The intrahepatic biliary epithelium in the guinea pig: Is hepatic artery blood flow essential in maintaining its function and structure?

To determine whether hepatic artery blood flow is essential in maintaining the function and structure of bile ductules/ducts, the acute effects of hepatic artery ligation on bile secretion and hepatic ultrastructure were examined in anesthetized, bile duct-cannulated guinea pigs. Sixty minutes after hepatic artery ligation, spontaneous bile flow (5.08 f 0.4 pl per min per gm liver) was virtually the same as that before hepatic artery ligation (5.31 f 0.3 pl per min per gm), as were the choleretic effects of 10 CU per kg per 30 rnin secretin (7.14 f 0.9 vs. 7.21 f 0.9 p1 per min per gm), 300 pg per kg per 30 min glucagon (6.72 2 0.9 vs. 6.59 f 0.8 pl per rnin per gm) and 60 pmoles per kg per 30 rnin glycochenodeoxycholate (6.43 f 0.6 vs. 6.45 f 0.6 p1 per rnin per gm). The failure of hepatic artery ligation to affect bile secretory function could not be attributed to the existence of collateral arterial blood flow to the liver. First of all, hepatic artery ligation resulted in diminishing significantly hepatic venous, but not portal, oxygen content. More importantly, in isolated guinea pig livers, perfused through the portal vein alone, secretin, glucagon and glycochenodeoxycholate produced changes in bile flow and composition similar to those seen in uiuo. Electron microscopy showed no major ultrastructural changes of hepatic parenchyma and biliary epithelium 2 hr after hepatic artery ligation, or 2 hr after perfusing the liver through the portal vein alone save for some portal edema in the latter instance. Failure to perfuse the hepatic artery resulted in dilatation of periportal bile canaliculi, but no evidence of anoxia was observed. These studies indicate that, in the guinea pig, the intrahepatic biliary epithelium receives oxygen in absence of hepatic artery perfusion. Thus, manipulation of hepatic vascular anatomy is not useful for separating canalicular from ductular function.

Prior to reaching the gallbladder or the duodenum, canalicular bile is thought to be significantly modified while flowing through the bile ductules and intralobular bile ducts. Both reabsorptive (1, 2) and secretory (2, 3) processes have been suggested to occur at these distal epithelial structures, and secretin choleresis is believed to be the most striking example of ductular secretory activity (3, 4). However, even though secretion has been