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Allogeneic Stem Cell Transplantation

Allogeneic stem cell transplantation involves transferring the stem cells from a healthy person (the donor) to you after high-intensity chemotherapy or radiation.

Allogeneic stem cell transplantation is used to cure some patients who:

  • are at high risk of relapse
  • don't respond fully to treatment
  • relapse after prior successful treatment

Allogeneic stem cell transplantation can be a high-risk procedure. The high-conditioning regimens are meant to severely or completely impair your ability to make stem cells. You may experience side effects during the days you receive high-dose conditioning radiation or chemotherapy. Specifically, high-conditioning therapy's goals are to:

  • treat the remaining cancer cells intensively to make a cancer recurrence less likely
  • inactivate the immune system to reduce the chance of stem cell graft rejection
  • enable donor cells to travel to the marrow (engraftment), produce blood cells and bring about graft versus tumor effect

Possible Adverse Effects

The immune system and the blood system are closely linked and can't be separated from each other. Because of this, allogeneic transplantation means that not only the donor's blood system but also his or her immune system is transferred. As a result, these adverse effects are possible:

  • immune rejection of the donated stem cells by the recipient (host-versus-graft effect)
  • immune reaction by the donor cells against the recipient's tissues (graft-versus-host disease [GVHD])

The immune reaction, or GVHD, is treated by giving drugs to the patient after the transplant to reduce the ability of the donated immune cells to attack and injure the patient's tissues. See Graft Versus Host Disease.

Allogeneic stem cell transplants for patients who are older or have overall poor health are relatively uncommon. This is because the pretransplant conditioning therapy is generally not well tolerated by such patients, especially those with poorly functioning internal organs. However, reduced intensity allogeneic stem cell transplants may be an appropriate treatment for some older or sicker patients.

T-Lymphocyte Depletion

One goal of allogeneic stem cell transplant is to get the T lymphocytes in the donor's blood or marrow to take hold (engraft) and grow in the patient's marrow. Sometimes the T lymphocytes attack the cancer cells. When this happens, it's called graft versus tumor (GVT) effect (also called graft versus cancer effect). The attack makes it less likely that the disease will return. The effect is more common in myeloid leukemias than it is in other blood cancers.

Unfortunately, T lymphocytes are the same cells that cause graft versus host disease (GVHD). Because of this serious and sometimes life-threatening side effect, doctors in certain cases want to decrease the number of T lymphocytes to be infused with the stem cells. This procedure, called T-lymphocyte depletion, is currently being studied by researchers. The technique involves treating the stem cells collected for transplant with agents that reduce the number of T lymphocytes.

The aim of T-lymphocyte depletion is to lessen GVHD's incidence and severity. However, it can also cause increased rates of graft rejection, a decreased GVT effect and a slower immune recovery. Doctors must be careful about the number of T lymphocytes removed when using this technique.

Stem Cell Selection

Stem cell selection is another technique being studied in clinical trials that can reduce the number of T lymphocytes that a patient receives. Because of specific features on the outer coat of stem cells, doctors can selectively remove stem cells from a cell mixture. This technique results in a rich number of stem cells and fewer other cells, including T lymphocytes.

Finding a Donor

If you're considering allogeneic stem cell transplantation, you'll need a bone marrow donor. First, you and your siblings, if any, will have your blood or a scraping from your inside cheek tested to determine tissue type. A sibling has the potential to match you most closely because you both received your genes from the same parents.

A lab technician examines the surface of the sample tissue cells to identify the proteins that give everyone his or her own unique tissue type, called human leukocyte antigens (HLAs). If the HLA on the donor cells are identical (from identical twins, for example) or similar (such as those from siblings), the transplant is more likely to be successful. On average, you have a one in four chance of having the same HLA type as a sibling, but many patients don't have a sibling with the same tissue type.

If a brother or sister doesn't provide a match, your doctor will search registries of volunteer donors such as the National Marrow Donor Program for an unrelated donor that matches your tissue type. A donor who's not related to you but who has a similar tissue type is called a matched unrelated donor (MUD).

Collecting Stem Cells

Stem cells for transplantation are collected from three sources:

  • blood
  • bone marrow
  • placental and umbilical cord blood

Before stem cells are collected from blood or bone marrow, the donor must undergo a thorough physical exam and blood testing for hepatitis viruses, human immunodeficiency disease (HIV) and other infectious agents or viruses.


The most common source of stem cells for transplant is peripheral blood, the blood that flows throughout our veins and arteries.

Bone marrow normally releases a small number of peripheral blood stem cells (PBSCs) into the bloodstream. To obtain enough PBSCs for a transplant, the donor takes a white cell growth factor, such as granulocyte-colony stimulating factor (G-CSF) drug, to increase the number of stem cells by drawing them out of the marrow and into the bloodstream. When a patient's own stem cells are used, both G-CSF and the chemotherapy used to treat the disease usually increase PBSCs. In patients who have myeloma and non-Hodgkin lymphoma, the drug plerixafor (Mozobil®) can be used to mobilize their own stem cells.

The blood is removed from the donor and the cells collected using a process called apheresis. The procedure involves placing a needle in the donor's vein, usually in the arm, similar to getting a blood test. The donor's blood is pumped through an apheresis machine, which separates the blood into four components: red cells, plasma, white cells and platelets. The white cells and platelets, which contain the stem cells, are collected, while the red cells and plasma are returned to the donor. It can take one to two sessions of apheresis to collect enough blood from a MUD. If you're your own donor, it may take more than two sessions.

Bone Marrow

If enough stem cells can't be retrieved from apheresis, they can be removed directly from the bone marrow. This requires the donor to undergo a minor outpatient surgical procedure.

While the donor is under anesthesia, the surgeon inserts a hollow needle into the donor's pelvic bones just below the waist and removes liquid marrow. This is done a number of times until several pints of marrow are collected. The donor can expect to stay in the hospital for about six to eight hours after the procedure to recover from the anesthesia and the acute pain at the needle insertion sites. He or she may feel some lower back soreness for a few days afterward. The donor's body replaces the marrow soon after the procedure. Red cells are also removed, and the donor may experience anemia, which in some cases is treated with iron supplements.

The marrow that's removed (harvested) is passed through a series of filters to remove bone or tissue fragments and then placed in a plastic bag from which it can be infused into the recipient's vein. The marrow is usually given to the patient within a few hours and rarely longer than within 24 hours. If necessary, the marrow can be frozen and stored and can remain suitable for use for years. If the transplant is autologous, the marrow is usually frozen while the patient undergoes intensive chemotherapy.

Placental and Umbilical Cord Blood

A rich source of stem cells for blood cancer patients is stored stem cells collected from the umbilical cord and placenta after a baby is born, called the cord blood unit. Parents may choose to have the cord blood unit collected after delivery. Healthy parents with healthy children and no transplant candidate in the family can choose to donate their newborn's cord blood to cord blood banks or research programs at participating hospitals. Parents with a child or a family member who could be a candidate for transplantation should discuss with their doctor the potential benefits of saving their newborn's cord blood for possible family use.

Stem cells are tested for tissue type, cell counts and infectious agents and frozen for long-term storage at a cord blood bank for later use. When they're needed, they're shipped to the transplant center where they're thawed and given to the patient.

Advantages of Using Cord Blood

The advantages of using cord blood stem cells instead of donor peripheral blood or donor marrow stem cells include:

  • Availability. Cord blood stored in a public cord blood bank has been prescreened, tested and frozen and is ready to use; on the other hand, it can take several months to find and confirm a marrow or peripheral blood donor.
  • HLA matching. A close match between the patient and the cord blood unit can improve outcome.
  • Graft-versus-host disease. Patients who undergo cord blood stem cell transplant are less likely to develop graft-versus-host disease  (GVHD) or experience less severe complications from GVHD than patients who have bone marrow or peripheral blood transplants.
  • Diversity. Donated cord blood units collected from hospitals where births from varied ethnic backgrounds are well represented have the potential to provide a source of stem cells that reflects racial diversity.
  • Infectious disease transmission. Cord blood stem cell transplants carry less risk of transmission of blood-borne infectious diseases compared with stem cells from the peripheral blood or marrow of related or unrelated donors.

Disadvantages of Using Cord Blood

There can be disadvantages of using cord blood stem cells as well:

  • Clinical data. Genetic diseases may be present but not apparent at the time of birth and could be transplanted to a patient via donor cord blood stem cells. Procedures to track this possibility require follow-up until the donor infant is months or even years old. Such follow-up has proven difficult. A partial solution used by many public cord blood banks is to obtain a detailed health history from potential donors in advance of cord blood collection, similar to standard procedures used to screen volunteer blood donors.
  • Storage. Researchers don't know how long cord blood can be frozen and stored before it loses its effectiveness. But cord blood samples have been preserved for as long as 10 years and have still been successfully transplanted.
  • Engraftment. The number of cells needed to give a transplant patient the best chance for engraftment and for surviving the transplant is based on his or her weight, age and disease status. A cord blood unit might contain too few stem cells for the recipient's size. Because of the smaller number of stem cells, cord blood stem cell transplants engraft more slowly than stem cells from marrow or peripheral blood. Until engraftment occurs, patients are at risk of developing life-threatening infections. This means that cord blood transplant recipients may be vulnerable to infections for an average of up to one to two months longer than marrow and peripheral blood stem cell recipients are.

After Treatment

Often by the second or third day after an allogeneic stem cell infusion, the decrease in marrow function begins to have its effects. You'll be kept in a protected environment to reduce contact with infectious agents. Generally within two to four weeks after the transplant, the engraftment of donated cells is apparent from the appearance of normal white cells in your blood. You'll receive periodic transfusions of red cells and platelets until your marrow function is restored by the transplanted stem cells.

Your doctor carefully monitors you with physical exams, blood chemistry tests, imaging studies and other tests to ensure that your heart, lungs, kidneys, liver and other major organs are functioning normally. You'll need drugs to prevent GVHD, in addition to blood transfusions. If you're suffering from a poor appetite or diarrhea, you may need to be fed intravenously or through a duodenal tube (called hyperalimentation) to ensure you get adequate nutrition

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last updated on Tuesday, March 15, 2011

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