Distribution of mRNAS of fibrinogen polypeptides and albumin in free and membrane-bound polyribosomes and induction of alpha-fetoprotein mRNA synthesis during liver regeneration after partial hepatectomy

To study the effect of regenerative response of the liver following partial hepatectomy on the synthesis of major plasma proteins (secretory proteins), we have determined the sequence contents and the distribution of albumin and fibrinogen polypeptide mRNAs in rat liver at intervals after partial hepatectomy and sham operation. Using a quantitative technique for the isolation of polyribosomes, we demonstrated that the distribution of RNA between free and membrane-bound polyribosomal fraction was unchanged in these experiments. There was no shift in the polyribosomal population to favor free polyribosomes after partial hepatectomy. However, there was a dramatic increase (5-6-fold) of the fibrinogen polypeptide mRNA concentration during the first 24 h after resection. In contrast, the albumin mRNA concentration decreased (2-3-fold). There were no alpha-fetoprotein mRNA sequences detectable in any liver RNA fraction in these experimental animals. In sham-operated rats with intact livers, similar changes of fibrinogen polypeptide and albumin mRNA concentrations as described in regenerating liver after partial hepatectomy, were observed. These results suggest that albumin and fibrinogen synthesis after partial hepatectomy is reciprocally regulated at the mRNA level and represents a nonspecific acute phase response to surgical trauma.     

Distribution of mRNAs of fibrinogen polypeptides and albumin in free and membrane-bound polyribosomes and induction of α-fetoprotein mRNA synthesis during liver regeneration after partial hepatectomy

To study the effect of regenerative response of the liver following partial hepatectomy on the synthesis of major plasma proteins (secretory proteins), we have determined the sequence contents and the distribution of albumin and fibrinogen polypeptide mRNAs in rat liver at intervals after partial hepatectomy and sham operation. Using a quantitative technique for the isolation of polyribosomes, we demonstrated that the distribution of RNA between free and membrane-bound polyribosomal fraction was unchanged in these experiments. There was no shift in the polyribosomal population to favor free polyribosomes after partial hepatectomy. However, there was a dramatic increase (5–6-fold) of the fibrinogen polypeptide mRNA concentration during the first 24 h after resection. In contrast, the albumin mRNA concentration decreased (2–3-fold). There were no α-fetoprotein mRNA sequences detectable in any liver RNA fraction in these experimental animals. In sham-operated rats with intact livers, similar changes of fibrinogen polypeptide and albumin mRNA concentrations as described in regenerating liver after partial hepatectomy, were observed. These results suggest that albumin and fibrinogen synthesis after partial hepatectomy is reciprocally regulated at the mRNA level and represents a nonspecific acute phase response to surgical trauma.     

3H]thymidine incorporation into whole liver as an alternative to [3H]thymidine incorporation into DNA as a parameter of cell proliferation in regenerating liver tissue in rats

OBJECTIVE: To monitor liver regeneration following partial hepatectomy, liver cell proliferation can be measured by assaying in vivo [3H]thymidine incorporation into liver cell DNA. We hypothesized that [3H]thymidine incorporation into whole liver tissue parallels [3H]thymidine incorporation into liver cell DNA, both in high proliferating and low proliferating liver. STUDY DESIGN: Liver cell proliferation in rats after partial hepatectomy or a sham operation was studied by measuring incorporation of [3H]thymidine into various fractions of liver tissue on days 1, 2, 3, 4 and 10 after surgery. RESULTS: [3H]thymidine incorporation into whole liver tissue and in the protein fraction correlated well with DNA-specific [3H]thymidine incorporation into regenerating (r > .80, P < .0001) and nonregenerating liver (r > .69, P < .005). [3H]thymidine incorporation into DNA was < 5% of the total amount of administered [3H]thymidine in both sham-operated and hepatectomized rats. Significant differences in [3H]thymidine incorporation into partially hepatectomized livers as compared to sham-operated rat livers were found on days 1 and 2 (whole liver tissue and protein fraction) or day 1 (DNA) after surgery. CONCLUSION: [3H]thymidine incorporation into whole liver tissue is a simple technique that can be used for the study of liver cell proliferation after partial hepatectomy in rats.     

Effect of developmental stage on arginase and urea production in the liver of rat

Arginase activity in the liver, brain, and testis of rats was examined during the different phases of life span. When expressed as specific activity (micromoles of L-arginine hydrolyzed per minute per gram of whole homogenate protein), the enzyme activity in the brain and testis decreased markedly during the early stage of life and stayed low during the remainder of the life span. On the other hand, the arginase in the liver showed a great dependency on the developmental phase of the animal, showing two distinct peaks: one during the early phase (20 days after birth) and the other at a later time (3 months of age). This pattern of change in the hepatic arginase activity closely coincided with the pattern of the rate of urea synthesis determined with liver slices and expressed in terms of micromoles of urea formed per hour per gram of tissue slice. In contrast to the above observations, however, curves obtained by plotting the total liver arginase or urea synthetic activity vs the developmental stage of rats showed no measurable discontinuity. Further studies revealed that the observed pattern of specific activity of hepatic arginase was, in part, due to the change in the relative concentration of arginase protein in the liver.     

Fatty acid synthesis in the regenerating liver of the rat.

1. Synthesis de novo of fatty acids in the rat liver, measured per g wet wt. of tissue, was increased by a factor of about two, between 1 and 4 days after partial hepatectomy, compared with rates in sham-operated control rat livers. 2. There were no associated changes in the rates of liver cholesterol synthesis or of adipose-tissue fatty acid synthesis in rats after partial hepatectomy, compared with rates in sham-operated rats. 3. In regenerating livers, perfused under three different conditions, there was no alteration in the capacity for fatty acid synthesis compared with that of control rats. 4. The increased synthesis of fatty acids in regenerating liver was associated with insignificant increases in plasma concentrations of tricylglycerols and free fatty acids, with a decrease in content of liver glycogen, and with no change in hepatic activity of acetyl-CoA carboxylase. 5. The accelerated rate of synthesis of fatty adids in regenerating liver appears not to be due to any intrinsic alteration in hepatic capacity for fatty acid synthesis, but it may be caused by the continuous action on liver of unidentified circulating factors.     

Biliary secretion in the rat after partial hepatectomy

The secretory efficiency of the liver increased in rats at 12 hr after partial hepatectomy. The secretory efficiency was seen to decrease at 24 hr after partial hepatectomy and increased again at 2-4 days following liver resection. These changes would correspond to the evolution of the hepatocyte proliferative process. The secretion of bile acids expressed per 100 g of body weight had returned to normal at 16 days after partial hepatectomy, although choleresis and the secretion of inorganic electrolytes remained lowered.     

Restoration of hepatic mast cells and expression of a different mast cell protease phenotype in regenerating rat liver after 70%-hepatectomy

Mast cells (MC) can undergo significant changes in number and phenotype; these alterations result in the differential expression of growth factors and cytokines. Kit ligand (KL; stem cell factor) is produced by mesenchymal cells, and in the liver by biliary epithelial cells. Recent studies suggest that KL, and its receptor c-kit, may be involved in liver regeneration after loss of liver mass. However, KL is also the major growth, differentiating, chemotactic, and activating factor for MC. The aim of our study was to elucidate the dynamics and phenotype of hepatic MC and KL/c-kit expression during liver regeneration after partial (70%) hepatectomy in the rat. Regenerating livers were harvested after 1, 3, 7, and 14 days, respectively (n = 6 each day). MC were stained for naphthol-AS/D-chloroacetate esterase and counted as MC per bile ductule. MC phenotype was assessed by rat MC protease (RMCP)-1 and -2 immunofluorescence staining, in order to distinguish RMCP-1 positive connective tissue MC (CTMC) from RMCP-2 positive mucosa MC (MMC). mRNA expression of RMCP, c-kit, and the differentially spliced variants of KL was quantified by RT-PCR. MC counts per bile ductule decreased in regenerating rat liver tissue at day 3, compared with native livers, and became normal thereafter. Hepatic MC were predominantly of a CTMC phenotype expressing RMCP-1, as previously published; after hepatectomy, between 76 and 99% of all MC double-expressed RMCP-1 and -2, compatible with an MMC phenotype. The ratio of the two alternatively spliced mRNAs for KL (KL-1 : KL-2), and c-kit mRNA expression did not differ significantly between regenerating livers and the livers of sham operated animals. These results suggest that hepatic mast cells are restored during liver regeneration after partial hepatectomy in the rat. Restored MC express an MMC phenotype, suggesting migration from outside into the regenerating liver. Alternative splicing of KL is affected by the surgical procedure in general, and, together with its receptor c-kit, doesn't seem to be involved in liver regeneration after partial hepatectomy in the rat. Further functional studies, and studies in regenerating human livers might offer the possibility of elucidating the role of the hepatic mast cell, and its different protease phenotypes during liver regeneration after surgical loss of liver mass.     

The impact of cortisol in steatotic and non‐steatotic liver surgery

The intent of this study was to examine the effects of regulating cortisol levels on damage and regeneration in livers with and without steatosis subjected to partial hepatectomy under ischaemia–reperfusion. Ultimately, we found that lean animals undergoing liver resection displayed no changes in cortisol, whereas cortisol levels in plasma, liver and adipose tissue were elevated in obese animals undergoing such surgery. Such elevations were attributed to enzymatic upregulation, ensuring cortisol production, and downregulation of enzymes controlling cortisol clearance. In the absence of steatosis, exogenous cortisol administration boosted circulating cortisol, while inducing clearance of hepatic cortisol, thus maintaining low cortisol levels and preventing related hepatocellular harm. In the presence of steatosis, cortisol administration was marked by a substantial rise in intrahepatic availability, thereby exacerbating tissue damage and regenerative failure. The injurious effects of cortisol were linked to high hepatic acethylcholine levels. Upon administering an α7 nicotinic acethylcholine receptor antagonist, no changes in terms of tissue damage or regenerative lapse were apparent in steatotic livers. However, exposure to an M3 muscarinic acetylcholine receptor antagonist protected livers against damage, enhancing parenchymal regeneration and survival rate. These outcomes for the first time provide new mechanistic insight into surgically altered steatotic livers, underscoring the compelling therapeutic potential of cortisol–acetylcholine–M3 muscarinic receptors.     

Temporary changes in arylsulphatase activity in mouse liver after gamma-irradiation

Temporary changes in arylsulphatase (EC 3.1.6.1) activity in the liver of adult male Swiss mice after gamma-irradiation were studied. The animals were whole-body irradiated with a single dose of 10 Gy from a 60Co source, always at 19.00. The enzyme activity in crude liver homogenates was assessed every four hours during the 24-hour period, starting at 20.00. The enzyme activity with p-nitrocatechol sulphate as a substrate was related to mg of protein, gram of fresh tissue, and the whole organ weight. Protein concentration in the liver was calculated both per gram of fresh tissue and for the whole organ weight. The body and liver weights were also analysed. No fluctuations in the activity of arylsulphatase in the control mice were observed. Gamma-irradiated mice showed enzyme activity changes expressed in nkat per mg protein with a maximum at 4.00 and minimum at 20.00, twenty-five hours after irradiation. As compared with non-irradiated controls, the arylsulphatase activity calculated in nkat per g of fresh tissue and nkat per whole liver weight differed in irradiated animals which were killed at 4.00, while there was also a difference in the protein concentration in mg related to the whole organ weight in those killed at 12.00.     

Selective portal vein embolization as introduction in major surgery

In the period between the December 2000 and September 2004, altogether 13 patients underwent preoperative portal vein embolization (PPVE); 9 patients with colorectal metastases and 4 patients with hepatocellular carcinoma. The indirect splenic portography was performed after catheter was introduced into superior mesenteric artery via femoral artery approach. The portal vein was punctured percutaneously transhepatic under fluoroscopy. Following portography, selected portal vein segments were embolized by injecting polyvinil alcohol (PVA) particles until stasis of blood flow was achieved. Proximal parts of branches and the channel in the liver parenchyma were occluded with Gelfoam particles. The increase of the remnant liver parenchyma was measured by magnetic resonance imaging. iTwo patients experienced post-embolization syndrome and another one had subcapsular hematoma. The volume of the liver parenchyma increased minimally for 8% and maximally for 109%. Altogether, 10 patients underwent surgical resection. In two patients, the disease progressed and carcinoma spread to the previously healthy liver lobe and in one there was no hypertrophy and we decided for artery chemoembolization (AC). The results show that PPVE triggers a strong regenerative response resulting in hypertrophy of normal liver parenchyma and expand possibilities of curative surgery for patients who would not otherwise have been candidates for extended resection.     

Pretreatment with recombinant human interleukin 2 (rhIL-2) Up-regulates PCNA-positive cells after partial hepatectomy in rat liver

We prepared recombinant human interleukin-2 (rhIL-2) and studied its pretreated influence on liver regeneration and the blood profile in partially (67%) hepatectomized (PH) male Sprague-Dawley rats. Rats were injected in the tail vein with rhIL-2 three times per day for 3 consecutive days and 67% underwent a partial hepatectomy (PH). Five days after the PH, liver tissue and blood samples were analyzed for liver regeneration and hematological changes. The weight of the liver in the rhIL-2 pretreated groups increased in a dose-dependent manner; with the highest treatment (24 × 10⁴ IU/kg), the maximum liver weight of 88.6% was exhibited. The control group showed a gradual increase to 76.3% of the original liver weight. A histological analysis of the liver showed an increase in proliferating cell nuclear antigen (PCNA)-positive cells in rhIL-2 pretreated rat livers. The rate of hepatocyte proliferation also increased significantly in primary cultured rat liver cells following rhIL-2 treatment. These results suggest that pretreatment with rhIL-2 may play adjuvant roles in liver regeneration after PH.     

Control of hepatic nitrogen metabolism and glutathione release by cell volume regulatory mechanisms

1. Urea synthesis was studied in isolated perfused rat liver during cell volume regulatory ion fluxes following exposure of the liver to anisotonic perfusion media. Lowering of the osmolarity in influent perfusate from 305 mOsm/l to 225 mOsm/l (by decreasing influent [NaCl] by 40 mmol/l) led to an inhibition of urea synthesis from NH4Cl (0.5 mmol/l) by about 60% and a decrease of hepatic oxygen uptake by 0.43 +/- 0.03 mumol g-1 min-1 [from 3.09 +/- 0.13 mumol g-1 min-1 to 2.66 +/- 0.12 mumol g-1 min-1 (n = 9)]. The effects on urea synthesis and oxygen uptake were observed throughout hypotonic exposure (225 mOsm/l). They persisted although volume regulatory K+ efflux from the liver was complete within 8 min and were fully reversible upon reexposure to normotonic perfusion media (305 mOsm/l). A 42% inhibition of urea synthesis from NH4Cl (0.5 mmol/l) during hypotonicity was also observed when the perfusion medium was supplemented with glucose (5 mmol/l). Urea synthesis was inhibited by only 10-20% in livers from fed rats, and was even stimulated in those from starved rats when an amino acid mixture (twice the physiological concentration) plus NH4Cl (0.2 mmol/l) was infused. 2. The inhibition of urea synthesis from NH4Cl (0.5 mmol/l) during hypotonicity was accompanied by a threefold increase of citrulline tissue levels, a 50-70% decrease of the tissue contents of glutamate, aspartate, citrate and malate, whereas 2-oxoglutarate, ATP and ornithine tissue levels, and the [3H]inulin extracellular space remained almost unaltered. Further, hypotonic exposure stimulated hepatic glutathione (GSH) release with a time course roughly paralleling volume regulatory K+ efflux. NH4Cl stimulated lactate release from the liver during hypotonic but not during normotonic perfusion. In the absence of NH4Cl, hypotonicity did not significantly affect the lactate/pyruvate ratio in effluent perfusate. With NH4Cl (0.5 mmol/l) present, the lactate/pyruvate ratio increased from 4.3 to 8.2 in hypotonicity, whereas simultaneously the 3-hydroxybutyrate/acetoacetate ratio slightly, but significantly decreased. 3. Addition of lactate (2.1 mmol/l) and pyruvate (0.3 mmol/l) to influent perfusate did not affect urea synthesis in normotonic perfusions, but completely prevented the inhibition of urea synthesis from NH4Cl (0.5 mmol/l) induced by hypotonicity. Restoration of urea production in hypotonic perfusions by addition of lactate and pyruvate was largely abolished in the presence of 2-cyanocinnamate (0.5 mmol/l). Addition of 3-hydroxybutyrate (0.5 mmol/l), but not of acetoacetate (0.5 mmol/l) largely reversed the hypotonicity-induced inhibition of urea synthesis from NH4Cl.(ABSTRACT TRUNCATED AT 400 WORDS)     

Effect of α-difluoromethylornithine on polyamine and DNA synthesis in regenerating rat liver: Reversal of inhibition of DNA synthesis by putrescine

The possibility that α-difluoromethylornithine, a specific, irreversible inhibitor of ornithine decarboxylase could be used to prevent the rise in hepatic putrescine and spermidine content following partial hepatectomy was tested. Administration of α-difluoromethylornithine at a dose of 400 mg/kg every 4 h reduced hepatic putrescine to <2 nmol/g, but had only a small effect on the rise in spermidine seen at 28 h after partial hepatectomy. Such treatment also reduced the rise in DNA synthesis produced by partial hepatectomy by up to 70%. The inhibitory effect towards DNA synthesis could be reversed by administration of putrescine which increased the hepatic putrescine content to about 30–40% of that in the regenerating control livers. These results suggest that accumulation of putrescine rather than spermidine is needed for DNA synthesis after partial hepatectomy. They also suggest that part, but not all of the rise in putrescine normally seen in the liver after partial hepatectomy is needed for the enhanced DNA synthesis associated with liver regeneration. Experiments with lower doses of α-difluoromethylornithine showed that a substantial part of the rise in hepatic ornithine decarboxylase activity could be abolished without affecting either the rise in spermidine content or the increase in DNA synthesis after partial hepatectomy.     

The effect of prolonged oligohydramnios on fetal lung development, maturation and ventilatory patterns in the newborn guinea pig

We drained the amniotic fluid surrounding guinea pig fetuses between days 45 and 65 of gestation (term is 67 days). The fetuses were delivered by Cesarean section and the impact of prolonged oligohydramnios on lung growth, maturation and postnatal ventilatory pattern was measured. Untouched littermate fetuses served as controls. Neither fetal body, liver nor brain weights were significantly affected by the experimental situation. When expressed in percent of control values, lung weight (63%), lung/body weight ratio (70%), lung volume (67%), total lung DNA content (63%) and lung DNA per gram of fetal weight (71%) were all significantly less following amniotic fluid drainage, confirming the diagnosis of lung hypoplasia. Disaturated phosphatidylcholine content per gram of lung tissue and total lung glycogen content were not affected by the procedure, indicating that the maturity of the hypoplastic lungs was not delayed. When measured 4 to 6 hours after birth, tidal volume was significantly less (62%) and respiratory frequency was significantly more (137%); however, minute ventilation per unit of body weight was not significantly changed. This animal model of sublethal lung hypoplasia could become useful to study the potential for, and the kinetics of, postnatal catch-up lung growth about which little is known.     

Comparison of metabolism of free fatty acid by isolated perfused livers from male and female rats.

Livers from normal, fed male and female rats were perfused with different amounts of [1-14C]oleate under steady state conditions, and the rates of uptake and utilization of free fatty acid (FFA) were measured. The uptake of FFA by livers from either male or female rats was proportional to the concentration of FFA in the medium. The rate of uptake of FFA, per g of liver, by livers from female rats exceeded that of the males for the same amount of FFA infused. The incorporation by the liver of exogenous oleic acid into triglyceride, phospholipid, and oxidation products was proportional to the uptake of FFA. Livers from female rats incorporated more oleate into triglyceride (TG) and less into phospholipid (PL) and oxidation products than did livers from male animals. Livers from female rats secreted more TG than did livers from male animals when infused with equal quantities of oleate. The incorporation of endogenous fatty acid into TG of the perfusate was inhibite) by exogenous oleate. At low concentrations of perfusate FFA, however, endogenous fatty acids contributed substantially to the increased output of TG by livers from female animals. Production of 14CO2 and radioactive ketone bodies increased with increasing uptake of FFA. The partition of oleate between oxidative pathways (CO2 production and ketogenesis) was modified by the availability of the fatty acid substrate with livers from either sex. The percent incorporation of radioactivity into CO2 reached a maximum, whereas incorporation into ketone bodies continued to increase. The output of ketone bodies was dependent on the uptake of FFA, and output by livers from female animals was less than by livers from male rats. The increase in rate of ketogenesis was dependent on the influx of exogenous FFA, while ketogenesis from endogenous sources remained relatively stable. The output of glucose by the liver increased with the uptake of FFA, but no difference due to sex was observed. The output of urea by livers from male rats was unaffected by oleate, while the output of urea by livers from females decreased as the uptake of FFA increased. A major conclusion to be derived from this work is that oleate is not metabolized identically by livers from the two sexes, but rather, per gram of liver, livers from female rats take up and esterify more fatty acid to TG and oxidize less than do livers from male animals; livers from female animals synthesize and secrete more triglyceride than do livers from male animals when provided with equal quantities of free fatty acid.     

Proteomic analysis of regenerating mouse liver following 50% partial hepatectomy

Background

Although 70% (or 2/3) partial hepatectomy (PH) is the most studied model for liver regeneration, the hepatic protein expression profile associated with lower volume liver resection (such as 50% PH) has not yet been reported. Therefore, the aim of this study was to determine the global protein expression profile of the regenerating mouse liver following 50% PH by differential proteomics, and thereby gaining some insights into the hepatic regeneration mechanism(s) under this milder but clinically more relevant condition.

Results

Proteins from sham-operated mouse livers and livers regenerating for 24 h after 50% PH were separated by SDS-PAGE and analyzed by nanoUPLC-Q-Tof mass spectrometry. Compared to sham-operated group, there were totally 87 differentially expressed proteins (with 50 up-regulated and 37 down-regulated ones) identified in the regenerating mouse livers, most of which have not been previously related to liver regeneration. Remarkably, over 25 differentially expressed proteins were located at mitochondria. Several of the mitochondria-resident proteins which play important roles in citric acid cycle, oxidative phosphorylation and ATP production were found to be down-regulated, consistent with the recently-proposed model in which the reduction of ATP content in the remnant liver gives rise to early stress signals that contribute to the onset of liver regeneration. Pathway analysis revealed a central role of c-Myc in the regulation of liver regeneration.

Conclusions

Our study provides novel evidence for mitochondria as a pivotal organelle that is connected to liver regeneration, and lays the foundation for further studies on key factors and pathways involved in liver regeneration following 50% PH, a condition frequently used for partial liver transplantation and conservative liver resection.     

Portal Hyperperfusion after Extended Hepatectomy Does Not Induce a Hepatic Arterial Buffer Response (HABR) but Impairs Mitochondrial Redox State and Hepatocellular Oxygenation

Background & Aims

Portal hyperperfusion after extended hepatectomy or small-for-size liver transplantation may induce organ dysfunction and failure. The underlying mechanisms, however, are still not completely understood. Herein, we analysed whether hepatectomy-associated portal hyperperfusion induces a hepatic arterial buffer response, i.e., an adaptive hepatic arterial constriction, which may cause hepatocellular hypoxia and organ dysfunction.

Methods

Sprague-Dawley rats underwent 30%, 70% and 90% hepatectomy. Baseline measurements before hepatectomy served as controls. Hepatic arterial and portal venous flows were analysed by ultrasonic flow measurement. Microvascular blood flow and mitochondrial redox state were determined by intravital fluorescence microscopy. Hepatic tissue pO2 was analysed by polarographic techniques. Hepatic function and integrity were studied by bromosulfophthalein bile excretion and liver histology.

Results

Portal blood flow was 2- to 4-fold increased after 70% and 90% hepatectomy. This, however, did not provoke a hepatic arterial buffer response. Nonetheless, portal hyperperfusion and constant hepatic arterial blood flow were associated with a reduced mitochondrial redox state and a decreased hepatic tissue pO2 after 70% and 90% hepatectomy. Microvascular blood flow increased significantly after hepatectomy and functional sinusoidal density was found only slightly reduced. Major hepatectomy further induced a 2- to 3-fold increase of bile flow. This was associated with a 2-fold increase of bromosulfophthalein excretion.

Conclusions

Portal hyperperfusion after extended hepatectomy does not induce a hepatic arterial buffer response but reduces mitochondrial redox state and hepatocellular oxygenation. This is not due to a deterioration of microvascular perfusion, but rather due to a relative hypermetabolism of the remnant liver after major resection.     

STUDIES ON LIVER REGENERATION: II. EFFECTS of PHENOBARBITAL ON the ONSET and PATTERN of RAT LIVER REGENERATION FOLLOWING PARTIAL HEPATECTOMY

Abstract. Partially hepatectomized rats were given a single intraperitoneal injection of a phenobarbital solution or of water immediately after surgery. At various time intervals following the operation, the animals were injected with ¹³¹ iododeoxyuridine (¹¹³IDU), sacrificed 2 hr later, and radioactivity retained in formalin-fixed liver tissue was determined as a measure of DNA synthesis at the time of administration of the labeled precursor. In control animals without phenobarbital treatment, ¹³¹IDU incorporation into liver began to increase between 14 and 16 hr after partial hepatectomy. Phenobarbital treatment (0.1 mg per g of body weight) resulted in a delay of the increase in ¹³¹IDU incorporation by several hours. This delay was observed in animals subjected to partial hepatectomy in the morning as well as in those operated on in the evening. After phenobarbital treatment, the increase of mitotic activity was either delayed or occurred more slowly. the results are compared with the reported effects of partial hepatectomy on the time course of microsomal enzyme induction by phenobarbital.     

Influence of Pre-, Intra- and Post-Operative Parameters of Donor Liver on the Outcome of Isolated Human Hepatocytes

The aim of the present study was to analyse, retrospectively on a large panel of patients (149), the influence of the donor liver characteristics on the outcome of human hepatocyte isolation obtained from resected liver biopsies from surgical waste after hepatectomy. Among the pre-operative parameters, the type of disease, age and sex of the patient, previous chemotherapy, alcohol or tobacco consumption did not affect the yield, viability, attachment rate and function of the isolated human hepatocytes. Pre-operative biological and anatomopathological data indicated that, while mild steatosis (≤10% steatotic hepatocytes) did also not affect the outcome of hepatocyte isolation, stronger steatosis (>10% steatotic hepatocytes) tended to decrease hepatocyte yield. Cholestasis, as assessed by γ-glutamyl transferase serum values, significantly negatively correlated with the percentage of digested liver and the yield of viable cells. Intra-operative clamping time, that is, warm ischaemia, longer than 30 min was found to decrease both the percentage of digested liver and cell yield. Among the post-operative parameters, the percentage of digested liver decreased when biopsy weights were higher than 100 g, the use of glue tended to increase both the percentage of digested tissue and the yield of viable cells. In conclusion, human diseased livers appear to be a valuable source of isolated functional human hepatocytes. We recommend, for an optimal isolation, to use liver biopsies weighing less than 100 g, to glue the section surfaces of the biopsies and to avoid the use of moderate steatotic livers (>10% steatotic hepatocytes) and cholestatic livers, as well as livers undergoing warm ischaemia or clamping during resection due to the decrease in cell yield. This revised version was published online in July 2006 with corrections to the Cover Date.