1. In vivo studies of cellular energy state, pH, and sodium in rat liver after thermal injury
- Author
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Navin Bansal, Evelyn E. Babcock, Jureta W. Horton, A. D. Sherry, Craig R. Malloy, Zhao-Fan Xia, and Piyu Zhao
- Subjects
Male ,Magnetic Resonance Spectroscopy ,Physiology ,Intracellular pH ,Sodium ,chemistry.chemical_element ,Blood Pressure ,Membrane Potentials ,Rats, Sprague-Dawley ,Organophosphorus Compounds ,Body Water ,In vivo ,Physiology (medical) ,Organometallic Compounds ,Animals ,Magnesium ,Thermal injury ,Chemistry ,Phosphorus ,Phosphorus Isotopes ,Hydrogen-Ion Concentration ,Rats ,Cytosol ,Liver ,Biochemistry ,Thulium ,Rat liver ,Sodium Isotopes ,Burns ,Energy Metabolism ,Intracellular - Abstract
In vivo 31P- and 23Na-magnetic resonance spectroscopy was used to measure phosphorus metabolites, intracellular pH, cytosolic free Mg2+, and intracellular Na+ in the liver of rats 24 h after 40% total body surface area full-thickness burn injury. Studies were performed during infusion of thulium (III) 1,4,7,10-tetraazacyclododecane N,N′,N″,N″′-tetra(methylenephosphonate), which served as the Na+ shift agent. Compared with the sham-burn group, there was a significant increase in hepatic intracellular Na+ along with a decrease in intracellular pH and free Mg2+. The ratio of intra- to extra-cellular Na+ increased, indicating a decreased Na+ gradient that may determine the hepatic transmembrane potential difference. Hepatic beta-ATP/P(i) also significantly decreased, which suggests that either ATP utilization is significantly accelerated or ATP synthesis is inhibited after the thermal injury. Of the cations measured (Na+, Mg2+, H+), the change in intracellular Na+ was most dramatic. This study demonstrates that major burn injury may cause profound changes in hepatic bioenergetics and ionic metabolism 24 h after injury and that intracellular Na+ may be a sensitive indicator of hepatic dysfunction 24 h after injury. Because these animals tolerated the shift reagent, thuliumIII) 1,4,7,10-tetraazacyclododecane N,N′,N″,N″′-tetra(methylenephosphonate), nuclear magnetic resonance spectroscopy may prove valuable in monitoring intracellular cations in the liver after major injury.
- Published
- 1994