Novel Personalized Score Predicts Risk for Postoperative Biliary Leak in Liver Surgery—a Retrospective Database Analysis

Riediger, Carina, Hoffmann, Raphael, Löck, Steffen, Giehl-Brown, Esther, Dennler, Sandra, Kahlert, Christoph, Weitz, Jürgen

21 May 2024

Background The number of liver resections is constantly rising over the last decades. Despite the reduction of overall mortality and morbidity in liver surgery, biliary leakage is still a relevant postoperative complication that can lead to a fatal postoperative course. Aim of this analysis is the identification of specific risk factors for postoperative biliary complications after liver resections and the development of a predictive biliary leakage risk score. Methods A single-center, retrospective analysis of 844 liver resections performed in the Department of Visceral, Thoracic and Vascular Surgery, Technische Universität Dresden, between 1/2013 and 12/2019 is conducted to identify risk factors for postoperative biliary leakage and a risk score for biliary leakage after hepatectomy is established based on multivariate regression. The score has been validated by an independent validation cohort consisting of 142 patients. Results Overall morbidity is 43.1% with 36% surgical complications and an overall mortality of 4.3%. Biliary leakage occurred in 15.8% of patients. A predictive score for postoperative biliary leakage based on age, major resection, pretreatment with FOLFOX/cetuximab and operating time is created. Patients are stratified to low (< 15%) and high (> 15%) risk with a sensitivity of 67.4% and a specificity of 70.7% in development cohort and a specificity of 68.2% and sensitivity of 75.8% in validation cohort. Conclusions The presented score is robust and has been validated in an independent patient cohort. Depending on the calculated risk, prevention or early treatment can be initiated to avoid bile leakage and to improve postoperative course.

info:eu-repo/classification/ddc/610

ddc:610

How Does a Single Cell Know When the Liver Has Reached Its Correct Size?

Hohmann, Nadine, Weiwei, Wei, Dahmen, Uta, Dirsch, Olaf, Deutsch, Andreas, Voss-Böhme, Anja

14 July 2014

The liver is a multi-functional organ that regulates major physiological processes and that possesses a remarkable regeneration capacity. After loss of functional liver mass the liver grows back to its original, individual size through hepatocyte proliferation and apoptosis. How does a single hepatocyte ‘know’ when the organ has grown to its final size? This work considers the initial growth phase of liver regeneration after partial hepatectomy in which the mass is restored. There are strong and valid arguments that the trigger of proliferation after partial hepatectomy is mediated through the portal blood flow. It remains unclear, if either or both the concentration of metabolites in the blood or the shear stress are crucial to hepatocyte proliferation and liver size control. A cell-based mathematical model is developed that helps discriminate the effects of these two potential triggers. Analysis of the mathematical model shows that a metabolic load and a hemodynamical hypothesis imply different feedback mechanisms at the cellular scale. The predictions of the developed mathematical model are compared to experimental data in rats. The assumption that hepatocytes are able to buffer the metabolic load leads to a robustness against short-term fluctuations of the trigger which can not be achieved with a purely hemodynamical trigger.

Leber

Hepatozyten

Zellwachstum

Proliferation

Apoptose

partielle Hepatektomie

TU Dresden

Publikationsfonds

liver

hepatocyte proliferation

apoptosis

partial hepatectomy

Technical University Dresden

Publication funds

ddc:500

ddc:610

rvk:TA 1000

rvk:XA 10000

Serial Analysis of Gene Expression of Rat Liver Regeneration by Oval Hepatic Stem Cells / Serielle Analyse der Genexpression während der Rattenleberregeneration durch Ovalstammzellen

Cimica, Velasco

05 November 2004

No description available.

570 Biowissenschaften, Biologie

Mathematics and Computer Science

SAGE

Serial Analysis of Gene Expression

Leber

Rattenleberregeneration

Ovalzellen

partiellen Hepatektomie

SAGE

Serial Analysis of Gene Expression

liver

liver regeneration

oval cells

partial hepatectomy.

W

W

Regulation of gene expression of hepcidin and of other proteins of the iron metabolism in the liver and in the extrahepatic tissues: in vivo and in vitro studies in different rat models. / Die Regelung der Genexpression von Hepcidin und anderen Proteinen des Eisen-stoffwechsels in der Leber und in extrahepatischen Geweben: in vivo und in vitro Studien in verschiedenen Rattenmodellen.

Sheikh, Nadeem

31 October 2006

No description available.

500 Naturwissenschaften allgemein

Mathematics and Computer Science

Hepcidin

Eisenregulation

Akut-phase-antwort

partieller Hepatektomie

Tetrachlorkohlenstoff (CCl4)

Anemia.

Hepcidin

Iron regulation

Acute-phase-response

Partial hepatectomy

Carbon tetra chloride

Anemia.

42 Biologie

42.13 Molekularbiologie

WF

How Does a Single Cell Know When the Liver Has Reached Its Correct Size?

Hohmann, Nadine, Weiwei, Wei, Dahmen, Uta, Dirsch, Olaf, Deutsch, Andreas, Voss-Böhme, Anja

14 July 2014

The liver is a multi-functional organ that regulates major physiological processes and that possesses a remarkable regeneration capacity. After loss of functional liver mass the liver grows back to its original, individual size through hepatocyte proliferation and apoptosis. How does a single hepatocyte ‘know’ when the organ has grown to its final size? This work considers the initial growth phase of liver regeneration after partial hepatectomy in which the mass is restored. There are strong and valid arguments that the trigger of proliferation after partial hepatectomy is mediated through the portal blood flow. It remains unclear, if either or both the concentration of metabolites in the blood or the shear stress are crucial to hepatocyte proliferation and liver size control. A cell-based mathematical model is developed that helps discriminate the effects of these two potential triggers. Analysis of the mathematical model shows that a metabolic load and a hemodynamical hypothesis imply different feedback mechanisms at the cellular scale. The predictions of the developed mathematical model are compared to experimental data in rats. The assumption that hepatocytes are able to buffer the metabolic load leads to a robustness against short-term fluctuations of the trigger which can not be achieved with a purely hemodynamical trigger.

info:eu-repo/classification/ddc/500

ddc:500

info:eu-repo/classification/ddc/610

ddc:610