31P NMR characterization of graded traumatic brain injury in rats

Abstract

Irreversible tissue injury following central nervous system trauma is believed to result from both mechanical disruption at the time of primary insult, and more delayed “autodestructive” processes. These delayed events are associated with various biochemical changes, including alterations in phosphate energy metabolism and intracellular pH. Using ³¹P NMR, we have monitored the changes in phosphorus energy metabolism and intracellular pH in a single hemisphere of the rat brain over an 8‐h period following graded, traumatic, fluid percussion‐induced brain injury. Following trauma the ratio of phosphocreatine to inorganic phosphate (PCr/P_i) declined in each injury group. This decline was transitory with low injury (1.0 ± 0.5 atm), biphasic with moderate (2.1 ± 0.4 atm) and high (3.9 ± 0.9 atm) injury, and sustained following severe injury (5.9 ± 0.7 atm). The initial PCr/Pi decline in the moderate and high injury groups was associated with intracellular acidosis; however, the second decline occurred in the absence of any pH changes. Alterations in ATP occurred only in severely injured animals and such changes were associated with marked acidosis and 100% mortality rate. After 4 h, the posttraumatic PCr/P_i ratio correlated linearly with the severity of injury. We suggest that a reduced posttraumatic PCr/P_i ratio may be indicative of altered mitochondrial energy production and may predict a reduced capacity of the cell to recover from traumatic injury. © 1988 Academic Press, Inc.