Clinical Trial Details
— Status: Active, not recruiting
Administrative data
| NCT number |
NCT05349591 |
| Other study ID # |
Pro00117578 |
| Secondary ID |
|
| Status |
Active, not recruiting |
| Phase |
Phase 1
|
| First received |
|
| Last updated |
|
| Start date |
August 15, 2022 |
| Est. completion date |
May 15, 2026 |
Study information
| Verified date |
May 2024 |
| Source |
University of Alberta |
| Contact |
n/a |
| Is FDA regulated |
No |
| Health authority |
|
| Study type |
Interventional
|
Clinical Trial Summary
The transplant of the insulin-producing cell into the liver (Islet transplant) has been
proven an effective and valuable treatment for type 1 diabetics patients with poor blood
sugar. However, Islet transplant is currently limited by the number of pancreas organ donors
and the need for lifelong medication requirements such as antirejection drugs. The
investigators have learned that Regulatory T cells (Tregs), a small subset of a cluster of
differentiation 4+ (CD4+) T cells, have emerged as the major contributor to self-tolerance by
preventing the initiation of unwanted immune activation and by suppressing ongoing immune
responses to limit bystander tissue destruction. It has been suggested that infusion of Tregs
before extensive graft damage may improve long-term graft outcomes. In this trial, we propose
to study Analogous cryopreserved PolyTregs (cePolyTregs). cePolyTregs is a product with the
same in vivo functionality to that of the non-cryopreserved PolyTregs.
Description:
Type-1 diabetes mellitus (T1DM) occurs due to a loss of insulin production caused by the
destruction of the insulin producing cells located in the human pancreas. Patients living
with T1DM experience substantial complications from uncontrolled blood sugar levels. Insulin
administration is a life-saving treatment but fails to replicate the dynamic and responsive
control provided by a person's own insulin producing cells. Insulin therapies can also
increase the risk of severe episodes of low glucose, which significantly impacts quality of
life in these patients. Additionally, these therapies fail to completely prevent long-term
complications from this devastating disease.
The transplant of the insulin producing cell into the liver (Islet transplant) has been
proven an effective and valuable treatment for those with poor blood sugar. However, Islet
transplant is currently limited by the number of pancreas organ donors and the need for
lifelong medication requirements such as antirejection drugs.
Tregs are a subset of CD4+ T cells that function to maintain immune system homeostasis and
preserve tolerance to self-antigens. The function of Tregs in maintaining immune tolerance
can be harnessed through Treg cell therapy for treating various immunological diseases. Tregs
have the ability to migrate to sites of inflammation and have over 30 different immune
regulatory mechanisms to respond to different inflammatory conditions. Treg effector function
appears to work by bystander suppression, regulating local inflammatory responses through a
combination of cell-cell contact and suppressive cytokine production. Finally, Tregs have
been shown to play a critical role in tissue repair. The discovery of the transcription
factor FOXP3 in 2003 represented a major advance in Treg characterization. FOXP3 is essential
for Treg cell lineage specification and directly contributes to Treg function. However, FOXP3
is an intracellular protein that cannot be used to isolate Tregs for therapeutic uses. Thus,
methods for the isolation of Tregs must rely on the use of cell surface markers. The
discovery of the inverse relationship between CD127 and FOXP3 expression led to the use of
the CD4+CD127lo/- CD25+ cell surface phenotype for high-yield selection of a highly pure
human Tregs population that is highly suppressive in vitro, thus providing the best source of
FOXP3+ Tregs for adoptive immunotherapy.
Cryoperserved PolyTregs (cePolyTregs) is a new cellular therapeutic for allogeneic or
autologous applications that have been studied so far for the treatment of acute respiratory
distress syndrome (ARDS) associated with SARS-CoV-2 infection. A previous analogous product,
PolyTregs, prepared using a similar methodology and only differed in final formulation, is
thought to perform similarly in vitro and in vivo. The clinical experience with cePolyTregs
is still limited; however, the analogous PolyTregs has been extensively used as an both
allogeneic and autologous product in various clinical conditions, including graft-versus host
disease (GvHD), Type 1 Diabetes, kidney transplant, systemic lupus erythematosus (SLE), and
pemphigus vulgaris (PV). These experiences with autologous PolyTregs provides valuable
insights to cePolyTregs.
We have used the analogous PolyTregs product in a clinical trial in subjects receiving islet
transplant (PolyTregs in Islet Transplant study). A total of 16 participants were screened
for eligibility for the study at the University of Alberta within the period of March 2018 to
March 2021. The participants were divided in two cohorts. Cohort 1 received islet transplant
using Alemtuzumab induction therapy with Etanercept and Anakinra anti-inflammatory therapy.
Cohort 2 received islet transplant using Anti-Thymocyte Globulin (ATG) induction therapy with
Etanercept and Anakinra anti-inflammatory therapy. The treatment groups of both cohorts
received PolyTregs infusion at 6 weeks and 2 weeks post islet transplantation for Cohort 1
and Cohort 2, respectively. All participants in both cohorts were maintained on low dose
tacrolimus (Tac) and sirolimus (SRL) immunosuppression and were followed for a year after
PolyTregs infusion to assess safety and preliminary efficacy of PolyTregs therapy. At the
time of this protocol, 3 participants have received PolyTregs infusions. All reported AEs
were mild to moderate in severity, resolved, and were determined to be unlikely or unrelated
to PolyTregs infusion. While feasible, this trial was limited by the logistics issues
surrounding PolyTregs manufacturing and the unpredictable nature of the timing of deceased
donor islet transplant.
Cryopreserved PolyTregs (cePolyTregs) To facilitate feasibility surrounding logistics of
PolyTregs manufacturing and the timing of islet transplant, cePolyTregs will be used.
cePolyTregs is cryopreserved after its formulation and thawed immediately prior to infusion.
cePolyTregs has a different formulation but the identity and characteristics are analogous to
PolyTregs before and after cryopreservation. cePolyTregs will be delivered to the infusion
site under controlled condition using a qualified shipper and will be kept cryopreserved
until just prior to infusion. cePolyTregs will be first thawed in a water bath maintained at
34ºC - 38 ºC and kept on ice before administration. The thawed cePolyTregs product will be
administered via a peripheral intravenous (IV) line primed with saline per established
standard operating procedures. The product will be administered by peripheral IV line via
manual syringe push in approximately 10 minutes to 30 minutes depending on the volume.
Following administration of the thawed cePolyTregs product, product bag, tubing and
peripheral IV line will be flushed with normal saline to ensure complete dose is infused.
Emergency medical equipment (i.e., emergency trolley) will be available during the infusion
in case the subject has an allergic response, severe hypotensive crisis, or any other
reaction to the infusion. Vital signs (temperature, respiration rate, pulse, and blood
pressure) will be taken before and after infusion, then every 15 minutes (+/- 3 minutes) for
at least one hour and until these signs are satisfactory and stable. The intravenous line
will be maintained after the infusion and the subject will be asked to remain in the clinical
research unit for 24 hours. Vital signs will be monitored every hour (+/- 3 minutes) for the
first four hours and every four hours (+/- 3 minutes) thereafter.
Based on existing pre-clinical and clinical findings, we hypothesize that cePolyTregs protect
from both auto and allorejection of transplanted islets, thereby improving insulin
independent durability and C-peptide function over time in adults with T1DM.
