Petra J. Ottens scite author profile

K E Y P O I N T Sl Liver-associated tissue factor drives rapid intrahepatic coagulation after PHx.l Intrahepatic fibrin(ogen) deposition, but not thrombin-mediated platelet activation, promotes liver regeneration after PHx.Platelets play a pivotal role in stimulating liver regeneration after partial hepatectomy in rodents and humans. Liver regeneration in rodents is delayed when platelets are inhibited. However, the exact mechanisms whereby platelets accumulate and promote liver regeneration remain uncertain. Thrombin-dependent intrahepatic fibrin(ogen) deposition was recently reported after partial hepatectomy (PHx) in mice, but the role of fibrin(ogen) deposits in liver regeneration has not been investigated. We tested the hypothesis that fibrin(ogen) contributes to liver regeneration by promoting intrahepatic platelet accumulation and identified the trigger of rapid intrahepatic coagulation after PHx. PHx in wildtype mice triggered rapid intrahepatic coagulation, evidenced by intrahepatic fibrin(ogen) deposition. Intrahepatic fibrin(ogen) deposition was abolished in mice with liver-specific tissue factor deficiency, pinpointing the trigger of coagulation after PHx. Direct thrombin activation of platelets through protease-activated receptor-4 did not contribute to hepatocyte proliferation after PHx, indicating that thrombin contributes to liver regeneration primarily by driving intrahepatic fibrin(ogen) deposition. Fibrinogen depletion with ancrod reduced both intrahepatic platelet accumulation and hepatocyte proliferation after PHx, indicating that fibrin(ogen) contributes to liver regeneration after PHx by promoting intrahepatic platelet accumulation. Consistent with the protective function of fibrin(ogen) in mice, low postoperative plasma fibrinogen levels were associated with liver dysfunction and mortality in patients undergoing liver resection. Moreover, increased intrahepatic fibrin(ogen) deposition was evident in livers of patients after liver resection but was remarkably absent in patients displaying hepatic dysfunction postresection. The results suggest a novel mechanism whereby coagulation-dependent intrahepatic fibrin(ogen) deposition drives platelet accumulation and liver regeneration after PHx. (Blood. 2019;133(11):1245-1256

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Distinct Transcriptional Changes in Donor Kidneys upon Brain Death Induction in Rats: Insights in the Processes of Brain Death

Schuurs¹,

Gerbens

Hoeven³

et al. 2004

American Journal of Transplantation

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Brain death affects hormone regulation, inflammatory reactivity and hemodynamic stability. In transplant models, donor organs retrieved from brain dead (BD) rats suffer from increased rates of primary nonfunction and lower graft survival. To unravel the mechanisms behind brain death we have performed DNA microarray studies with kidney-derived RNA from normo-and hypotensive BD rats, corresponding with optimal and marginal BD donors, respectively. In kidneys from normotensive donors 63 genes were identified as either up-(55) or down-regulated (8), while 90 genes were differentially expressed (67 up-regulated) in hypotensive BD donor kidneys. Most genes were categorized in different functional groups: metabolism/transport (including the down-regulated water channel Aqp-2), inflammation/coagulation (containing the largest number (16) of up-regulated genes including selectins, Il-6, a -and b -fibrinogen), cell division/fibrosis (including KIM-1 involved in tubular regeneration) and defense/repair (with the cytoprotective genes HO-1, Hsp70, MnSOD2). Also, genes encoding transcription factors (including immediate early genes as Atf-3, Egr-1) and proteins involved in signal transduction (Pik3r1) were identified. Summarizing, the use of DNA microarrays has clarified parts of the process of brain death: Brain-death-induced effects ultimately lead, via activation of transcription factors and signal transduction cascades, to differential expression of different "effector" genes. Not only deleterious processes such as inflammation and fibrosis occur in brain dead donor kidneys but genes involved in protection and early repair processes are activated as well. These findings can be used to introduce specific cytoprotective interventions in the brain dead donor to better maintain or even increase organ viability.

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Normothermic machine perfusion reduces bile duct injury and improves biliary epithelial function in rat donor livers

et al. 2016

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Bile duct injury may occur during liver procurement and transplantation, especially in livers from donation after circulatory death (DCD) donors. Normothermic machine perfusion (NMP) has been shown to reduce hepatic injury compared to static cold storage (SCS). However, it is unknown whether NMP provides better preservation of bile ducts. The aim of this study was to determine the impact of NMP on bile duct preservation in both DCD and non-DCD livers. DCD and non-DCD livers obtained from Lewis rats were preserved for 3 hours using either SCS or NMP, followed by 2 hours ex vivo reperfusion. Biomarkers of bile duct injury (gamma-glutamyltransferase and lactate dehydrogenase in bile) were lower in NMP-preserved livers compared to SCS-preserved livers. Biliary bicarbonate concentration, reflecting biliary epithelial function, was 2-fold higher in NMP-preserved livers (P < 0.01). In parallel with this, the pH of the bile was significantly higher in NMP-preserved livers (7.63 6 0.02 and 7.74 6 0.05 for non-DCD and DCD livers, respectively) compared with SCS-preserved livers (7.46 6 0.02 and 7.49 6 0.04 for non-DCD and DCD livers, respectively). Scanning and transmission electron microscopy of donor extrahepatic bile ducts demonstrated significantly decreased injury of the biliary epithelium of NMP-preserved donor livers (including the loss of lateral interdigitations and mitochondrial injury). Differences between NMP and SCS were most prominent in DCD livers. Compared to conventional SCS, NMP provides superior preservation of bile duct epithelial cell function and morphology, especially in DCD donor livers. By reducing biliary injury, NMP could have an important impact on the utilization of DCD livers and outcome after transplantation.

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Petra J. Ottens

Time-Dependent Changes in Donor Brain Death Related Processes

Intrahepatic fibrin(ogen) deposition drives liver regeneration after partial hepatectomy in mice and humans

Distinct Transcriptional Changes in Donor Kidneys upon Brain Death Induction in Rats: Insights in the Processes of Brain Death

Normothermic machine perfusion reduces bile duct injury and improves biliary epithelial function in rat donor livers

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