grant

Targeting Donor Regulatory Dendritic Cells During Normothermic Ex Vivo Liver Perfusion to Overcome Rejection after Liver Transplant

Organization UNIVERSITY OF WISCONSIN-MADISONLocation MADISON, UNITED STATESPosted 7 Jun 2021Deadline 31 May 2026
NIHUS FederalResearch GrantFY2025AcuteAffectAnimalsAnti-InflammatoriesAnti-Inflammatory AgentsAnti-inflammatoryB7-H1BN RatsBeliefBiologyBiometricsBiometryBiostatisticsBone-Derived Transforming Growth FactorCD274CSIFCSIF-10CancersCell BodyCellsCellular biologyClinicalCommon Rat StrainsCommunicationCompetenceCytokine Synthesis Inhibitory FactorDangerousnessDataDedicationsDendritic CellsDevelopmentDrugsEducational ActivitiesEnvironmentEthicsFlow CytofluorometriesFlow CytofluorometryFlow CytometryFlow MicrofluorimetryFlow MicrofluorometryFoundationsFrequenciesGoalsGraft RejectionGraft SurvivalGrafting ProcedureHepatic TransplantationIL-10IL10IL10AImmuneImmune reactionImmune responseImmune systemImmunesImmunochemical ImmunologicImmunologicImmunologicalImmunologicallyImmunologicsImmunomodulationIn VitroInbred BN RatsInbred Brown Norway RatsInfectionInterleukin 10 PrecursorInterleukin-10InterventionInvestigatorsKnowledgeLaboratoriesLaboratory ResearchLifeLiverLiver GraftingLiver TransplantMalignant NeoplasmsMalignant TumorMeasuresMediatingMedicationMentorshipMethodsMilk Growth FactorModelingModificationOperative ProceduresOperative Surgical ProceduresOrganOrgan DonorOrgan TransplantationOrgan TransplantsOutcomePD-L1PD-L1 antibodyPDL-1PatientsPerfusionPharmaceutical PreparationsPhenotypePhysiologicPhysiologicalPlatelet Transforming Growth FactorProductionProgram DevelopmentProgrammed Cell Death 1 Ligand 1Programmed Death Ligand 1PropertyProteinsRatRats MammalsRattusReactionResearchResearch DesignResearch PersonnelResearchersRiskRoleScientistSolidStudy TypeSurgeonSurgicalSurgical InterventionsSurgical ProcedureTGF BTGF-betaTGF-βTGFbetaTGFβTechniquesTechnologyTestingTimeTrainingTransforming Growth Factor betaTransforming Growth Factor-Beta Family GeneTranslatingTransplant RecipientsTransplant RejectionTransplant immunologyTransplantationTransplantation ImmunologyTransplantation RejectionTransplantation SurgeryUniversitiesVeiled CellsWisconsinaPD-L1aPD-L1 antibodiesanti programmed cell death ligand 1anti programmed cell death protein ligand 1anti-PD-(L)1anti-PD-L1anti-PD-L1 antibodiesanti-PD-L1 monoclonal antibodiesanti-PDL-1anti-PDL1anti-PDL1 antibodiesantiPD-L1careercareer developmentcell biologyclinical practiceclinical relevanceclinically relevantcytokinecytokine based immunotherapycytokine based therapycytokine immunotherapycytokine therapycytokine treatmentdeceased donordeceased organ donorsdevelopmentaldrug/agentend stage liver diseaseend stage liver failureethicalexperienceextracellular vesiclesflow cytophotometryhepatic body systemhepatic organ systemhost responseimmune check pointimmune checkpointimmune microenvironmentimmune modulationimmune regulationimmune system responseimmunecheckpointimmunologic reactivity controlimmunomodulatoryimmunoreactionimmunoregulationimmunoregulatoryimmunoresponseimmunosuppressive microenvironmentimmunosuppressive tumor microenvironmentimprovedin vivoinnovateinnovationinnovativeliver functionliver transplantationmalignancyneoplasm/cancernovelorgan allograftorgan graftorgan rejectionorgan transplant rejectionorgan xenograftposthumous donorsposthumous organ donorprofessorprogrammed cell death ligand 1programmed cell death protein ligand 1protein death-ligand 1public health relevanceresponseside effectskillssocial rolestudy designsurgerytransplanttransplant modeltransplant patienttumor immune microenvironmenttumor-immune system interactionsαPD-L1αPD-L1 antibodiesαPDL1
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Full Description

ABSTRACT
This proposal presents a five-year research career development program focused on targeting donor liver-
resident cells with regulatory properties to decrease rejection after transplantation. I am an Assistant Professor
of Surgery at the University of Wisconsin-Madison, with previous research and clinical experience in transplant
immunology and transplant surgery involving normothermic ex vivo machine perfusion (NEVLP), whereby an
organ is housed under physiologic conditions. The present project will advance the field of transplant
immunology by using NEVLP technology to modify the immune cells within the liver prior to transplantation. I
have assembled an outstanding mentorship team of investigators with expertise in transplant immunology,
dendritic cell biology, and extracellular vesicle biology. The proposed training will guide and enhance my
development in core competencies, including transplant immunology, communication, biostatistics, and ethical
research design that will enable me to transition to research independence as a surgeon-scientist dedicated to
reducing organ rejection in the field of transplant surgery.
Liver transplantation is the only treatment option for patients with end-stage liver disease; however,
rejection of the transplant can decrease liver and patient survival. In addition, patients still require lifelong use
of anti-rejection medications that suppress the immune system. Modification of the donor liver, and the immune
cells within it, has the potential to promote acceptance of the liver and minimize the need for anti-rejection
drugs. Advances in an innovative technique called normothermic ex vivo liver perfusion (NEVLP) offer a unique
opportunity to benefit significantly the 25% of liver transplant recipients that develop acute rejection, as well as
many more transplant recipients who would benefit from using fewer anti-rejection drugs. Recent studies have
demonstrated the importance of regulatory dendritic cells (DCregs) for prolonging transplant survival. My
central hypothesis is that expansion of the number of liver-resident DCregs during NEVLP will promote a
regulatory environment for the organ after transplant. Using a rat model of NEVLP and liver transplantation that
my research group has optimized, I expect NEVLP to expand DCregs potently, leading to an increase in
immune checkpoint molecule expression and production of anti-inflammatory extracellular vesicles and
cytokines that can reduce immune-mediated rejection. This innovative approach of expanding graft-resident
DCregs to decrease rejection could be used in deceased donor liver transplantation as well as translated to
other types of solid organ transplants. To achieve these objectives, I propose the following scientific aims:
1) Determine the dominant regulatory function of liver-resident DCregs after NEVLP, and 2) Measure the
impact of expanded liver-resident DCregs generated by combination cytokine therapy during NEVLP on liver
graft rejection in vitro and in vivo.

Grant Number: 5K08AI155816-05
NIH Institute/Center: NIH
Principal Investigator: David Al-Adra

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