Normothermic human kidney preservation drives iron accumulation and ferroptosis

Marlon J. A. de Haan; Marleen E. Jacobs; Annemarie M. A. de Graaf; Roan H. van Scheppingen; Rico J. E. Derks; Dorottya K. de Vries; Jesper Kers; Ian P. J. Alwayn; Cees van Kooten; Elena Sánchez-lópez; Martin Giera; Marten A. Engelse; Ton J. Rabelink

doi:10.1038/s41467-025-61058-9

Normothermic human kidney preservation drives iron accumulation and ferroptosis

Marlon J. A. de Haan
, Marleen E. Jacobs
, Annemarie M. A. de Graaf
, Roan H. van Scheppingen
, Rico J. E. Derks
, Dorottya K. de Vries
, Jesper Kers
, Ian P. J. Alwayn
, Cees van Kooten
, Elena Sánchez-lópez
, Martin Giera
, Marten A. Engelse
, Ton J. Rabelink^*

^*Corresponding author for this work

Leiden University
University of Amsterdam

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

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Abstract

Ex vivo normothermic machine perfusion has been proposed to protect deceased donor kidneys. However, its benefits remain ambiguous. We postulate that the use of red blood cells (RBCs) and associated secondary hemolysis may in fact cause renal injury, offsetting potential advantages. During 48-hour normothermic perfusion of seven human donor kidneys, we observed progressive hemolysis, leading to iron accumulation in perfusate and tissue. Untargeted lipidomic profiling revealed significant increases in oxidized phospholipid species in perfused kidneys, pointing towards iron-dependent cell death known as ferroptosis. Next, in twelve additional perfusions, we assessed strategies to mitigate hemolysis-driven injury. Dialysis-based free hemoglobin removal reduced lipid peroxidation, but a ferroptosis gene signature persisted. In contrast, cell-free perfusion at subnormothermia negated iron accumulation, the ferroptosis gene signature, phospholipid peroxidation, and acute kidney injury. Our findings highlight the pathological role of hemolysis and iron on the kidney, urging restraint in the clinical application of RBC-based kidney perfusion.

Original language	English
Article number	5420
Journal	Nat. Commun.
Volume	16
Issue number	1
DOIs	https://doi.org/10.1038/s41467-025-61058-9
Publication status	Published - 1 Dec 2025

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de Haan, M. J. A., Jacobs, M. E., de Graaf, A. M. A., van Scheppingen, R. H., Derks, R. J. E., de Vries, D. K., Kers, J., Alwayn, I. P. J., van Kooten, C., Sánchez-lópez, E., Giera, M., Engelse, M. A., & Rabelink, T. J. (2025). Normothermic human kidney preservation drives iron accumulation and ferroptosis. Nat. Commun., 16(1), Article 5420. https://doi.org/10.1038/s41467-025-61058-9

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title = "Normothermic human kidney preservation drives iron accumulation and ferroptosis",

abstract = "Ex vivo normothermic machine perfusion has been proposed to protect deceased donor kidneys. However, its benefits remain ambiguous. We postulate that the use of red blood cells (RBCs) and associated secondary hemolysis may in fact cause renal injury, offsetting potential advantages. During 48-hour normothermic perfusion of seven human donor kidneys, we observed progressive hemolysis, leading to iron accumulation in perfusate and tissue. Untargeted lipidomic profiling revealed significant increases in oxidized phospholipid species in perfused kidneys, pointing towards iron-dependent cell death known as ferroptosis. Next, in twelve additional perfusions, we assessed strategies to mitigate hemolysis-driven injury. Dialysis-based free hemoglobin removal reduced lipid peroxidation, but a ferroptosis gene signature persisted. In contrast, cell-free perfusion at subnormothermia negated iron accumulation, the ferroptosis gene signature, phospholipid peroxidation, and acute kidney injury. Our findings highlight the pathological role of hemolysis and iron on the kidney, urging restraint in the clinical application of RBC-based kidney perfusion.",

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AU - de Haan, Marlon J. A.

AU - Jacobs, Marleen E.

AU - de Graaf, Annemarie M. A.

AU - van Scheppingen, Roan H.

AU - Derks, Rico J. E.

AU - de Vries, Dorottya K.

AU - Kers, Jesper

AU - Alwayn, Ian P. J.

AU - van Kooten, Cees

AU - Sánchez-lópez, Elena

AU - Giera, Martin

AU - Engelse, Marten A.

AU - Rabelink, Ton J.

PY - 2025/12/1

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N2 - Ex vivo normothermic machine perfusion has been proposed to protect deceased donor kidneys. However, its benefits remain ambiguous. We postulate that the use of red blood cells (RBCs) and associated secondary hemolysis may in fact cause renal injury, offsetting potential advantages. During 48-hour normothermic perfusion of seven human donor kidneys, we observed progressive hemolysis, leading to iron accumulation in perfusate and tissue. Untargeted lipidomic profiling revealed significant increases in oxidized phospholipid species in perfused kidneys, pointing towards iron-dependent cell death known as ferroptosis. Next, in twelve additional perfusions, we assessed strategies to mitigate hemolysis-driven injury. Dialysis-based free hemoglobin removal reduced lipid peroxidation, but a ferroptosis gene signature persisted. In contrast, cell-free perfusion at subnormothermia negated iron accumulation, the ferroptosis gene signature, phospholipid peroxidation, and acute kidney injury. Our findings highlight the pathological role of hemolysis and iron on the kidney, urging restraint in the clinical application of RBC-based kidney perfusion.

AB - Ex vivo normothermic machine perfusion has been proposed to protect deceased donor kidneys. However, its benefits remain ambiguous. We postulate that the use of red blood cells (RBCs) and associated secondary hemolysis may in fact cause renal injury, offsetting potential advantages. During 48-hour normothermic perfusion of seven human donor kidneys, we observed progressive hemolysis, leading to iron accumulation in perfusate and tissue. Untargeted lipidomic profiling revealed significant increases in oxidized phospholipid species in perfused kidneys, pointing towards iron-dependent cell death known as ferroptosis. Next, in twelve additional perfusions, we assessed strategies to mitigate hemolysis-driven injury. Dialysis-based free hemoglobin removal reduced lipid peroxidation, but a ferroptosis gene signature persisted. In contrast, cell-free perfusion at subnormothermia negated iron accumulation, the ferroptosis gene signature, phospholipid peroxidation, and acute kidney injury. Our findings highlight the pathological role of hemolysis and iron on the kidney, urging restraint in the clinical application of RBC-based kidney perfusion.

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Normothermic human kidney preservation drives iron accumulation and ferroptosis

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