Clinical Trial Details
— Status: Active, not recruiting
Administrative data
| NCT number |
NCT04208919 |
| Other study ID # |
STUDY20010215 |
| Secondary ID |
|
| Status |
Active, not recruiting |
| Phase |
Phase 1/Phase 2
|
| First received |
|
| Last updated |
|
| Start date |
December 18, 2019 |
| Est. completion date |
June 2026 |
Study information
| Verified date |
September 2023 |
| Source |
University of Pittsburgh |
| Contact |
n/a |
| Is FDA regulated |
No |
| Health authority |
|
| Study type |
Interventional
|
Clinical Trial Summary
Phase I/II, single center, prospective, open-label, non-controlled, non-randomized,
interventional, cohort study in which low risk living donor liver transplant (LDLT)
recipients who are between 1 and 3 years after transplantation and meet specific criteria (no
positive crossmatch, no clinically treated rejection within 2 years preceding enrollment,
permissive liver function tests (LFTs) within 30 days preceding enrollment, no prior liver
biopsy showing significant fibrosis or ductopenia*) will be enrolled and will undergo a
protocol liver biopsy unless they have had a permissive liver biopsy** within 90 days of
anticipated immunosuppression weaning. Those patients with permissive liver biopsy** will
then receive a single infusion of donor-derived DCreg and will remain on their current
standard of care (SOC) immunosuppression. One week after DCreg infusion, immunosuppression
weaning will be initiated. Recipients will be slowly weaned off immunosuppression.
Successfully weaned participants who remain rejection-free will undergo 3 years of follow-up
after the last dose of immunosuppression. They will undergo a liver biopsy at 1 yr and 3 yrs
after immunosuppression withdrawal. Participants who are removed from the study protocol at
any time will return to standard of care but will continue to be followed by the study team
and will undergo a liver biopsy at the end of the study.
* Permissive LFTs are defined as ALT, AST and total bilirubin < 2.5 times the upper limit of
normal.
**A permissive biopsy is based on 2016 Comprehensive Update of the Banff Working Group on
Liver Allograft Pathology (the criteria detailed in Table 8, Demetris et al. 2016).
Description:
Long-term immunosuppression after solid organ transplantation is associated with
life-threatening side effects that include infection, malignancy, diabetes and increased risk
of cardiovascular disease. In addition, use of calcineurin inhibitors (CNI) causes
nephrotoxicity and a significant rate of chronic renal insufficiency (CRI) at 5 years after
orthotopic liver transplantation (OLT). Many patients with CRI after OLT require renal
replacement therapy (dialysis or renal transplantation) and are at increased mortality risk.
A large study based on the Scientific Registry of Transplant Recipients (SRTR) and the
Centers for Medicare and Medicaid Services (CMMS) ESRD Program database showed an ESRD
incidence of 15 per 1000 patient years, implying that in 20 years, ~30% of patients require
renal replacement therapy. Patients demonstrating progressive loss in functional nephron mass
are also at risk of progressing to chronic kidney disease (CKD), which is known to confer > 4
fold increase in mortality risk. Immunosuppression (CNI) withdrawal, particularly before
significant renal injury has set in, may preserve renal function and prevent morbidity and
mortality associated with CKD/CRI and renal replacement therapy. Immunosuppression withdrawal
may also mitigate the increased risk of infection, malignancy, diabetes, and cardiovascular
disease directly associated with conventional immunosuppressive medications.
Our goal is to develop a novel, safe cell therapy approach that, when used in liver
transplantation would facilitate the safe complete withdrawal of immunosuppression without
jeopardizing allograft function or histology. Recent evidence suggests that, by exploiting
inherent mechanisms of immune regulation, it may be possible to achieve this goal. Rare,
naturally-occurring regulatory immune cells, either innate or adaptive, critically regulate
immunity, promote antigen (Ag)-specific T cell hyporesponsiveness and prevent adverse immune
reactions in the healthy steady-state. In addition to Treg, being evaluated for cell-based
therapy in organ transplantation, a compelling rationale has emerged for clinical testing of
regulatory DC modified ex vivo to promote their regulatory properties (DCreg). Thus, in
rodents, infusion of donor-derived DCreg before transplantation, including their combination
with conventional IS, promotes indefinite (> 100 day) organ allograft survival. There is also
evidence that infusion of donor- or recipient- derived DCreg post-transplant can promote
indefinite allograft survival. More importantly and uniquely, using a robust,
clinically-relevant, non-human primate (NHP) model with minimal IS, we have shown that
infusion of DCreg, one week before transplantation, significantly and safely prolongs renal
allograft survival, with no evidence of host sensitization. Equally significant, is our
demonstration that prolongation of allograft survival is associated with selective
attenuation of donor-reactive Tmem responses, an important barrier to improving long-term
graft survival and achieving operational tolerance.
Development of safe and effective approaches that improve long-term graft survival while
reducing the burden of conventional immunosuppressive drugs, will have a significant impact
on the health, as well as costs, of thousands of organ transplant recipients. Extensive
pre-clinical studies conducted by Dr. Thomson (IND Sponsor) and others in rodents and
humanized mouse models are persuasive regarding the potential of regulatory immune cell
therapy to enhance long-term allograft survival and in many instances, promote donor-specific
tolerance. The case for evaluation of DCreg generated ex vivo is particularly compelling.
First, DC are inherently tolerogenic, uniquely well-equipped, professional Ag-presenting
cells (APC) that potently regulate innate and adaptive immunity. Second, in many animal
studies, DCreg adoptively transferred to allograft recipients before or after transplant
induce Ag-specific tolerance and promote indefinite graft survival. Moreover, this
therapeutic effect does not appear to depend on the in vivo persistence of intact DCreg.
Independence of efficacy and underlying regulatory mechanisms on persistence of intact donor
DCreg may be a distinct advantage over other cell therapy approaches, where costly repeated
infusion of large numbers of cells and their sustained viability/stability/replication may be
required to achieve a therapeutic effect. Third, an important attribute of DCreg is their
ability to regulate preformed Tmem responses, that, due to molecular mimicry, cross-react
with HLA Ags [66], representing a major barrier to long-term graft survival in humans.
Fourth, in normal humans, adoptive transfer of monocyte-derived DCreg induces Ag-specific
inhibition of effector T cell function. Fifth, using minimal IS in a robust, NHP model, we
have reported that a single infusion of 3.5-10.106/kg donor-derived DCreg pre-transplant
safely prolongs renal allograft survival, without host sensitization. Importantly, this
effect is associated with attenuation of donor-specific, alloreactive Tmem responses.
The DCreg approach could be readily applied in the clinic since a single infusion of a
relatively small number of DCreg (3.5-10.106/kg) in NHP is sufficient to achieve a salutary
therapeutic effect. Therefore, neither expensive expansion of the cell product over several
weeks (compared with Treg), nor repeated infusion appears necessary. It is also likely that
DCreg will have broader clinical application to encompass recipients of organ transplants
from deceased donors as rodent studies have shown that delay of DCreg infusion to 7 or 14 d
after transplant is still effective in prolonging graft survival and promoting tolerance,
providing ample time to prepare DCreg from deceased donors.
The possibility that DCreg administration could enable early withdrawal of immunosuppression
(< 3 years) after liver transplantation carries the potentially great advantage of sparing
patients the cardiovascular, infectious, neoplastic, and renal side effects of long-term
immunosuppression, particularly with CNI. Liver transplantation provides a particular
opportunity to achieve this goal because liver grafts are more tolerated by the recipient's
immune system than other solid organ grafts, with immunosuppression withdrawal possible in
~20% of patients overall (in the absence of any experimental, immunomodulatory therapy)
compared to <5% in renal transplant recipients. Increasing the proportion of liver transplant
recipients who can be withdrawn from immunosuppression through the administration of DCreg
around the time of transplantation could reap significant health benefits to this patient
population.
