The effect of glucagon and blood transfusion on hepatic circulation and oxygen consumption in hemorrhagic shock

Ten pigs were subjected to a standard shock model, including two 30-min periods of hemorrhagic shock at 50 mm Hg. After the first period of shock, treatment was given with glucagon and transfusion of the shed blood. Portal vein and hepatic artery flow as well as oxygen consumption were measured. Both periods of shock resulted in a marked decrease in blood flow as well as oxygen consumption.Treatment with glucagon and blood transfusion resulted in an increase in hepatic artery flow to 300% of the preshock value but no significant increase in the portal vein flow compared with blood transfusion alone. The high hepatic artery flow caused a very high inflow of oxygen to the liver. In spite of this high inflow of oxygen, the oxygen consumption of the liver was not significantly higher than after blood transfusion alone.     

Experimental study of partial arterialization of the portal vein on the dearterialized liver

The influence of hepatic arterial obstruction on the hepatic circulation and tissue metabolism was studied between animals with and without partial arterialization of the portal vein. Mongrel dogs were divided into these groups: a group in which the collaterals to the liver were obstructed and the hepatic artery was dissected (hepatic artery ligated group); two groups in which an extracorporeal femoral artery-portal vein shunt was produced, and blood was sent by a Biopump at a rate of 100 or 200 ml/min (100 ml/min and 200 ml/min portal arterialized groups). The hepatic artery ligated group showed CO2 accumulation and acidosis in hepatic venous blood, reduction of oxygen supply, increase of oxygen consumption and marked increase of GOT and GPT. In the portal arterialized groups, sufficient oxygenation of portal blood was noted, and the oxygen demand and supply and tissue metabolism were kept approximately normal. The optimum flow rate for partial arterialization of the portal vein seemed to be 100 ml/min. At the flow rate of 200 ml/min, the original portal blood was reduced, leading to portal hypertension and increase of GOT and GPT. These results indicate that partial arterialization of the portal vein effectively preserves the liver function during the operation and in the early period after dissection of the hepatic artery.     

A pilot study on early versus delayed hypertonic saline dextran resuscitation in a porcine model of near-lethal liver injury: early hemodynamic response and short-term survival

BACKGROUND: We studied the effects of early versus delayed fluid resuscitation on hemodynamic response and short-term survival in a porcine model of severe hepatic injury associated with hemorrhagic shock. MATERIALS AND METHODS: Eighteen anesthetized swine were randomized after standardized liver injury into two groups: early resuscitation (ER, n = 9) and delayed resuscitation (DR, n = 9). The ER and DR groups were resuscitated with hypertonic saline dextran (HSD) 20 min and 40 min after the injury, respectively. Mean arterial pressure (MAP), cardiac output (CO), and arterial blood gases were measured in addition to vascular blood flow rates in the aorta, hepatic artery and portal vein. The duration of follow-up was 100 min. RESULTS: MAP decreased from 112 +/- 4 to 23 +/- 2 mmHg (P < 0.05) during 20 min after the injury. Bolus infusion of HSD significantly elevated MAP, CO, and flow rates in the aorta, portal vein and common hepatic artery in both groups. Portal vein flow remained relatively high during the shock. Intra-abdominal bleeding (ER, 701 +/- 42 mL; DR 757 +/- 78 mL) and the mortality rate (ER 44%; DR 33%) did not differ between the groups 100 min after injury (P > 0.05). Aortic flow, portal vein flow, common hepatic artery flow, MAP, CO, PaO(2), PaCO(2), base deficit, pH, hemoglobin measurements, and the volume of blood shed into the intraperitoneal cavity did not affect survival in the Cox regression analysis. CONCLUSIONS: Early versus delayed fluid infusion with HSD resulted in a comparable hemodynamic response and survival 100 min after injury. No rebleeding was observed.     

Liver circulation and oxygen metabolism during short time ligation and the hepatic artery in the dog

The changes of liver circulation and liver oxygen metabolism during and after one hour hepatic artery ligation (HAL) were studied in eight mongrel dogs. At the end of the HAL period total hepatic blood flow (THBF) was reduced from 115.6 +/- 5.5 ml/min . 100 g liver tissue to 68.0 +/- 3.7 ml/min . 100 g or 59% of the initial value. The portal venous blood flow was reduced from 83.1 +/- 3.4 to 58.8 +/- 3.7 ml/min . 100 or 82% of the initial value and the liver oxygen consumption was reduced from 4.1 +/- 0.2 ml/min . 100 g to 3.1 +/- 0.3 ml/min . 100 g or 76% of the initial value. The changes in portal venous blood flow and liver oxygen consumption were reversible following reopening of the hepatic artery. The clinical importance of a reduced portal venous blood flow and liver oxygen consumption following HAL and the possibilities to increase the portal venous blood flow are discussed.     

Effect of propofol on hepatic blood flow and oxygen balance in rabbits

PURPOSE: Propofol has been reported to alter hepatic blood flow and to increase hepatic oxygen consumption. This study was designed to determine the effect of propofol on hepatic blood flow and oxygenation in rabbits, in order to establish its net effect on hepatic oxygen balance. METHODS: Twenty, adult male, New Zealand white rabbits were randomly divided into two groups: Group P (propofol, 0.6 mg.kg(-1).min(-1)) or Group C (10% intralipid, 0.6 mg.kg(-1).min(-1)). An electromagnetic flowmeter was used to measure hepatic blood flow, and blood, from the carotid artery, the portal vein, and the hepatic vein, was used to determine hepatic oxygenation. After we obtained baseline values, we repeated measurements ten, 30, and 60 min after initiating the infusion. RESULTS: Intralipid did not affect systemic hemodynamics, hepatic blood flow, or oxygenation during the 60 min infusion; however, propofol caused a time-dependent decrease in mean arterial blood pressures and an increase in portal venous flow and total hepatic blood flow. In contrast, hepatic arterial blood flow remained unchanged during the propofol infusion. Hepatic oxygen delivery and consumption increased in a time-dependent manner to maximums of 25% and 21.4% (both, P < 0.05) above baseline, respectively. Hepatic venous oxygen saturation and extraction was unchanged throughout the study period. CONCLUSION: Propofol increases total hepatic blood flow, primarily by increasing hepatic portal venous flow. The increase in liver oxygen consumption was fully compensated by an increase in oxygen supply to the liver, resulting in a preserved, hepatic oxygen balance.     

失血性休克期间器官血流量的变化

本文研究了氯胺酮麻醉犬出血性休克期间器官血流量的变化。杂种犬７只，放血２６７±２０．５８ｍｌ，休克持续４５ｍｉｎ，用电磁血流量计测得失血性休克期间肝动脉血流量、门静脉血流量、右肾动脉血流量、颈内动脉血流量降低非常显著，心率显著增快。     

The synergistic effects of pentoxifylline on systemic and regional perfusion after hemorrhage and hypertonic resuscitation

Small volumes of hypertonic saline solution ([HS] 7.5% NaCl) produce systemic and microcirculatory benefits in hemorrhaged animals. Pentoxifylline (PTX) has beneficial effects when administrated after hemorrhagic shock. We tested the hypothesis that the combination of HS and PTX in the initial treatment of hemorrhagic shock provides synergistic hemodynamic benefits. Twenty-four dogs were bled to a target arterial blood pressure of 40 mm Hg and randomized into 3 groups: lactated Ringer's solution (33 mL/kg; n = 6); HS (7.5% NaCl 4 mL/kg; n = 9); and HS+PTX (7.5% NaCl 4 mL/kg + PTX 15 mg/kg; n = 9). Systemic hemodynamics were measured by Swan-Ganz and arterial catheters. Gastric mucosal-arterial Pco2 gradient (D(g-a)Pco2; gas tonometry), portal vein blood flow (ultrasonic flowprobe), and systemic and regional O2-derived variables were also evaluated. HS induced a partial increase in mean arterial blood pressure, cardiac output, and portal vein blood flow. In the HS+PTX group, we observed a significant, but transitory, increase in systemic oxygen delivery (180 +/- 17 versus 141 +/- 13 mL/min) in comparison to HS alone. PTX infusion during hypertonic resuscitation promoted a significant reduction in D(g-a)Pco2 (41.8 +/- 4.8 to 25.7 +/- 3.9 mm Hg) when compared with isolated HS infusion (48.2 +/- 6.4 to 39.4 +/- 5.5 mm Hg). We conclude that PTX as an adjunct drug during hypertonic resuscitation improves cardiovascular performance and gastric mucosal oxygenation.     

Attenuation of vascular endothelial dysfunction by testosterone receptor blockade after trauma and hemorrhagic shock

HYPOTHESIS: The salutary effects of the testosterone receptor antagonist flutamide on the depressed immune and cardiovascular functions after hemorrhage and resuscitation are related to improved endothelial cell function, which can subsequently lead to an increase in organ blood flow, oxygen delivery, and tissue oxygen consumption. DESIGN, INTERVENTIONS, AND MAIN OUTCOME MEASURES: Male adult rats underwent a 5-cm midline laparotomy (ie, trauma) and were bled to and maintained at a mean systemic arterial pressure of 40 mm Hg until 40% maximal blood-out volume was returned in the form of Ringer lactate). The animals were then resuscitated with 4 times the total volume of shed blood with Ringer lactate for 60 minutes. Flutamide (25 mg/kg) or an equivalent volume of the vehicle propanediol was injected subcutaneously 15 minutes before the end of resuscitation. At 20 hours after resuscitation, aortic rings (approximately 2.5 mm in length) were isolated and mounted in an organ chamber. Dose responses for an endothelium-dependent vasodilator (acetylcholine chloride) and endothelium-independent vasodilator (nitroglycerine) were determined. Organ blood flow was measured using strontium 85-labeled microspheres. Total hemoglobin and oxygen content in the femoral artery and portal, hepatic, and renal veins were determined. Oxygen delivery and consumption in liver, small intestine, and kidneys were calculated. RESULTS: Administration of flutamide after trauma-hemorrhage attenuated the depressed endothelial function. Furthermore, flutamide treatment restored the reduced blood flow and oxygen delivery and consumption in all organs tested after trauma-hemorrhage and resuscitation. CONCLUSION: Flutamide appears to be a useful adjunct for improving vascular endothelial function and regional hemodynamics after trauma-hemorrhage and resuscitation.     

比较硬膜外阻滞复合安氟醚或异氟醚对肝血流及氧代谢的影响

目的 探讨硬膜外阻滞与安氟醚或异氟醚吸入复合麻醉对血流动力学,肝血流及代谢的影响。方法 选用健康杂种犬２０只行胸段硬膜外阻滞后分为两缚,分别吸入,０．５和１．０ＭＡＣ安氟醚或异氟醚,监测麻醉前后体循环,肝动脉,门静脉血流动力及肝脏氧供,氧耗。结果 硬膜外阻滞后血压,门静脉血流和氧供下降,加吸安氟醚０．５ＭＡＣ使心排血量也下降,１．０ＭＡＣ后肝动脉血流及氧供也减少,加吸异氟醚０．５ＭＡＣ心排血量稳定     

Arterial blood supply of the liver

We examined (dogs) the influence of hypovolaemic shock and reversible interruption of the portal vein on the arterial blood flow and metabolism of the liver. Depending on the arterial mean-pressure hypovolaemic shock decreases the flowrate of the hepatic artery, while it is increases to 30 to 40% during interruption of the portal vein. Whether hypoxy will cause liver damage or not is only dependant from the resulting oxygen supply of the liver. This critical range is below 6 to 7 ml/min per 100 g liver tissue.     

Hepatic blood flow and oxygen consumption after burn and sepsis

BACKGROUND: Alteration in the hepatic circulation after burn and in sepsis seems to be an essential component in the development of multiple organ failure. METHODS: Female pigs (n = 12, 20-25 kg) were instrumented with ultrasonic flow probes on the portal vein and the common hepatic artery. Catheters were inserted in the superior mesenteric and left hepatic veins. After 5 days, all animals were anesthetized and six of them received 40% total body surface area third-degree burn. A total of 100 microg/kg Escherichia coli LPS was intravenously administered at 18 hours after burn. All animals were studied for 42 hours. RESULTS: Thermal injury resulted in a 48% decrease in hepatic arterial blood flow despite maintenance of normal cardiac output, resulting in a fall in hepatic oxygen delivery rate. Portal venous blood flow showed a 32% increase at 4 hours after burn. Post-LPS portal blood flow was significantly reduced for a period of 8 hours (51% of baseline (bl), p < 0.05 analysis of variance [ANOVA]). The hepatic arterial blood supply was also significantly reduced (12-67% of bl, p < 0.05 ANOVA) during the first 4 hours after LPS, indicating loss of the hepatic arterial response. The following 12 hours, a hepatic reperfusion phase was observed with an elevation of the hepatic arterial blood flow to 152% of bl (p < 0.05 ANOVA). Postburn endotoxemia resulted in a significant decrease of hepatic oxygen delivery (88%) and hepatic oxygen consumption (79%). Although the burn injury did not affect the portal venous pressure, postburn endotoxemia caused a significant portal hypertension during a period of 8 hours (225% of bl, p < 0.05 ANOVA). CONCLUSION: Postburn sepsis amplifies the selective vasconstrictive impact of thermal injury on hepatic arterial blood flow, yielding a pronounced ischemia/ reperfusion injury, associated with a critical reduction of hepatic oxygen delivery and consumption. A postburn septic challenge induces portal hypertension, which may account for previously documented gut barrier dysfunction.     

Hepatic arterial and portal venous flows during hemorrhage.

Changes of total liver blood flow (TLBF), portal venous and hepatic arterial flows have been investigated using a hemorrhagic model in dogs. The dogs were bled stepwise from normal blood pressure to a pressure of 50-60 mm Hg. TLBF was measured by the xenon clearance method. Hepatic arterial blood flow was measured by electromagnetic flowmeter. Portal venous flow was calculated by subtracting hepatic arterial blood flow from TLBF. Other parameters studied during the experiment were systemic arterial blood pressure and portal venous pressure. Under normotensive conditions TLBF in mean was registered as 127 ml/min X 100 g liver tissue (25 ml/min X kg body weight). The relation between the flow value in portal vein and hepatic artery was on average 2.3:1. The study shows that there was a pronounced decrease of TLBF flow during hemorrhage. Portal venous flow decreased almost parallel to TLBF, while hepatic arterial flow decreased to a lesser extent which means that there was autoregulation in this flow bed. Hepatic arterial flow successively constituted a larger part of TLBF, during hemorrhage sometimes 65% compared to the normal value of about 30%. During the study there was an increase of vascular resistance in the portal venous system and decreased resistance in the hepatic arterial bed.     

The effects of vasopressin on systemic and splanchnic hemodynamics and metabolism in endotoxin shock

We compared the effects of vasopressin and norepinephrine on systemic and splanchnic circulation and metabolism in endotoxin shock in pigs. Twenty-one pigs were randomized to endotoxin shock (Escherichia coli endotoxin infusion) (n = 6), endotoxin and vasopressin (VASO; n = 6), endotoxin and norepinephrine (NE; n = 6), and controls (n = 3). Endotoxin infusion was increased to induce hypotension, after which vasopressin or norepinephrine was started to keep systemic mean arterial blood pressure >70 mm Hg. Regional blood flows and arterial and regional lactate concentrations were measured. Tonometers with microdialysis capillaries were inserted into the stomach, jejunum, and colon. Systemic mean arterial blood pressure >70 mm Hg was achieved in the VASO and NE groups. Vasopressin decreased cardiac output, superior mesenteric artery, and portal vein blood flow, whereas hepatic arterial blood flow increased. Arterial lactate concentration increased from 2.0 mM (1.6-2.1 mM) to 4.7 mM (4.7-4.9 mM) (P = 0.007). Systemic and mesenteric oxygen delivery and consumption decreased and oxygen extraction increased in the VASO group. Vasopressin increased mucosal-arterial PCO(2) gradients in all three locations, whereas luminal lactate release occurred only in the jejunum. Animals in the NE group remained stable. Vasopressin reversed hypotension but decreased systemic and gut blood flow. This was associated with hyperlactatemia, signs of visceral dysoxia, and jejunal luminal lactate release. IMPLICATIONS: Although vasopressin induces vasoconstriction in visceral region, its effects on splanchnic circulation and metabolism during septic-endotoxin shock are still poorly characterized. We evaluated the metabolic and hemodynamic effects of vasopressin and norepinephrine within the splanchnic area in porcine endotoxin shock.     

The effect of low dose dopamine on gut hemodynamics during PEEP ventilation for acute lung injury

Mechanical ventilation with positive end-expiratory pressure (PEEP) diminishes gut and hepatic blood flow and redistributes cardiac output away from the splanchnic circulation. This flow-limited environment can aggravate underlying hypoperfusion and ischemia in the postinjury setting. To examine the effects of low dose dopamine on a lung injury PEEP model of gut hypoperfusion, six anesthetized, splenectomized canines were instrumented with arterial, pulmonary artery, portal vein, and hepatic vein catheters. Electromagnetic flow probes were placed around the hepatic artery and portal vein for continuous flow measurements. Gut and hepatic blood flow, oxygen delivery, oxygen consumption, and extraction ratio were calculated at four time points: baseline, 1 hr after lung injury with oleic acid, 1 hr after ventilation with 10 cm H2O PEEP, and 1 hr after the continuous infusion of dopamine. Portal flow and gut oxygen delivery fell significantly with the infusion of PEEP. These values returned to near baseline levels with the addition of dopamine. Gut oxygen extraction increased from 16 +/- 2% to 35 +/- 3% with PEEP but returned to near baseline with dopamine (20 +/- 4%, P less than 0.01 compared to PEEP). We conclude that dopamine improves blood flow and oxygen delivery to the gut in this flow-limited model. This may preserve splanchnic physiology during PEEP ventilation for acute lung injury.     

Temporary portal vein arterialization as an attractive option in canine orthotopic partial liver transplantation.

We performed 22 canine orthotopic partial liver transplantations (PLTs) with three different revascularization methods; portal vein arterialization (PVA group, n = 11), hepatic arterial shunt (HAS group, n = 5), and conventional portal vein reperfusion (control group, n = 6). Our purpose was to evaluate the feasibility of PVA as a revascularization technique in PLT assessing the changes in arterial ketone body ratio (KBR) as an index of hepatic energy status. After the first anastomosis (left hepatic vein), the ischemic partial liver graft was revascularized with arterial blood flow shunted from the external iliac artery to the hepatic side of the portal vein (PVA group) or the proper hepatic artery (HAS group). Both anhepatic period and ischemia time were significantly shortened in groups PVA and HAS as compared with those in control. In the PVA group, 10 out of 11 recipients survived for at least 5 days (14.2 +/- 3.8 days, mean +/- SEM), while 3 out of 5 (5.2 +/- 1.0) survived in the HAS group and 4 out of 6 (6.2 +/- 1.3) in the controls. Although portal blood flow during PVA was only about 25% of the total hepatic blood flow at preclamping, the KBR was rapidly restored after PVA and showed almost the same values at preclamping. The KBR values during the arterialization time and initial velocity of KBR recovery in the PVA group were significantly higher than those in the HAS and control groups. These results suggest that PVA presents an attractive option in PLT.     

Hemihepatectomy and replacement of the afferent hepatic blood supply in the dog. Resection of liver and hepatoduodenal ligament

Hemihepatectomy along with portal vein or hepatic artery replacement in dogs was well tolerated, but combined with replacement of both vessels it was lethal because of outflow block and shock. Total liver blood flow should be kept as high as possible during such procedures in man.     

控制性低中心静脉压对兔肝缺血再灌注损伤的影响

目的 评价控制性低CVP对兔肝缺血再灌注损伤的影响.方法 新西兰大白兔32只,随机分为4组(n=8):假手术组(S组)、控制性低CVP组(L组)、肝缺血再灌注组(IR组)和控制性低CVP下肝缺血再灌注组(LIR组).L组静脉输注硝酸甘油10～30μg·kg~(-1)·min~(-1)和多巴胺30～40μg·kg~(-1)·min~(-1),在5 min内使CVP降至4～5 cm H_2O且维持MAP≥90 mm Hg,持续至再灌注6 h.IR组采用夹闭肝门30 min后再开放的方法建立肝缺血再灌注模型.LIR组在控制性低CVP模型制备成功后立即进行肝缺血再灌注.分别于实施控制性低CVP前(T_0,基础状态)、再灌注即刻(T_1)、30 min(T_2)、1 h(T_3)、2 h(T_4)、4 h(T_5)、6 h(T_6)时采用彩色超声多普勒诊断仪测定门静脉、肝动脉和肝静脉的血流速度,同时采集动脉血样,测定血浆AST和ALT的活性.于再灌注6 h时,取肝组织,电镜下观察细胞超微结构.结果 与S组比较,L组各时点门静脉、肝动脉、肝静脉的血流速度、血浆AST和ALT的活性差异无统计学意义(P＞0.05),IR组T_(1～5)时肝动脉血流速度减慢,T_(5,6)时肝静脉血流速度增快,血浆AST和ALT的活性升高,LIR组T_(1～6)时肝静脉血流速度度增快,T_(1～6)时血浆AST和ALT的活性升高(P＜0.05);与IR组比较,LIR组T_(1,2)时肝动脉血流速度增快,T_1～6时肝静脉血流速度增快,T_(1,4～6)时血浆ALT和AST的活性降低(P＜0.05).与IR组比较,LIR组肝细胞线粒体及窦周间隙面微绒毛的肿胀程度减轻,肝血寞窦壁覆盖完整.结论 控制性低CVP可减轻兔肝缺血再灌注损伤,其机制可能与增加再灌注期间肝血流量,减轻肝细胞及肝血窦损伤,从而改善肝灌注有关.     

The effects of ischemia and ischemia-reperfusion on bacterial translocation, lipid peroxidation, and gut histology: studies on hemorrhagic shock in pigs.

The bacterial translocation hypothesis was tested in two studies (acute and subacute) in a porcine model of hemorrhagic shock. Male pigs (30-40 kg each) under general anesthesia had their femoral vein, femoral artery, and portal vein catheterized. After stabilization (1 hour) they were bled (40% of blood volume) over 30 minutes, then maintained in the hypotensive state (MAP = 30-40 mm Hg) for 2 hours, following which, according to randomization, they entered the control group or were resuscitated with whole blood (WB group) or with lactated Ringer's solution (LR group). In the acute study, the mesenteric efferent lymphatic was also cannulated, the control group was not resuscitated, and the animals remained under general anesthesia to the end of the experiment (8.5 hours), when gut tissue was obtained for histologic study and measurement of lipid peroxidation. In the subacute study, the control group was not bled, the animals were awakened at 6.5 hours, and the portal vein catheter remained in situ until 48 hours. In both studies, samples of portal blood were obtained for culture at regular intervals and on completion, samples from mesenteric lymph nodes (MLNs) for culture were taken in the acute study, and in the subacute study samples from MLNs, spleen, and liver were obtained. In the acute study significant bacterial translocation to the MLNs and portal blood did not occur among the controls (n = 3), the LR group (n = 5), and the WB group (n = 6). Significant evidence of lipid peroxidation was found in both the LR and WB groups. Histologic assessment showed no difference among the groups.(ABSTRACT TRUNCATED AT 250 WORDS)     

Hemodynamic profile and tissular oxygenation in orthotopic liver transplantation: Influence of hepatic artery or portal vein revascularization of the graft.

We performed a prospective, randomized study of adult patients undergoing orthotopic liver transplantation, comparing hemodynamic and tissular oxygenation during reperfusion of the graft. In 30 patients, revascularization was started through the hepatic artery (i.e., initial arterial revascularization) and 10 minutes later the portal vein was unclamped; in 30 others, revascularization was started through the portal vein (i.e., initial portal revascularization) and 10 minutes later the hepatic artery was unclamped. The primary endpoints of the study were mean systemic arterial pressure and the gastric-end-tidal carbon dioxide partial pressure (PCO(2)) difference. The secondary endpoints were other hemodynamic and metabolic data. The pattern of the hemodynamic parameters and tissue oxygenation values during the dissection and anhepatic stages were similar in both groups At the first unclamping, initial portal revascularization produced higher values of mean pulmonary pressure (25 +/- 7 mm of Hg vs. 17 +/- 4 mm of Hg; P < 0.05) and wedge and central venous pressures. At the second unclamping, initial portal revascularization produced higher values of cardiac output and mean arterial pressure (87 +/- 15 mm of Hg vs. 79 +/- 15 mm of Hg; P < 0.05) and pulmonary blood pressure. Postreperfusion syndrome was present in 13 patients (42.5%) in the arterial group and in 11 patients (36%) in the portal group. During revascularization, the values of gastric and arterial pH decreased in both groups and recovered at the end of the procedure, but were more accentuated in the initial arterial revascularization group. In conclusion, we found that initial arterial revascularization of the graft increases pulmonary pressure less markedly, so it may be indicated for those patients with poor pulmonary and cardiac reserve. Nevertheless, for the remaining patients, initial portal revascularization offers more favorable hemodynamic and metabolic behavior, less inotropic drug use, and earlier normalization of lactate and pH values.     

Portal vein pressure and graft oxygen consumption monitoring during liver transplantation

Abnormal splanchnic circulation (ASC) is often detected too late, when hepatic circulation is already irreversibly compromised. If we could detect surgical or metabolic problems early after graft reperfusion, we might be able to correct them immediately before the damage becomes irreversible. The aim of this study was to determine if ASC can be predicted early after liver transplantation (LT) using portal vein pressure measurements and graft oxygen consumption monitoring. PATIENTS AND METHODS: Twenty-patients (13 men, 7 women of mean age 46 years) undergoing LT with the piggyback technique for hepatitis C virus (HCV)/hepatitis B virus (HBV)-related cirrhosis were retrospectively divided in two groups. Group A (16 patients), in which LT was successful, and group B (4 patients) in which LT was unsuccessful because of primary nonfunction (2 patients), infrahepatic portal vein thrombosis (1 patient), or hepatic vein kinking (1 patient). We then compared the portal blood pressure values and the prehepatic and posthepatic oxygen content difference (p-pDO(2)) before portal clamping; at the end of anhepatic phase; 5, 15, and 25 minutes after portal vein (PV) reperfusion; and 5, 20, 40, and 100 minutes after hepatic artery anastomosis. RESULTS: Early after graft reperfusion; portal pressure decreased to levels lower than that at baseline in group A, but remained high until the end of surgery in group B. At the end of surgery, p-pDO(2) increased more among group B than group A. CONCLUSION: ASC, specifically an increased PV resistance, can be predicted early after LT by portal vein pressure measurements and graft oxygen consumption monitoring.