Clinical Trial

Disease: Transfusion-dependent Beta- Thalassemia, TDT, (NCT06065189)

Disease info:

Beta-thalassemia is a group of blood disorders characterised by a reduction in the production of haemoglobin. Haemoglobin is the iron-containing protein in red blood cells that carries oxygen to cells throughout the body.

Haemoglobin is encoded by genes that encode the building blocks of the haemoglobin protein. Mutations in these genes can produce abnormal haemoglobins leading to a family of conditions termed "haemoglobinopathies". Abnormal haemoglobin appears in one of three basic circumstances:

  1. Structural defects in the haemoglobin molecule. Alterations in the gene for one of the two haemoglobin subunit chains, alpha (a) or beta (b), are called mutations. Often, mutations change a single amino acid building block in the subunit. Most commonly the change is innocuous, perturbing neither the structure nor function of the haemoglobin molecule. Occasionally, alteration of a single amino acid dramatically disturbs the behavior of the haemoglobin molecule and produces a disease state. Sickle haemoglobin exemplifies this phenomenon.
  2. Diminished production of one of the two subunits of the haemoglobin molecule. Mutations that produce this condition are termed "thalassemias." Equal numbers of haemoglobin alpha and beta chains are necessary for normal function. Haemoglobin chain imbalance damages and destroys red cells thereby producing anaemia. Although there is a dearth of the affected haemoglobin subunit, with most thalassemias the few subunits synthesised are structurally normal.
  3. Abnormal associations of otherwise normal subunits. A single subunit of the alpha chain (from the a-globin locus) and a single subunit from the b-globin locus combine to produce a normal haemoglobin dimer. With severe a-thalassemia, the b-globin subunits begin to associate into groups of four (tetramers) due to the paucity of potential a-chain partners. These tetramers of b-globin subunits are functionally inactive and do not transport oxygen. No comparable tetramers of alpha globin subunits form with severe beta-thalassemia. Alpha subunits are rapidly degraded in the absence of a partner from the beta-globin gene cluster (gamma, delta, beta globin subunits).

In individuals suffering from beta-thalassemia, low levels of haemoglobin lead to a lack of oxygen in many parts of the body. People with beta-thalassemia are at an increased risk of developing abnormal blood clots.

Beta thalassemia is classified into two types depending on symptom severity. Transfusion-dependent thalassemia, also known as thalassemia major, is the more severe, while thalassemia intermedia is less severe.

Frequency:
Annually, approximately 1 in 100,000 cases are diagnosed worldwide. Beta-thalassaemia occurs most frequently in people from Mediterranean countries, North Africa, the Middle East, India, China and South East Asia.
Official title:
Evaluation and Promotion of Key Technologies of Base-edited Autologous Hematopoietic Stem Cell Transplantation in Treating Patients With β-thalassemia Major
Who:

Contact 
Name: Xiaowen Zhai, M.D.

Phone: +86-021-64931126

Email: zhaixiaowendy@163.com

Contact Backup
Name: Zifeng Li, M.S.

Phone: +86-13920704768

Email: zfli18@fudan.edu.cn

Sponsor:

Children's Hospital of Fudan University

Locations:

Shanghai, China

Children's Hospital of Fudan University, Shanghai, Shanghai, China, 201102

Study start:
Dec. 31, 2024
Enrollment:
5 participants
Gene editing method:
CRISPR-mediated base editing (transformer Base Editor, tBE)
Type of edit:
Gene disruption
Gene:
HBG promoter
Delivery method:
- Ex-vivo
Indicator
IND Enabling Pre-clinical
Phase I Safety
Phase II Safety and Dosing
Phase III Safety and Efficacy

Status: Active recruiting

Description

The goal of this open label, single-arm clinical study is to learn about the safety and efficacy of base-edited autologous hematopoietic stem cell transplantation(CS-101) in treating patients with β-thalassemia major.

CS-101 is an autologous CD34+ cell suspension modified by ex vivo base editing technology, removing the inhibitory effect of BCL11A on the γ-globin coding gene, inducing the production of γ-globin chains, increasing the concentration of fetal hemoglobin (HbF) in the blood, compensating for the loss of adult hemoglobin (HbA) to treat transfusion-dependent type/ Major β - thalassemia. The therapy addresses two major challenges in the treatment of the disease: lack of matching donors and graft-versus-host responses commonly seen in allogeneic hematopoietic stem cell transplantation.

The study consists of the following five phases:

Screening phase: Sign informed consent, complete screening assessments, and confirm the eligibility for enrollment

Baseline: check the subject's baseline status

Mobilization, collection and manufacturing phase: mobilize, collect autologous CD34+ cells and manufacture, release and transport CS-101 product

Conditioning and treatment phase: including myeloablation and CS-101 product infusion

Follow-up phase: 180 days post-infusion

Last updated: Oct. 24, 2024
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