessive neuroexcitation and target cell deafferentation. The current study examines the contribution of these injury components, separately as well as their combined effect, on postinjury alterations in the capacity for long-term potentiation and the immunolocalization of N-methyl- d-aspartate receptors and GABA. Adult rats underwent central fluid percussion traumatic brain injury, electrolytic bilateral entorhinal cortex lesions, or a combined injury of both procedures separated by 24 h. At two or 15 days postinjury, the capacity for long-term potentiation of the Schaffer collateral–commissural input to CA1 was measured in acute electrophysiological recordings. Entorhinal cortical lesions resulted in time-dependent increases in the effectiveness of tetanic stimulation to elevate population postsynaptic potentials and population spike amplitudes. These lesions also resulted in a marked intensification in the density of N-methyl- d-aspartate receptors in the CA1 stratum lacunosum-moleculare. All injury conditions that included fluid percussion as a component (alone or in combined injuries) produced a persistent impairment in long-term potentiation of the evoked population postsynaptic potentials. Thus, in combined injuries, the presence of concussion-induced neuroexcitation attenuated deafferentation-induced response increases. Both N-methyl- d-aspartate receptor and GABA immunobinding following combined injuries were also reduced relative to those observed following entorhinal lesions alone. The present results suggest that a process of receptor plasticity, possibly involving reactive synaptogenesis, may contribute to postdeafferentation enhancements of long-term potentiation, and that a traumatic brain insult will attenuate these enhancements. This interaction of different injury components suggests that recovery of function following brain injury may be enhanced by pharmacological reduction of neuroexcitation during postinjury intervals of reactive receptor plasticity.