Overview
Haploidentical Stem Cell Transplant for Patients With Sickle Cell Disease and Prior Stroke or Abnormal Transcranial Ultrasound
Status:
Completed
Completed
Trial end date:
2009-01-01
2009-01-01
Target enrollment:
0
0
Participant gender:
All
All
Summary
Sickle cell disease is a life-long blood condition that can cause damage to the brain and other organs of the body. Children may develop severe, debilitating clinical states, with stroke or abnormal blood flow to the brain. Treatment generally includes chronic blood transfusions which may cause iron overload, potentially leading to severe and sometimes fatal complications. Hematopoietic stem cell transplant using cells obtained from a sibling or an unrelated volunteer donor who is a perfect HLA "match" (same tissue type) for the recipient has shown to help, and possibly cure, sickle cell disease. Unfortunately, only about 10-20% of sickle cell patients have a HLA matched sibling donor, and the likelihood of locating an appropriate HLA matched unrelated donor through the various donor registries is limited. Stem cells from partially HLA matched family members (also called haploidentical transplant) is an option currently being explored for this patient population. This type of transplant has been used and found to be successful in some patients, mostly those with cancers of the blood. However, there can be significant complications with haploidentical transplant, primarily infection, failure of the graft to grow (graft failure), and a disorder called graft-versus-host disease. In addition, few patients with sickle cell disease have undergone this procedure. Therefore, the risks and benefits of haploidentical transplants for patients with sickle cell disorder are not as well established as those using an HLA identical sibling or unrelated donor. The primary objective of this study is to assess the safety of haploidentical stem cell transplantation for children and adolescents with severe sickle cell disease and stroke or abnormal transcranial Doppler ultrasound requiring chronic transfusion therapy. The treatment plan will be considered safe if there is not excessive toxicity. Toxicity for this protocol is defined as graft failure/graft rejection, severe acute GVHD, or regimen related death within 100 days after the last cellular product administered. Of note, the protocol was closed to accrual in September 2007 as we had met the stopping rules related to graft integrity (graft failure and graft rejection). Participants currently enrolled continue to be followed per protocol.Phase:
Phase 1Accepts Healthy Volunteers?
NoDetails
Lead Sponsor:
St. Jude Children's Research Hospital
Criteria
Inclusion Criteria:- Hemoglobin SS or S-Beta Thalassemia Sickle Cell Disease.
- Partially-matched family member with hemoglobin AA (normal) or hemoglobin AS (sickle
trait) phenotype.
- Stroke (persistent neurologic deficit lasting > 24 hours and present on MRI) or
abnormal transcranial Doppler (TCD) ultrasonography requiring chronic transfusion
therapy. A TCD is deemed abnormal when the velocity is greater than or equal to 200
cm/sec. Chronic transfusion therapy is defined as "packed red blood cell transfusions
administered approximately every 3-5 weeks to decrease the percentage of sickle
hemoglobin (Hemoglobin S) to prevent complications of sickle cell disease. This is
used most commonly to treat/prevent stroke, acute chest syndrome, and/or pain crises.
Exclusion criteria
- Karnofsky or Lansky score < 60%
- Acute hepatitis or evidence of moderate or severe portal fibrosis on biopsy. (Biopsy
will be obtained if patient on chronic transfusion therapy > 6 months or ferritin >
1000 ng/ml) International normalized ratio (INR) less than 2 times normal. ALT and AST
less than 3 times the upper limit of normal.
- Severe renal impairment (as evidenced by GFR < 30% predicted normal)
- Ejection fraction or shortening fraction below lower limit of normal for age.
- Pregnancy
- Lactating and pregnant females are excluded
- Positive HLA crossmatch with donor.
- No sickle cell chronic lung disease > Stage 2