How to estimate the size of the donor liver

Abstract  Of readily available methods to estimate the donor liver size, measurement of the body circumference at the xiphoid level (xiphoid measure) appeared to be the most accurate in the present prospective study of 60 donors and 57 recipients ( r = 0.64, P = 0.0001). The estimated liver volume could be calculated using the equation: bloodless liver volume (1) = 1.44 x xiphoid measure (m). The difference between donor and recipient xiphoid measures was significantly higher in slowly recovering patients than in those recovering uneventfully (7 ± 7 cm vs. - 5 ± 8 cm, P < 0.001). The bloodless donor liver volume measured by water displacement averaged 1249 k 230 ml and had increased by 3 weeks post-transplant by 64 ± 28 % as determined using computed tomography. The volume of the liver graft seemed to adapt to the recipient as it correlated positively with body weight ( r = 0.64, P < 0.01) and negatively with the age of the recipient (r = - 0.42, P < 0.01). The liver graft volume seemed to increase less markedly in patients with a slow recovery than in those with an uncomplicated recovery (37 %±15 % vs. 68 %± 24 %, P< 0.001). We conclude that a simple measurement of the body circumference at the xiphoid level can be used to estimate the donor liver volume. A gross mismatch of this parameter between the donor and the recipient seems to increase the risk of graft dysfunction. We also found that the change in the liver graft volume is influenced by the recipient's age and body weight.     

Haemodynamic monitoring and liver function evaluation by pulsion cold system Z-201 (PCS) during orthotopic liver transplantation

Pulsion cold system (PCS, COLD) is a haemodynamic monitoring system that allows measurement of cardiac output (CO), partial blood volumes, lung water, and liver function. The aim of the study was to evaluate this monitoring system during human orthotopic liver transplantation (OLT) for the following: (a) to determine agreement between CO measurements via pulmonary artery thermodilution (CO TDpa), and aortic transpulmonary thermodilution (CO TDa); (b) to compare the preload dates obtained with the COLD with central venous pressure (CVP) and pulmonary capillary wedge (PCWP); and (c) to assess the use of the plasma disappearance rate (PDR) of indocyanine green (ICG) as a measure of graft function. Fifteen consecutive patients undergoing OLT were studied. Each patient received a pulmonary artery catheter and a 5F aortic catheter with an integrated thermistor. The thermistor of the aortic catheter were connected to one computer system (COLD-Z201, Pulsion Medical Systems, Munich, Germany). Haemodynamic data were registered an all the phases of OLT. PDR was measured during surgery in 12 patients. Correlations between PDR and the other markers of graft function (transaminases, protrombine time, and bile production) were sought. The correlation coefficient between CO TDa (COLD) and CO TDpa was r = 0.766 (p < 0.001), and an additional analysis according to Bland-Altman was also performed. There was a better correlation between the cardiac index (determined by two monitoring systems) and the volume measurements than the correlation observed with pressure preload parameters. The best correlations were found between the cardiac index in the femoral artery and intrathoracic blood volume index (ITBVI) and pulmonary blood volume index (PBVI) (r = 0.79 and r = 0.72, respectively; p < 0.01). PDR measured in the group patients with bad early graft function were lower (13.6 +/- 2.7) than those in the group with a good graft function (21.6 +/- 9) (p < 0.05). The degree of discrepancy between femoral and pulmonary thermodilution cardiac output measures is very wide during OLT so as to make the techniques using the COLD machine clinically useless. On the other hand, the volumes measured by COLD, specially ITBVI and PBVI, are more useful to asses the pre-load than pressure measurements. In OLT, the PDR measured within the first few hours after liver reperfusion may become a useful tool for early diagnosis of primary graft dysfunction (PDF).     

Parameters associated with changes in liver volume in patients undergoing portal vein embolization

BACKGROUND: To identify predictors of changes in hepatic volumes after portal vein embolization (PVE) before hepatectomy, we examined the relationship between clinicopathological parameters and changes in volume of embolized and nonembolized liver and regeneration of remnant liver after hepatectomy. MATERIALS AND METHODS: The subjects were 25 patients who underwent laparotomy. PVE was performed through transileocolic vein (n = 15) and percutaneous transhepatic puncture (n = 10). RESULTS: Significant atrophy and hypertrophy of the embolized and nonembolized liver were observed after PVE, respectively, and further increase of remnant liver volume was observed after hepatectomy. Background liver disease did not seem to influence the results. Alkaline phosphatase (ALP) level correlated negatively with atrophy of embolized lobe (r = -0.433). Platelet count correlated positively with hypertrophy of nonembolized lobe (r = 0.412, P < 0.05) and percent increase between lobes and (r = 0.515, P < 0.05). Seven (32%) patients developed postoperative complications, such as long-term ascites or cholestasis. Changes in embolized liver and percent increase between lobes in patients with postoperative cholestasis (-94 +/- 97 cm(3) and 9.6 +/- 5.1% gain) were significantly lower than those in patients without cholestasis (17 +/- 54 cm(3) and 6.6 +/- 1.3% gain, P < 0.05). CONCLUSION: ALP and platelet counts might be able to predict PVE effect and were related to postoperative course. Identification of more specific predictors is desirable.     

A simple and accurate formula to estimate left hepatic graft volume in living-donor adult liver transplantation

BACKGROUND: In the field of living-donor adult liver transplantation, a small-for-size graft often occurs, particularly when using left-lobe grafts. This is because of the limited volumes associated with left-lobe grafts. The accurate preoperative evaluation of graft volumes is crucial to avoid this complication. The aim of this study is to clarify the usefulness of a new formula to estimate the left-lobe graft volume. METHOD: In 61 left-lobe grafts, a new formula was created with stepwise regression analysis using the following variables: height, weight, the thoracic and abdominal distance from anterior to posterior side (A-P), and distance from left to right side (L-R) of the initial 20 donors. With another 41 donors, the difference between the actual and estimated graft volume using the formula and two- and three-dimensional computed tomography was prospectively evaluated. RESULTS: On the basis of the results of the stepwise regression analysis, a new formula was created as follows: graft volume (ml) = 313.4 + 7.7 x weight (kg)-12.6 x thoracic L-R (cm). The difference between the actual and estimated graft volumes using the formula was significantly better (10.8 +/- 9.5%) than that of the volumetry using two-dimensional computed tomography (16.3 +/- 10.1%) (P < 0.05). CONCLUSIONS: In conclusion, the new formula can estimate the actual graft volume more accurately than conventional volumetry with two-dimensional computed tomography. The formula is useful to estimate the volume of left-lobe graft in living-donor adult liver transplantation.     

Donor outcome and liver regeneration after right-lobe graft donation

Sufficiently detailed information on donor safety and the liver regeneration process following right-lobe living donation has been unavailable, so we evaluated donor outcome and liver regeneration in 13 males and 14 females (39.0 +/- 14.8 years old) who provided 27 right-lobe grafts without the middle hepatic vein. Preoperative total liver volume (TLV), graft volume, and postoperative changes in residual liver volume (RLV) were measured by volumetric computed tomography. Histological steatosis of the liver was graded as none, minimal (< or =10%), and mild (11-30%). The median follow-up period was 337 days. Estimated graft volume and actual graft weight were linearly correlated (Y = 177.85 + 0.795X, R(2) = 0.812, P < 0.0001). Graft-to-recipient weight ratio was 1.08 +/- 0.19%. Four donors had postoperative complications, but they resolved in response to conservative treatment. Postoperative hospital stay was 15.2 +/- 5.5 days. Peak liver enzyme values were significantly higher in donors with mild steatosis (n = 7) than without steatosis (n = 16) (P < 0.05). Donor RLV was 40.8 +/- 6.6% of original TLV at surgery, 79.8 +/- 12.0% by 6 months, and 97.2 +/- 10.8% by 12 months. At 3 months the liver of the older donors (> or =50 years) had grown significantly more slowly than in younger donors (70.4 +/- 9.2% vs. 79.3 +/- 9.6%, P = 0.0391). In conclusion, right hepatectomy without middle hepatic vein of living donors is a safe procedure with acceptable morbidity, and the residual liver regenerated to its preoperative size by 1 year. However, meticulous care should be taken in donors with liver steatosis and aged donors.     

肝硬变门静脉高压症患者肝脏体积测定及其临床意义

目的通过测定肝脏体积术前判断肝硬变门静脉高压症患者手术耐受能力和术后远期效果。方法使用双螺旋ＣＴ应用三维表面遮盖显示法检测了２５例肝硬变门静脉高压症患者的肝脏体积,并与对照组３０例比较。结果对照组肝脏大小与身高呈正线性相关,ｒ＝０４２（Ｐ＜００５）,平均肝体积为（１０７０６８±２２７５２）ｃｍ３,与肝硬变组（７９７０２±１３５１１）ｃｍ３比较差异有显著性意义（Ｐ＜００５）。肝硬变门静脉高压症患者肝体积与Ｃｈｉｌｄ分级有关,ＣｈｉｌｄＣ级患者肝脏明显小于ＣｈｉｌｄＢ级患者（６７２４±９１１）ｃｍ３,（８８８２±９２６）ｃｍ３,Ｐ＜００５。结论肝体积小者分流术后易发生脑病,但肝脏大小、门静脉血流量和门体自然分流率没有密切的相关关系。     

Total and segmental liver volume variations: implications for liver surgery

BACKGROUND: Liver remnant volumes after major hepatic resection and graft volumes for liver transplantation correlate with surgical outcome. The relative contributions of the hepatic segments to total liver volume (TLV) are not well established. METHODS: TLV and hepatic segment volumes were measured with computed tomography (CT) in 102 patients without liver disease who underwent CT for conditions unrelated to the liver or biliary tree. RESULTS: TLV ranged from 911 to 2729 cm(3). On average, the right liver (segments V, VI, VII, and VIII) contributed approximately two thirds of TLV (997+/-279 cm(3)), and the left liver (segments II, III and IV) contributed approximately one third of TLV (493+/-127 cm(3)). Bisegment II+III (left lateral section) contributed about half the volume of the left liver (242+/-79 cm(3)), or 16% of TLV. Liver volumes varied significantly between patients--the right liver varied from 49% to 82% of TLV, the left liver, 17% to 49% of TLV, and bisegment II+III (left lateral section) 5% to 27% of TLV. Bisegment II+III contributed less than 20% of TLV in more than 75% of patients and the left liver contributed 25% or less of TLV in more than 10% of patients. DISCUSSION: There is clinically significant interpatient variation in hepatic volumes. Therefore, in the absence of appreciable hypertrophy, we recommend routine measurement of the future liver remnant before extended right hepatectomy (right trisectionectomy) and in selected patients before right hepatectomy if a small left liver is anticipated.     

Effects of the liver volume and donor steatosis on errors in the estimated standard liver volume

An accurate assessment of donor and recipient liver volumes is essential in living donor liver transplantation. Many liver donors are affected by mild to moderate steatosis, and steatotic livers are known to have larger volumes. This study analyzes errors in liver volume estimation by commonly used formulas and the effects of donor steatosis on these errors. Three hundred twenty-five Asian donors who underwent right lobe donor hepatectomy were the subjects of this study. The percentage differences between the liver volumes from computed tomography (CT) and the liver volumes estimated with each formula (ie, the error percentages) were calculated. Five popular formulas were tested. The degrees of steatosis were categorized as follows: no steatosis [n = 178 (54.8%)], ≤ 10% steatosis [n = 128 (39.4%)], and >10% to 20% steatosis [n = 19 (5.8%)]. The median errors ranged from 0.6% (7 mL) to 24.6% (360 mL). The lowest was seen with the locally derived formula. All the formulas showed a significant association between the error percentage and the CT liver volume (P < 0.001). Overestimation was seen with smaller liver volumes, whereas underestimation was seen with larger volumes. The locally derived formula was most accurate when the liver volume was 1001 to 1250 mL. A multivariate analysis showed that the estimation error was dependent on the liver volume (P = 0.001) and the anthropometric measurement that was used in the calculation (P < 0.001) rather than steatosis (P ≥ 0.07). In conclusion, all the formulas have a similar pattern of error that is possibly related to the anthropometric measurement. Clinicians should be aware of this pattern of error and the liver volume with which their formula is most accurate.     

Donor Kidney Volume and Outcomes Following Live Donor Kidney Transplantation

Pre-donation kidney volume and function may be crucial factors in determining graft outcomes in kidney transplant recipients. We measured living donor kidney volumes by 3D helical computed tomography scanning and glomerular filtration rate (GFR) by (125)I-iothalamate clearances in 119 donors, and correlated these values with graft function and incidence of acute rejection at 2 years post-transplantation. Kidney volume strongly correlated with GFR (Pearson r= 0.71, p < 0.001). Body size and male gender were independent correlates of larger kidney volumes, and body size and age were predictors of kidney function. The effects of transplanted kidney volume on graft outcome were studied in 104 donor-recipient pairs. A transplanted kidney volume greater than 120 cc/1.73 m(2) was independently associated with better estimated GFR at 2 years post-transplant when compared to recipients of lower transplanted kidney volumes (64 +/- 19 vs. 48 +/- 14 mL/min/1.73 m(2), p < 0.001). Moreover, recipients of lower volumes had a higher incidence of acute cellular rejection (16% vs. 3.7%, p = 0.046). In conclusion, kidney volume strongly correlates with function in living kidney donors and is an independent determinant of post-transplant graft outcome. The findings suggest that (1) transplantation of larger kidneys confers an outcome advantage and (2) larger kidneys should be preferred when selecting from otherwise similar living donors.     

Oral tacrolimus bioavailability is increased after right split liver transplantation

OBJECTIVE: Tacrolimus (Tac) is mainly metabolized in the liver. The aim of this trial was to analyze Tac bioavailability after partial liver transplantation. PATIENTS AND METHODS: A total of 33 patients after right split liver grafting (n=8 living related, LRLT; n=8 cadaver split, CS) or full-size liver transplantation (n=17, FS) were included in this trial. All of them received Tac perorally with an initial dose of 2x5 mg/d. Dose adjustment was performed according to the Tac trough level (T0) with an initial target T0 levels of 12 to 15 ng/mL. RESULTS: The time to reach target T0 levels tended to be lower (P=.05) in the split liver groups (LRLT: 2.8+/-1.6 days; CS: 2.1+/-0.9 days; FS: 4.5+/-3.2 days). In addition, mean Tac dose to maintain the target T0 level was significantly decreased (P=.01) in the split liver cohorts (LRLT: 5.8+/-1.1 mg/d; CS: 5.5+/-2.5 mg/d; FS: 9.8+/-3.9 mg/d). Only graft weight/standard liver volume ratio (r=.566, P=.02) and graft weight/body weight ratio (r=.709, P=.002) showed significant correlations with Tac maintenance doses in the split liver group. CONCLUSIONS: Peroral Tac bioavailability was significantly higher after partial liver transplantation using the right hepatic lobe compared with full-size transplants. The volume of the split liver graft highly correlated with Tac maintenance therapy and should be used to calculate the most appropriate initial posttransplantation Tac dose.     

多层螺旋CT半自动法测量肝体积在成人活体肝移植中的应用

目的 探讨多层螺旋CT(MSCT)半自动法测量右半供肝体积的准确性,及该方法在活体肝移植(LDLT)中的应用价值.方法 对56例供者术前行MSCT四期增强扫描,然后分别根据MSCT图像手动绘图(简称:手动法)计算右半供肝体积(V手)和应用IQQA(R)-liver肝脏诊断辅助分析系统进行半自动化绘图(简称:半自动法)计算右半供肝体积(V半),将两种方法计算的右半供肝体积与术中经水置换法实测的右半供肝体积(V术)进行相关分析和Bland-Altman检查,得出其线性回归方程.结果 V半、V手和V术分别为(818.60±161.43)、(880.16±169.92)和(669.84±141.37)cm3;半自动法和手动法测量供肝体积与术中实测肝体积均显著相关(r值分别为0.778和0.746,P＜0.05),其线性回归方程分别为V术=V半×0.681+112.26,V术=V手×0.620+123.81.半自动法测量肝体积与术中实测肝体积的差值为148.76cm3,95%可信区间为121.57～175.95 cm3,吻合限为-354.135～56.62 cm3,手动法测量肝体积与术中实测肝体积的差值为210.33 cm3,95%可信区间为180.09～240.56 cm3,吻合限为-438.66～18.01cm3.结论 半自动法测量LDLT右半供肝体积比目前最常用的手动法更为准确.

Abstract：

Objective To evaluate the accuracy of multi-detector spiral CT (MSCT) semiautomated volumetric measurement of right lobes and its value in living donor liver transplantation (LDLT). Methods Fifty-six donors underwent four phases MSCT. Pre-operative liver volumes of two measurements [IQQA(R)-liver semi-automated (Vs) and manual volume (Vm) measurements] in portal vein phase were compared with intra-operative measurement (Vio) by means of water displacement. Results Correlation analysis and Bland-Altman tests were used for statistical analysis.Results Pre-operative measurements of grafts resulted in a mean Vs, Vm, Vio of (818. 60 ± 161.43)cm3 , (880. 16 ± 169. 92) cm3 and (669. 84 ± 141.37) cm3 respectively. All corresponding pre-and intra-operative data were correlated significantly with each other. There was a good correlation between Vs and Vio(r= 0. 778, P＜0. 05), so did Vm and Vio(r= 0. 746, P＜0. 05). The equations of linear regression were Vio = Vs × 0. 681 + 112. 26, and Vio = Vm × 0. 620 + 123. 81 respectively. Exact 95 % CIs and the extent of concordance were 121.57-175. 95 cm3, -354. 135-56. 62 cm3 for semiautomated measurements, and 180. 09-240. 56 cm3 , - 438. 66-18. 01 cm3 for manual measurements,respectively. Conclusion Semi-automated method for the volumetric measurements of the right liver lobes in LDLT is more accurate than the manual method.     

Standardized measurement of the future liver remnant prior to extended liver resection: methodology and clinical associations

BACKGROUND: There is no agreement regarding the preoperative measurement of liver volumes and the minimal safe size of the liver remnant after extended hepatectomy. METHODS: In 20 patients with hepatobiliary malignancy and no underlying chronic liver disease, volumetric measurements of the liver remnant (segments 2 and 3 +/- 1) were obtained before extended right lobectomy (right trisegmentectomy). The ratios of future liver remnant to total liver volume were calculated by using a formula based on body surface area. In 12 patients, response to preoperative right trisectoral portal vein embolization was evaluated. In 15 patients who underwent the planned resection, preoperative volumes were correlated with biochemical and clinical outcome parameters. RESULTS: The future liver remnants increased after portal vein embolization (26% versus 36%, P < .01). Smaller size liver remnants were associated with an increase in postoperative liver function tests (P < .05) and longer lengths of hospital stay (P < .02). Preliminary data indicates an increase in major complications for liver volumes < or = 25% (P = .02). CONCLUSIONS: A simple method of measurement provides an assessment of the liver remnant before resection. It is useful in evaluating response to portal vein embolization and in predicating the outcome before extended liver resections.     

Mechanical versus manual ventilation via a face mask during the induction of anesthesia: a prospective, randomized, crossover study

One approach to make ventilation safer in an unprotected airway has been to limit tidal volumes; another one might be to limit peak airway pressure, although it is unknown whether adequate tidal volumes can be delivered. Accordingly, the purpose of this study was to evaluate the quality of automatic pressure-controlled ventilation versus manual circle system face-mask ventilation regarding ventilatory variables in an unprotected airway. We studied 41 adults (ASA status I-II) in a prospective, randomized, crossover design with both devices during the induction of anesthesia. Respiratory variables were measured with a pulmonary monitor (CP-100). Pressure-controlled mask ventilation versus circle system ventilation resulted in lower (mean +/- SD) peak airway pressures (10.6 +/- 1.5 cm H(2)O versus 14.4 +/- 2.4 cm H(2)O; P < 0.001), delta airway pressures (8.5 +/- 1.5 cm H(2)O versus 11.9 +/- 2.3 cm H(2)O; P < 0.001), expiratory tidal volume (650 +/- 100 mL versus 680 +/- 100 mL; P = 0.001), minute ventilation (10.4 +/- 1.8 L/min versus 11.6 +/- 1.8 L/min; P < 0.001), and peak inspiratory flow rates (0.81 +/- 0.06 L/s versus 1.06 +/- 0.26 L/s; P < 0.001) but higher inspiratory time fraction (48% +/- 0.8% versus 33% +/- 7.7%; P < 0.001) and end-tidal carbon dioxide (34 +/- 3 mm Hg versus 33 +/- 4 mm Hg; not significant). We conclude that in this model of apneic patients with an unprotected airway, pressure-controlled ventilation resulted in reduced inspiratory peak flow rates and peak airway pressures when compared with circle system ventilation, thus providing an additional patient safety effect during mask ventilation. IMPLICATIONS: In this model of apneic patients with an unprotected airway, pressure-controlled ventilation resulted in reduced inspiratory peak flow rates and lower peak airway pressures when compared with circle system ventilation, thus providing an additional patient safety effect during face-mask ventilation.     

Right ventricular end-diastolic volume index as a predictor of preload status in patients with low right ventricular ejection fraction during orthotopic liver transplantation

OBJECTIVE: The objective of this study was to compare the accuracy of 2 variables: pulmonary artery occlusion pressure (PAOP) and right ventricular end diastolic volume index (RVEDVI) as predictors of the hemodynamic response to fluid challenge as well as definition of the overall correlation between RVEDVI and change in PAOP, right ventricular ejection fraction (RVEF), central venous pressure (CVP), and determination of the right ventricular function during orthotopic liver transplantation. MATERIALS AND METHODS: A modified pulmonary artery catheter equipped with a fast response thermistor was used to determine RVEF, allowing calculation of RVEF end-diastolic volume index (EDVI, as the ratio of stroke index [SI] to EF). The above-mentioned hemodynamic measures were taken in 4 phases: T0, after induction of anesthesia; T1, during anhepatic phase; T2, 30' after graft reperfusion; and T3, at the end of surgery. RESULTS: The variation of the REF value was 36 +/- 4% and 39 +/- 6%. Linear regression analysis showed a significant correlation between RVEDVI (range, 133 +/- 33-145 +/- 40 mL/m(2)) and stroke volume index (SVI) in each phase (r(2) = 0.49, P < .01; r(2) = 0.57, P < .01) at T0 and T1, respectively, and at T2 and T3 (r(2) = 0.51, P < .01; r(2) = 0.44, P < .01), respectively. No significant variations in the linear regression analysis between RVEDVI, PAOP, CVP, and RVEF were observed. No relationship was found between PAOP (range, 10 +/- 2-6 +/- 2 mm Hg) and SVI. CONCLUSION: RVEDVI may be the best clinical estimate of right ventricular preload. In fact, minor changes of RVEF have been recorded, confirming that RV function was not altered during uncomplicated orthotopic liver transplantation.     

New aspects of breast volume measurement using 3-dimensional surface imaging

Precise and objective calculation of breast volume is helpful to evaluate the aesthetic result of breast surgery, but traditional methods are unsatisfactory. Three-dimensional (3D) scanning of the body surface allows reproducible and objective assessment of the complex breast region but requires further investigation before clinical application. The main goal of this study was to investigate the precision and accuracy of breast volume measurement using 3D body scanning. Five independent observers standardized the 3D scanning method using 2 dummy models (n = 200) and examined its applicability with 6 test subjects and 10 clinical patients (n = 2220). Breast volume measurements obtained with the 3D-scanner technology were compared with reference measurements obtained from test subjects through nuclear magnetic resonance imaging. The mean deviation of the breast volume measurements of 1 test subject by all observers, expressed as percentage of volume, was 2.86 +/- 0.98, significantly higher than the deviation for the dummy models, 1.65 +/- 0.42 (P < 0.001). With respect to all clinical patients, the mean measurement precision obtained preoperatively was less precise than that obtained postoperatively (3.31 +/- 1.02 versus 1.66 +/- 0.49, respectively). Interobserver differences in measurement precision were not statistically significant. The mean breast volumes obtained by nuclear magnetic resonance imaging (441.42 +/- 137.05 mL) and 3D scanning (452.51 +/- 141.88 mL) significantly correlated (r = 0.995, P < 0.001). Breast volume measurement with 3D surface imaging represents a sufficiently precise and accurate method to guarantee objective and exact recording.     

Normal hepatic hemodynamics during early postoperative period in recipients with adult live donor liver transplantation

To recognize "normal" hepatic hemodynamics after live donor liver transplantation (LDLT), we analyzed Doppler parameters on recipients with a right liver graft and donors after extended left hepatectomy. Theoretically these values should be the same. From April 2000 to October 2004, 20 LDLTs were performed using a right liver graft. The 10 recipients without postoperative complications and their donors were included in this study. Portal venous velocity (PVV; cm/s), hepatic arterial peak systolic velocity (cm/s), and hepatic venous peak velocity (HVPV; cm/s) were measured during the first 2 weeks. In donors PVV and HVPV after LDLT were significantly higher after than before left hepatectomy: 19.2 +/- 4.2 vs. 31.5 +/- 13.0 cm/s (P = .013) and 23.0 +/- 7.2 vs. 41.8 +/- 10.3 cm/s respectively (P = .010). However, there were mild degrees of increased PVV and HVPV. In recipients, a markedly increased PVV (106.3 +/- 45.2 cm/s on day 1) was significantly higher than that in donors on each postoperative day. The hepatic arterial resistive index in recipients was also significantly higher than that in donors on each postoperative day, for example, 0.72 +/- 0.11 vs 0.62 +/- 0.04 on day 1 (P = .0326). In conclusion, we have shown "abnormal" hepatic hemodynamics in even those recipients without complications during the early postoperative period after LDLT.     

Alveolar Recruitment in Pulmonary and Extrapulmonary Acute Respiratory Distress Syndrome: Comparison Using Pressure-Volume Curve or Static Compliance

Background: Alveolar recruitment in response to positive end-expiratory pressure (PEEP) may differ between pulmonary and extrapulmonary acute respiratory distress syndrome (ARDS), and alveolar recruitment values may differ when measured by pressure-volume curve compared with static compliance.

Methods: The authors compared PEEP-induced alveolar recruitment in 71 consecutive patients identified in a database. Patients were classified as having pulmonary, extrapulmonary, or mixed/uncertain ARDS. Pressure-volume curves with and without PEEP were available for all patients, and pressure-volume curves with two PEEP levels were available for 44 patients. Static compliance was calculated as tidal volume divided by pressure change for tidal volumes of 400 and 700 ml. Recruited volume was measured at an elastic pressure of 15 cm H2O.

Results: Volume recruited by PEEP (10 +/- 3 cm H2O) was 223 +/- 111 ml in the pulmonary ARDS group (29 patients), 206 +/- 164 ml in the extrapulmonary group (16 patients), and 242 +/- 176 ml in the mixed/uncertain group (26 patients) (P = 0.75). At high PEEP (14 +/- 2 cmH2O, 44 patients), recruited volumes were also similar (P = 0.60). With static compliance, recruitment was markedly underestimated and was dependent on tidal volume (226 +/- 148 ml using pressure-volume curve, 95 +/- 185 ml for a tidal volume of 400 ml, and 23 +/- 169 ml for 700 ml; P < 0.001).     

The impact of arterialization on hepatic microcirculation and leukocyte accumulation after liver transplantation in the rat.

This study investigated the influence of hepatic arterialization on early graft function, microcirculation, and leukocyte-endothelial interaction after syngeneic orthotopic liver transplantation in Lewis rats. Livers were preserved for 17 hr in UW solution and transplanted without rearterialization (group 1: n = 10) or with immediate arterial reconstruction (group 2: n = 10). Graft function was analyzed by bile flow; microcirculation was assessed by laser Doppler flowmetry (LDF) and intravital microscopy (IVM). In addition, flow behavior of leukocytes was quantified by IVM after i.v. injection of the WBC marker acridine orange. Improved graft function in group 2 was indicated by increased bile production during the observation period of 90 min after reperfusion (7.18 +/- 0.62 vs. 3.63 +/- 0.63 ml/100 g liver [mean +/- SEM] P < 0.001). In arterialized grafts LDF values increased by 22.9 +/- 3.8% upon reperfusion of the hepatic artery (P = 0.004). Arterialization increased WBC velocities in sinusoids (group 1: 0.29 +/- 0.02 mm/sec, group 2: 0.34 +/- 0.01 mm/sec, P < 0.001) and postsinusoidal venules (0.43 +/- 0.05 vs. 0.64 +/- 0.05 mm/sec, P = 0.029). In addition, the number of nonperfused midzonal sinusoids decreased significantly (8.5 +/- 2.2% of all sinusoids analyzed vs. 4.2 +/- 1.3%, P = 0.048). However, the marked sinusoidal and venular WBC adherence observed 1 hr after reperfusion was not altered by arterialization. It is concluded that arterial reconstruction in rat liver transplantation improves microvascular perfusion and graft function but this improvement does not relate to WBC accumulation within the graft. We propose that studies on hepatic preservation and postischemic reperfusion in the rat should be based on the physiological model of dual vascularization.     

Validity of preoperative volumetric analysis of congestion volume in living donor liver transplantation using three-dimensional computed tomography.

Reconstruction of middle hepatic vein (MHV) tributaries is controversial in right-lobe living donor liver transplantation (LDLT). This study aimed to evaluate the appropriateness of reconstructing MHV tributaries by volumetry using 3-dimensional computed tomography (3D-CT). Between November 2003 and January 2005, 42 donor livers (right-lobe graft, n = 25; left-lobe graft, n = 17) were evaluated using this software. The total congestion volume (CV) associated with the MHV tributaries and the inferior right hepatic vein (IRHV), and graft volume (GV) were calculated. In recipients with right-lobe grafts, CV/(right liver volume [RLV]) and (GV - CV)/(standard liver volume [SLV]) were compared between 2 groups: with reconstruction (n = 16) and without reconstruction (n = 9). To evaluate the influence of CV on the remnant right lobe in donors, total bilirubin was compared between 2 groups: high CV (CV > 20%, n = 13) or low CV (CV < or = 20%, n = 4). The mean CV/RLV ratio was 32.3 +/- 17.1% (V5, 15.2 +/- 9.9%; V8, 9.2 +/- 4.1%; and IRHV, 8.5 +/- 11.4%) and the maximum ratio was as high as 80.8%. The mean (GV - CV)/SLV ratio before reconstruction in patients with or without reconstruction resulted in 33.5 +/- 12.8% and 55.4 +/- 12.9%, respectively (P < 0.01). In donors, total bilirubin was significantly high in the high CV group on postoperative day 1 compared with the low CV group (P < 0.05). In conclusion, calculation of CV using 3D-CT software proved to be very useful. We concluded that this evaluation should be an integral part of procedure planning, especially for right-lobe LDLT.     

Remnant liver regeneration and spleen volume changes after living liver donation: influence of the middle hepatic vein

BACKGROUND AND OBJECTIVES: Graft harvest with or without the middle hepatic vein (MHV) affects venous return and function of the remaining liver. The aims of this study are to compare the remnant liver volume and spleen changes in the donors of different types of graft harvest and to evaluate the influence of resection with or without the MHV on the remnant liver volume regeneration, spleen volume change and serum total bilirubin. PATIENTS AND METHODS: A total of 165 donors were grouped according to the type of graft harvest: 88 donors underwent left lateral segmentectomy (LLS), 10 donors underwent extend LLS or left lobectomy (LL), and 67 donors underwent right lobectomy (RL). Groups LLS and LL were later combined as group LH (left hepatectomy, n = 98). There were 68 men and 97 women. The mean age was 32.9 +/- 8.1 yr. The total liver volume (LV) and spleen volume (S1) before graft harvest, graft weight (GW), regenerated liver volume (LV(6m)) and spleen volume (S2) six months post-donation were calculated. RESULTS: There were no significant differences in the regenerated liver volume six months postoperation (LV(6m)) and recovery ratio (LV(6m)/LV x 100%) among the different groups, albeit significant smaller LV(6m) in both groups compared with the initial liver volume was noted. Postoperative spleen volume (S2), average spleen ratio (S2/S1) and spleen change ratio were significantly larger and higher in group RL than in group LH. A significant increase in spleen volume was noted in both groups six months after graft harvest. A significantly higher TB in group RL (4.1 +/- 1.7 mg/dL, range: 1.4-8.5 mg/dL) was noted compared with that of group LH (1.6 +/- 1.0 mg/dL, range: 0.7-6.2 mg/dL). CONCLUSION: There was a significant increase in the regenerated remnant liver and splenic volumes six months postoperation in all types of hepatectomy following living donor hepatectomy, and there was no difference in the mean TB levels among donors whether the MHV was included or not in the graft.