Hepatic metabolic response to injury and sepsis

Background. Experimental reports have indicated that hepatic oxidative and synthetic metabolism may become depressed in sepsis. Because the mechanism of infection-related liver dysfunction has not been established, further study of these functional alterations could contribute to the therapeutic man...

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Bibliographic Details
Published in:Surgery 1995-05, Vol.117 (5), p.520-530
Main Authors: Dahn, Michael S., Mitchell, Robert A., Lange, M. Patricia, Smith, Stuart, Jacobs, Lloyd A.
Format: Article
Language:English
Subjects:
Adult
Aged
Biological and medical sciences
Functional investigation of the digestive system
Gluconeogenesis
Glucose - metabolism
Humans
Infection - metabolism
Investigative techniques, diagnostic techniques (general aspects)
Liver - metabolism
Medical sciences
Middle Aged
Oxygen Consumption
Reference Values
Serum Albumin - biosynthesis
Viscera - metabolism
Wounds and Injuries - metabolism
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Summary:Background. Experimental reports have indicated that hepatic oxidative and synthetic metabolism may become depressed in sepsis. Because the mechanism of infection-related liver dysfunction has not been established, further study of these functional alterations could contribute to the therapeutic management of septic organ failure syndromes. However, recently controversy has arisen over the existence of these derangements that must be reconciled before further progress in this field can be made. Methods. Splanchnic balance studies for the measurement of glucose output and oxygen consumption were used to assess hepatic function in fasted normal volunteers (n=18), injured patients (n=10), and patients with sepsis (n=18). The liver's contribution to splanchnic metabolism was estimated from a comparison of splanchnic oxygen utilization in response to increases in the liver-specific process of glucogenesis. In addition, in vivo liver albumin production was determined by using the [ 14C] carbonate technique. Results. Glucose output after injury and sepsis was increased by 12.8% and 76.6%, respectively, compared with controls. On the basis of substrate balance studies, gluconeogenesis was estimated to account for 46%, 87%, and 93%, respectively, of splanchnic glucose output in each of the three groups. In patients with sepsis glucose output was also noted to be linearly related to regional oxygen consumption, indicating that these processes were coupled and increases in the respiratory activity of the splanchnic cellular mass could be accounted for by increases in new glucose output and gluconeogenic substrate clearance. The mean albumin synthetic rate increased during injury and sepsis by 22% and 29%, respectively, compared with normal volunteers. Conclusions. These studies cast doubt on the commonly held notion that tissue respiratory dysfunction may occur during sepsis. On the contrary, hepatic function is accelerated during hyperdynamic sepsis, and evidence indicating oxidative or synthetic functional depression is lacking.
ISSN:0039-6060
1532-7361
DOI:10.1016/S0039-6060(05)80251-X