A reproducible extended ex-vivo normothermic machine liver perfusion protocol utilising improved nutrition and targeted vascular flows

George Clarke; Jingwen Mao; Angus Hann; Yiyu Fan; Amita Gupta; Anisa Nutu; Erwin Buckel Schaffner; Kayani Kayani; Nicholas Murphy; Mansoor N. Bangash; Anna L. Casey; Isla Wootton; Alexander J. Lawson; Bobby V. M. Dasari; M. Thamara P. R. Perera; Hynek Mergental; Simon C. Afford

doi:10.1038/s43856-024-00636-2

A reproducible extended ex-vivo normothermic machine liver perfusion protocol utilising improved nutrition and targeted vascular flows

George Clarke^*, Jingwen Mao, Angus Hann, Yiyu Fan, Amita Gupta, Anisa Nutu, Erwin Buckel Schaffner, Kayani Kayani, Nicholas Murphy, Mansoor N. Bangash, Anna L. Casey, Isla Wootton, Alexander J. Lawson, Bobby V. M. Dasari, M. Thamara P. R. Perera, Hynek Mergental, Simon C. Afford

^*Corresponding author for this work

Immunology and Immunotherapy

Research output: Contribution to journal › Article › peer-review

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Abstract

Background: Normothermic machine perfusion of donor livers has become standard practice in the field of transplantation, allowing the assessment of organs and safe extension of preservation times. Alongside its clinical uses, there has been expanding interest in extended normothermic machine perfusion (eNMP) of livers as a potential vehicle for medical research. Reproducible extended normothermic machine perfusion has remained elusive due to its increased complexity and monitoring requirements. We set out to develop a reproducible protocol for the extended normothermic machine perfusion of whole human livers.

Methods: Human livers declined for transplantation were perfused using a blood-based perfusate at 36 °C using the Liver Assist device (XVIVO, Sweden), with continuous veno-venous haemofiltration in-parallel. We developed the protocol in a stepwise fashion.

Results: Perfusion techniques utilised included: targeted physiological vascular flows, phosphate replacement (to prevent hypophosphataemia), N-acetylcysteine (to prevent methaemoglobin accumulation), and the utilisation of sodium lactate as both a nutritional source and real-time measure of hepatocyte function. All five human livers perfused with the developed protocol showed preserved function with a median perfusion time of 168 h (range 120–184 h), with preserved viability throughout.

Conclusions: Livers can be reproducibly perfused in excess of 120 (range 121–184) hours with evidence of preserved hepatocyte and cholangiocyte function.

Original language	English
Article number	214
Number of pages	12
Journal	Communications Medicine
Volume	4
Issue number	1
DOIs	https://doi.org/10.1038/s43856-024-00636-2
Publication status	Published - 24 Oct 2024

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Clarke, G., Mao, J., Hann, A., Fan, Y., Gupta, A., Nutu, A., Buckel Schaffner, E., Kayani, K., Murphy, N., Bangash, M. N., Casey, A. L., Wootton, I., Lawson, A. J., Dasari, B. V. M., Perera, M. T. P. R., Mergental, H., & Afford, S. C. (2024). A reproducible extended ex-vivo normothermic machine liver perfusion protocol utilising improved nutrition and targeted vascular flows. Communications Medicine, 4(1), Article 214. https://doi.org/10.1038/s43856-024-00636-2

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title = "A reproducible extended ex-vivo normothermic machine liver perfusion protocol utilising improved nutrition and targeted vascular flows",

abstract = "Background: Normothermic machine perfusion of donor livers has become standard practice in the field of transplantation, allowing the assessment of organs and safe extension of preservation times. Alongside its clinical uses, there has been expanding interest in extended normothermic machine perfusion (eNMP) of livers as a potential vehicle for medical research. Reproducible extended normothermic machine perfusion has remained elusive due to its increased complexity and monitoring requirements. We set out to develop a reproducible protocol for the extended normothermic machine perfusion of whole human livers. Methods: Human livers declined for transplantation were perfused using a blood-based perfusate at 36 °C using the Liver Assist device (XVIVO, Sweden), with continuous veno-venous haemofiltration in-parallel. We developed the protocol in a stepwise fashion. Results: Perfusion techniques utilised included: targeted physiological vascular flows, phosphate replacement (to prevent hypophosphataemia), N-acetylcysteine (to prevent methaemoglobin accumulation), and the utilisation of sodium lactate as both a nutritional source and real-time measure of hepatocyte function. All five human livers perfused with the developed protocol showed preserved function with a median perfusion time of 168 h (range 120–184 h), with preserved viability throughout. Conclusions: Livers can be reproducibly perfused in excess of 120 (range 121–184) hours with evidence of preserved hepatocyte and cholangiocyte function.",

author = "George Clarke and Jingwen Mao and Angus Hann and Yiyu Fan and Amita Gupta and Anisa Nutu and \{Buckel Schaffner\}, Erwin and Kayani Kayani and Nicholas Murphy and Bangash, \{Mansoor N.\} and Casey, \{Anna L.\} and Isla Wootton and Lawson, \{Alexander J.\} and Dasari, \{Bobby V. M.\} and Perera, \{M. Thamara P. R.\} and Hynek Mergental and Afford, \{Simon C.\}",

year = "2024",

month = oct,

day = "24",

doi = "10.1038/s43856-024-00636-2",

language = "English",

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journal = "Communications Medicine",

issn = "2730-664X",

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Clarke, G, Mao, J, Hann, A, Fan, Y, Gupta, A, Nutu, A, Buckel Schaffner, E, Kayani, K, Murphy, N, Bangash, MN, Casey, AL, Wootton, I, Lawson, AJ, Dasari, BVM, Perera, MTPR, Mergental, H & Afford, SC 2024, 'A reproducible extended ex-vivo normothermic machine liver perfusion protocol utilising improved nutrition and targeted vascular flows', Communications Medicine, vol. 4, no. 1, 214. https://doi.org/10.1038/s43856-024-00636-2

TY - JOUR

T1 - A reproducible extended ex-vivo normothermic machine liver perfusion protocol utilising improved nutrition and targeted vascular flows

AU - Clarke, George

AU - Mao, Jingwen

AU - Hann, Angus

AU - Fan, Yiyu

AU - Gupta, Amita

AU - Nutu, Anisa

AU - Buckel Schaffner, Erwin

AU - Kayani, Kayani

AU - Murphy, Nicholas

AU - Bangash, Mansoor N.

AU - Casey, Anna L.

AU - Wootton, Isla

AU - Lawson, Alexander J.

AU - Dasari, Bobby V. M.

AU - Perera, M. Thamara P. R.

AU - Mergental, Hynek

AU - Afford, Simon C.

PY - 2024/10/24

Y1 - 2024/10/24

N2 - Background: Normothermic machine perfusion of donor livers has become standard practice in the field of transplantation, allowing the assessment of organs and safe extension of preservation times. Alongside its clinical uses, there has been expanding interest in extended normothermic machine perfusion (eNMP) of livers as a potential vehicle for medical research. Reproducible extended normothermic machine perfusion has remained elusive due to its increased complexity and monitoring requirements. We set out to develop a reproducible protocol for the extended normothermic machine perfusion of whole human livers. Methods: Human livers declined for transplantation were perfused using a blood-based perfusate at 36 °C using the Liver Assist device (XVIVO, Sweden), with continuous veno-venous haemofiltration in-parallel. We developed the protocol in a stepwise fashion. Results: Perfusion techniques utilised included: targeted physiological vascular flows, phosphate replacement (to prevent hypophosphataemia), N-acetylcysteine (to prevent methaemoglobin accumulation), and the utilisation of sodium lactate as both a nutritional source and real-time measure of hepatocyte function. All five human livers perfused with the developed protocol showed preserved function with a median perfusion time of 168 h (range 120–184 h), with preserved viability throughout. Conclusions: Livers can be reproducibly perfused in excess of 120 (range 121–184) hours with evidence of preserved hepatocyte and cholangiocyte function.

AB - Background: Normothermic machine perfusion of donor livers has become standard practice in the field of transplantation, allowing the assessment of organs and safe extension of preservation times. Alongside its clinical uses, there has been expanding interest in extended normothermic machine perfusion (eNMP) of livers as a potential vehicle for medical research. Reproducible extended normothermic machine perfusion has remained elusive due to its increased complexity and monitoring requirements. We set out to develop a reproducible protocol for the extended normothermic machine perfusion of whole human livers. Methods: Human livers declined for transplantation were perfused using a blood-based perfusate at 36 °C using the Liver Assist device (XVIVO, Sweden), with continuous veno-venous haemofiltration in-parallel. We developed the protocol in a stepwise fashion. Results: Perfusion techniques utilised included: targeted physiological vascular flows, phosphate replacement (to prevent hypophosphataemia), N-acetylcysteine (to prevent methaemoglobin accumulation), and the utilisation of sodium lactate as both a nutritional source and real-time measure of hepatocyte function. All five human livers perfused with the developed protocol showed preserved function with a median perfusion time of 168 h (range 120–184 h), with preserved viability throughout. Conclusions: Livers can be reproducibly perfused in excess of 120 (range 121–184) hours with evidence of preserved hepatocyte and cholangiocyte function.

UR - https://www.scopus.com/pages/publications/85207631821

U2 - 10.1038/s43856-024-00636-2

DO - 10.1038/s43856-024-00636-2

M3 - Article

SN - 2730-664X

VL - 4

JO - Communications Medicine

JF - Communications Medicine

IS - 1

M1 - 214

ER -

A reproducible extended ex-vivo normothermic machine liver perfusion protocol utilising improved nutrition and targeted vascular flows

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