BONE MARROW TRANSPLANT IN
CANCER TREATMENT
Bone marrow transplant is a specialized treatment that replaces damaged blood-forming cells, helping treat leukemia, lymphoma, myeloma, and other serious blood disorders.
analyticsAt a Glance
- check_circleReplaces damaged bone marrow with healthy donor or patient stem cells
- check_circleStandard of care for leukaemia, lymphoma, and multiple myeloma
- check_circleAdvanced programmes in India, China, and internationally
- check_circleRequires pre-transplant conditioning and post-transplant monitoring
What Is Bone Marrow Transplant?
In cancer treatment, bone marrow transplant refers to hematopoietic stem cell transplantation (HSCT), a procedure where the patient's bone marrow is destroyed with high-dose chemotherapy and radiation, then rebuilt with healthy stem cells from a donor or the patient's own stored cells.
“HSCT has a five-decade evidence base and remains one of the most powerful curative treatments for blood cancers in the right patients.”
A bone marrow transplant is a procedure in which the patient's bone marrow is intentionally destroyed using very high-dose chemotherapy and sometimes radiation and then rebuilt by infusing donor or the patient's own stem cells that travel to the bone marrow and regenerate the entire blood-forming and immune system.
It is important to clarify this distinction at the outset because the term 'stem cell therapy' is used very broadly in the lay public and in unregulated medical marketing to describe a wide range of interventions, many of which have no established evidence in cancer treatment and some of which represent genuine medical fraud. This pillar page focuses exclusively on hematopoietic stem cell transplantation, which has a robust five-decade evidence base and remains one of the most powerful anti-cancer treatments in existence for appropriate patients.
Dose Escalation
HSCT allows chemotherapy doses far beyond what the bone marrow could normally survive. The marrow is then rescued with stem cell infusion, turning a dose-limiting toxicity into a treatment strategy.
Graft-Versus-Tumour Effect
In allogeneic transplant, the donor immune system actively attacks residual cancer cells — a naturally occurring anti-cancer immune surveillance that no other treatment can replicate.
What HSCT Is Not
HSCT is a standardised, evidence-based procedure governed by EBMT and CIBMTR protocols. It is completely different from unproven "stem cell treatments" marketed by unlicensed facilities for cancer or anti-aging.
Why HSCT Matters in Oncology?
“Important: Hematopoietic stem cell transplantation for cancer is an established, regulated medical procedure with decades of published evidence and worldwide standardization through organizations including the European Bone Marrow Transplantation group (EBMT), the Center for International Blood and Marrow Transplant Research (CIBMTR), and the BMT-CTN. It is entirely distinct from unproven stem cell therapies marketed for cancer, anti-aging, or regenerative purposes at unlicensed clinics. Patients should be alert to this distinction and should only pursue HSCT at accredited transplant centers with documented transplant experience.”
There are two separate but important aspects to HSCT that require some explanation. First, it provides a way to escalate the dosage of chemotherapeutic drugs and radiation therapy to levels that exceed the capacity of the bone marrow to cope with them. The bone marrow is the organ that sets the upper limits of tolerable dosages for many of the strongest anti-cancer drugs because above a certain level, they induce permanent damage to the bone marrow, preventing its hematopoietic function, from which it will not recover.
The second one, and perhaps the more important aspect of allogeneic transplantation, is immunological. When stem cells from a suitable donor are transfused into the patient, they not only regenerate the recipient’s own blood system but also create a new immune system that originates from the donor. The new immune system is able to detect and kill cancer cells that have survived after the pre-transplantation preparation procedure, a process called the graft-versus-tumor effect. In the case of certain blood malignancies, including chronic myeloid leukemia and chronic lymphocytic leukemia, the graft versus tumor effect represents the main anticancer approach used during HSCT.
The Biology Behind HSCT: How Stem Cells Rebuild the Blood System
The entire human blood system, every red cell, white cell, and platelet, derives from a small pool of hematopoietic stem cells (HSCs) in the bone marrow. Because this pool is self-renewing and capable of differentiating into all blood lineages, the entire system can be rebuilt from a small number of healthy donor or patient stem cells.
Understanding how HSCT works and why it is such a complicated process will be easier to do if one starts off with knowledge of the physiology of blood and the immune system. The whole blood physiology process, which includes the production of red cells, white cells, and platelets in the body, originates from a pool of hematopoietic stem cells (HSCs) located within the bone marrow. HSCs are multipotent self-renewing cells that are capable of differentiating into different blood cell lineages. This includes erythroid cells, which generate red cells and platelets; myeloid cells, which generate neutrophils, monocytes, and macrophages; and lymphoid cells, which generate T-cells, B-cells, and natural killer cells.
Such a hierarchical arrangement is what allows HSCT to occur. Since all blood cells have an origin from this limited pool of stem cells, it is enough to restore the same from this very small population of stem cells by infusing only some number of healthy cells from the body’s own stored cells or from a donor’s to rejuvenate the whole system. The stem cells will reach the bone marrow via the bloodstream and get engrafted there and produce new cells through proliferation. The time between the death of the bone marrow and the complete engraftment and restoration of the blood cells is known as the engraftment period. This is the most dangerous stage for a transplant where patients are highly vulnerable to infections, bleeds, and so forth.
Erythroid Lineage
Produces red blood cells and platelets. Red cells survive ~120 days, requiring continuous marrow production.
Myeloid Lineage
Produces neutrophils, monocytes, and macrophages — the frontline innate immune defence. Neutrophils survive only ~24 hours.
Lymphoid Lineage
Produces T-cells, B-cells, and natural killer cells — the adaptive immune system responsible for targeted pathogen and cancer cell destruction.
Types of Stem Cell Transplant: Autologous vs Allogeneic
The most fundamental distinction in HSCT determines stem cell source, treatment rationale, immunologic consequences, and risk profile. Understanding this difference is critical for patients considering transplant.
Autologous Transplant
- Patient's own stem cellsCollected before conditioning, frozen, then reinfused after high-dose chemo.
- No GvHD riskNo immune mismatch since donor and recipient are the same person.
- No graft-versus-tumour effectAnti-cancer benefit comes solely from high-dose chemotherapy.
- Used in myeloma, lymphoma, germ cell tumoursStandard consolidation for transplant-eligible myeloma.
Allogeneic Transplant
- Donor stem cells replace marrow and immune systemFrom matched sibling, unrelated donor, haploidentical, or cord blood.
- Graft-versus-tumour effectDonor immune cells attack residual cancer — uniquely curative mechanism.
- GvHD riskDonor immune cells may also attack normal tissues, causing significant morbidity.
- Used in AML, ALL, CML, MDS, myelofibrosisDiseases where immune anti-cancer surveillance is critical.
Sources of Stem Cells: Bone Marrow, Peripheral Blood, and Cord Blood
Three clinically validated sources of HSCs are used for transplant, each with distinct biological characteristics, advantages, and limitations.
| Source | Collection Method | Engraftment Speed | Key Advantage | Key Limitation |
|---|---|---|---|---|
| Peripheral Blood (PBSCs) | G-CSF ± plerixafor mobilisation → apheresis (outpatient, non-surgical) | Fastest (14-21 days for neutrophils) | High cell yield; most common source for adults | Slightly higher risk of chronic GvHD vs bone marrow |
| Bone Marrow | Aspiration from posterior iliac crests under anaesthesia (surgical) | Moderate | Lower T-cell content may reduce chronic GvHD risk | Requires operating theatre and general anaesthesia |
| Umbilical Cord Blood | Collected at delivery, stored in cord blood banks | Slowest (delayed engraftment) | Tolerates wider HLA disparity; valuable for ethnic minorities | Finite cell dose per unit; risk of graft failure in large patients |
Which Cancers Are Treated with Stem Cell Transplantation?
The strongest evidence base for HSCT is in hematological malignancies, the very cancers arising from the blood and immune system. Select solid tumors also benefit from high-dose chemotherapy with autologous rescue.
| Cancer | Transplant Type | Clinical Context |
|---|---|---|
| AML (intermediate/adverse risk) | Allogeneic | First or subsequent CR; GVT reduces relapse risk |
| ALL (high-risk / relapsed) | Allogeneic | First CR (high-risk) or post-CAR-T bridge consolidation |
| CML (TKI failure / blast crisis) | Allogeneic | Reserved for TKI-refractory or accelerated/blast phase |
| MDS (higher-risk) | Allogeneic | Only curative option for higher-risk MDS |
| Hodgkin Lymphoma (r/r) | Autologous | Standard second-line after failed first-line chemo |
| DLBCL (chemosensitive relapse) | Autologous | Standard for relapse if not CAR-T eligible |
| Multiple Myeloma | Autologous | Standard consolidation after induction; tandem for high-risk |
| Myelofibrosis | Allogeneic | Only curative option; JAK inhibitors as bridge |
| Aplastic Anaemia (severe) | Allogeneic | Matched sibling donor preferred in young patients |
| Germ Cell Tumours (r/r) | Autologous | Salvage for cisplatin-refractory testicular cancer |
| High-risk Neuroblastoma | Autologous | Standard consolidation in paediatric high-risk disease |
The Transplant Process: Step by Step
The entire transplant journey from initial evaluation through engraftment and recovery spans several months. The inpatient phase alone lasts weeks to over a month.
- 1
Pre-Transplant Evaluation
Comprehensive assessment: organ function (cardiac, pulmonary, hepatic, renal), infectious disease screening (CMV, EBV, hepatitis, HIV), dental clearance, fertility preservation, HLA typing, and donor identification.
- 2
Stem Cell Collection or Donor Work-Up
Autologous: G-CSF mobilisation + apheresis to harvest and cryopreserve patient's stem cells. Allogeneic: donor evaluation, mobilisation, and peripheral blood or bone marrow harvest.
- 3
Conditioning Regimen
High-dose chemotherapy ± total body irradiation administered in a dedicated inpatient unit with HEPA filtration. Destroys residual cancer and creates marrow space for new stem cells.
- 4
Stem Cell Infusion (Day 0)
Thawed (autologous) or fresh (allogeneic) stem cells infused intravenously over 1-2 hours. Generally well tolerated; mild flushing or nausea from DMSO preservative may occur.
- 5
Engraftment Period (Day 0 to ~Day +30)
The most critical phase. Bone marrow is empty; intensive support with antibiotics, antifungals, antivirals, transfusions, and nutritional care. Neutrophil engraftment: Day +14-21 (PBSCs). Platelet engraftment: Day +28-35.
- 6
Post-Engraftment Recovery and Long-Term Follow-Up
Immune reconstitution takes months to years. Monitoring for GvHD, infections, relapse, organ function, and late effects. Complete re-vaccination required. Formal long-term follow-up programme essential.
Conditioning Regimens: Myeloablative vs Reduced-Intensity
The conditioning regimen — chemotherapy ± radiation given before infusion — is one of the most critical decisions in transplant planning, directly affecting the balance between efficacy and toxicity.
| Aspect | Myeloablative (MAC) | Reduced-Intensity (RIC) |
|---|---|---|
| Dose intensity | Maximum tolerable; permanently ablates marrow | Lower doses; sufficient for engraftment without full ablation |
| Anti-cancer mechanism | Primarily chemotherapy-driven tumour kill | Primarily graft-versus-tumour (immunologic) |
| Toxicity profile | Higher: mucositis, organ damage, TRM | Lower non-relapse mortality; better tolerated |
| Patient suitability | Younger, fitter patients; high relapse risk diseases | Older patients (60s-70s), comorbidities |
| Best indications | AML, ALL, high-risk disease requiring maximum kill | CML, FL, MDS — diseases with strong GVT effect |
| Common regimens | BuCy, Cy/TBI, BEAM (lymphoma auto-HSCT) | Fludarabine/melphalan, Flu/Bu2 |
Graft-Versus-Tumour Effect: The Immune Anti-Cancer Mechanism
The graft-versus-tumour (GVT) effect is one of the most powerful immunologic phenomena in cancer medicine — a naturally occurring, potentially curative immune attack driven by donor T-cells and NK cells recognising the recipient's cancer as foreign.
“Donor lymphocyte infusions alone can induce remission in relapsed CML with response rates exceeding 70% — proving the GVT effect is genuinely curative.”
Evidence for GVT
Relapsed patients after allo-HSCT achieved new remissions from donor lymphocyte infusions alone — no chemo. Identical twin transplants show higher relapse rates than matched unrelated donor transplants, confirming immune-mediated anti-cancer activity.
The GVT-GvHD Dilemma
The same donor T-cells that attack cancer also attack normal tissues, causing graft-versus-host disease. Separating GVT from GvHD through selective T-cell depletion and post-transplant immune modulation remains a central research challenge.
Donor Lymphocyte Infusion (DLI)
Additional donor T-cell infusions used for molecular or haematological relapse post-transplant, or prophylactic immune reconstitution. Most effective in CML (>70% response in molecular relapse). Main risk is GvHD, carefully dose-titrated at experienced centres.
Complications and Risks: GvHD and Other Major Toxicities
HSCT is one of the most medically intensive cancer treatments. Understanding risks is essential for informed decision-making — these risks are why transplant must be performed at experienced centres with full supportive care.
Graft-Versus-Host Disease (GvHD)
The most distinctive complication of allogeneic HSCT. Acute GvHD (skin, GI, liver) is graded I-IV; Grade III-IV carries significant mortality. Chronic GvHD mimics autoimmune disease and can affect multiple organs. Treated with corticosteroids, ruxolitinib (steroid-refractory), and other immunosuppressants.
Infectious Complications
Three risk periods: pre-engraftment (bacterial/fungal from neutropenia), early post-engraftment (viral — CMV, EBV, adenovirus), and late post-transplant (encapsulated bacteria/fungi with chronic GvHD). Requires prophylaxis for PJP, Aspergillus, CMV, and respiratory viruses.
Sinusoidal Obstruction Syndrome (SOS/VOD)
Hepatic sinusoid occlusion causing rapid weight gain, ascites, jaundice, and liver failure. Treated with defibrotide for severe cases.
Other Major Risks
Primary graft failure (persistent cytopenias requiring second transplant), TA-TMA (endothelial injury with haemolysis and organ dysfunction), pulmonary complications (bronchiolitis obliterans, IPS), secondary malignancies (PTLD, therapy-related MDS/AML), and transplant-related mortality (2-5% autologous; 5-20%+ allogeneic).
Donor Matching: HLA Typing and Finding a Compatible Donor
For allogeneic HSCT, donor compatibility is established by matching human leukocyte antigens (HLA) — cell surface proteins the immune system uses to distinguish self from non-self. A 10/10 match across HLA-A, -B, -C, -DRB1, and -DQB1 is the gold standard.
- 1
Matched Sibling Donor (Best Option)
25% chance any sibling is a full HLA match. Lowest GvHD risk and best outcomes. Always tested first.
- 2
Matched Unrelated Donor (MUD)
International registries (WMDA, DKMS, Be The Match) hold 40M+ donors. A 10/10 MUD is the next best option when no sibling match exists.
- 3
Haploidentical Donor
A partially matched family member (parent, child, half-matched sibling). Enabled by post-transplant cyclophosphamide for GvHD control. Critical for ethnic minorities with limited registry representation.
- 4
Cord Blood
Immunologically naive T-cells allow wider HLA disparity. Stored in public cord blood banks. Especially valuable for patients without other donor options.
Key Outcome Data for BMT
- 60-70%5-Year Survival (AML CR1, Matched Sibling)Young patients with AML in first complete remission — best-case scenario.
- 3-4 yrMedian PFS (Myeloma, Auto-HSCT)With contemporary induction including daratumumab-based regimens.
- 40M+Registered Donors WorldwideCoordinated through WMDA, DKMS, Be The Match, and national registries.
- >70%DLI Response Rate (CML Molecular Relapse)Demonstrating the curative power of the graft-versus-tumour effect.
- 14–21 daysMedian time to neutrophil engraftmentIn many modern stem cell transplant series, white blood cell recovery begins within about two to three weeks after transplant, making this one of the most important early recovery milestones.
- ~60%ong-term survival in selected adult ALL transplant patientsModern allogeneic transplant can deliver durable survival in appropriately selected adults with acute lymphoblastic leukemia, especially when performed in remission at experienced centers.
International Treatment and How CancerFax Helps
Centre expertise, transplant volume, and infrastructure quality directly and measurably impact transplant outcomes. Higher-volume centres achieve better engraftment rates, lower transplant-related mortality, and improved survival.
Stem cell transplant is one of the clinical procedures that can benefit from the center's experience, the volume of transplants, the quality of infrastructure, and the program's experience itself. The published literature indicates that high-volume centers have higher rates of engraftment, lower rates of transplant-related deaths, better handling of complications, and increased overall survival compared to low-volume programs.
For patients from abroad, especially for patients coming from nations with less-developed transplant infrastructure, without access to donor registries, or who are unable to undergo certain types of transplants like haploidentical or cord blood transplants, referral to an internationally recognized specialist center may prove life-changing.
Medical Records & Eligibility Review
CancerFax helps patients compile, translate, and submit medical records for transplant eligibility assessment at international centres.
Donor Search Coordination
Initiation and coordination with international donor registries (WMDA network), including haploidentical and cord blood options.
Centre Selection & Referral
Identification of the most appropriate transplant centre based on disease type, donor availability, conditioning requirements, and geographic accessibility.
Pre-Transplant Consultation
Arrangement of specialist consultations and evaluations at international transplant centres before travel.
Travel, Accommodation & Cost Planning
Logistical support for patients and accompanying family members, including cost estimation and financial planning.
Post-Transplant Shared Care
Coordination between the transplant centre and home oncologist for long-term follow-up, vaccination schedules, and GvHD management.
Know Further Details About Stem Cell Transplant
Each page provides deeper coverage of a specific topic within bone marrow transplant for cancer treatment.
- What is Stem Cell Therapy in Cancer?
- Types of Stem Cell Transplants
- Autologous vs Allogeneic Transplant
- Stem Cell Therapy for Leukemia
- Stem Cell Therapy for Lymphoma
- Stem Cell Therapy for Multiple Myeloma
- Stem Cell Therapy for Aplastic Anemia
- Eligibility for Stem Cell Transplant
- Donor Matching for Stem Cell Transplant
- The Stem Cell Transplant Process
- Conditioning Regimen Explained
- Graft vs Host Disease Explained
- Side Effects of Stem Cell Transplant
- Recovery After Stem Cell Transplant
- Success Rates of Stem Cell Transplant
- Stem Cell Therapy vs CAR-T Therapy
- Cost of Stem Cell Transplant Worldwide
- International Centers for Stem Cell Therapy
- Clinical Trials in Stem Cell Therapy
- Questions to Ask Before Stem Cell Transplant
Questions Every Patient Should Ask About Stem Cell Transplant
These questions are designed to help patients engage actively and effectively with their hematologist, transplant physician, or a CancerFax-connected specialist at every stage of the HSCT decision-making and planning process.
About the Transplant
What is the difference between a bone marrow transplant and a stem cell transplant?
In modern practice, "bone marrow transplant" and "stem cell transplant" refer to the same procedure — hematopoietic stem cell transplantation (HSCT). The term "bone marrow transplant" dates from when marrow harvest was the only stem cell source. Today, peripheral blood stem cells are the most common source, but the umbrella term HSCT covers all three sources: peripheral blood, bone marrow, and cord blood.
How long does the entire transplant process take?
From initial evaluation through engraftment and early recovery, expect 3-6 months. Pre-transplant workup takes 2-4 weeks, conditioning is 4-10 days, and the inpatient engraftment phase lasts 3-5 weeks. Full immune reconstitution can take 1-3 years after allogeneic transplant.
Can older patients undergo stem cell transplant?
Yes. Reduced-intensity conditioning (RIC) has extended allogeneic HSCT to patients in their 60s and even 70s with acceptable toxicity. The decision depends on the patient's fitness, comorbidities, disease biology, and the expected benefit of transplant versus alternative treatments. Many centres now use comorbidity indices rather than age alone to assess eligibility.
What is graft-versus-host disease and how serious is it?
GvHD occurs when donor immune cells attack the recipient's normal tissues. Acute GvHD (skin, GI, liver) ranges from mild to life-threatening (Grade III-IV). Chronic GvHD can affect multiple organs and mimic autoimmune disease. GvHD is the most common cause of non-relapse mortality after allogeneic transplant but is manageable with modern immunosuppressive protocols at experienced centres.
Treatment process
What does the bone marrow transplant process involve?
The process generally follows several stages. First, stem cells are collected, either from the patient (autologous) or from a matched donor (allogeneic), usually from the bloodstream after a mobilizing medication, or sometimes directly from bone marrow. The patient then receives a conditioning regimen, a course of high-dose chemotherapy and sometimes radiotherapy, designed to destroy the diseased marrow and make room for the new cells.
Current EBMT guidance notes that conditioning intensity is tailored by patient factors; for example, patients younger than 30 years old should receive high-dose cyclophosphamide, and those aged 30 to 40 years old should receive a fludarabine-based regimen with a lower dose of cyclophosphamide. The stem cells are then infused, followed by a recovery period in the hospital while blood counts rebuild and the new marrow begins functioning, typically lasting several weeks.
What are the side effects and risks of bone marrow transplant?
The conditioning treatment temporarily wipes out the immune system, leaving patients vulnerable to infection, fatigue, and low blood counts during recovery. For allogeneic transplants, the most significant specific risk is graft-versus-host disease, where the donor's immune cells attack the patient's healthy tissue. Guidelines highlight specific measures to reduce this risk, recommending that all patients should receive in vivo lymphodepletion with ATG or alemtuzumab, and bone marrow is the recommended source of stem cells in certain high-risk settings, like severe aplastic anemia, specifically to lower chronic graft-versus-host disease risk. Long-term risks can also include fertility effects, organ effects from prior chemotherapy and radiotherapy, and a small risk of second cancers, which is why long-term follow-up care matters.
Efficacy and outcomes
How effective is a bone marrow transplant?
Effectiveness depends heavily on the disease being treated, the patient's age, and the type of transplant. In multiple myeloma, a large single-center study of patients who had a second autologous transplant at relapse found a median overall survival of 47.3 months after the procedure. In acute myeloid leukemia, outcomes have improved meaningfully over time, with current data showing about 45 to 50% of patients who get allogeneic transplants survive for five years, depending on age and disease characteristics.
For severe aplastic anemia, transplant from a fully matched sibling donor is considered the standard of care for adult patients, with outcomes that decline as patient age increases, becoming less favorable above 40 and generally not recommended above 50.
Can a bone marrow transplant cure cancer?
For many blood cancers and certain non-cancerous blood disorders, a bone marrow transplant can be curative, and it remains the only potentially curative option for some conditions. This is reflected in how transplant guidelines are written. The most recent international recommendations describe transplant indications based on the risk of the disease, risk of the HCT procedure and non-HCT strategies, including evolving cellular therapies, which means the decision to pursue a curative-intent transplant is always weighed against the disease's natural risk and the procedure's own risks. A cure is realistic for many patients, but it is not automatic, and outcomes vary by disease type, disease status at the time of transplant, donor match quality, and patient age and fitness.
About Eligibility and Access
What if I cannot find a matched donor?
Multiple alternatives exist. Haploidentical transplant from a half-matched family member (parent, child, or sibling) is increasingly performed with excellent outcomes using post-transplant cyclophosphamide. Cord blood transplant allows wider HLA disparity. CancerFax can assist with international donor registry searches and alternative donor identification.
Is stem cell transplant a cure for cancer?
For many blood cancers, HSCT offers the best chance of long-term cure. Allogeneic transplant provides ongoing immune surveillance through the graft-versus-tumour effect. Autologous transplant deepens remission but is generally not curative for myeloma. Cure rates depend heavily on disease type, stage, remission status at transplant, and donor match quality.
How does CancerFax help international patients access transplant?
CancerFax provides end-to-end support: medical record review, eligibility assessment, donor search coordination through international registries, centre selection based on disease type and donor availability, pre-transplant specialist consultations, travel and accommodation logistics, cost planning, and post-transplant shared care coordination with the home oncologist.
How CancerFax Helps
CancerFax is a specialist cancer access and patient-navigation platform. We help patients and families understand their options, organise medical records, coordinate hospital communication, and support cross-border treatment planning where appropriate.
We help collect and organise reports, scans, pathology, biomarker results, and treatment history for structured case review.
We communicate with hospitals or trial teams to assess whether a case may be suitable for further screening.
We support appointment coordination, document submission, translation, and direct communication with international departments.
For international patients, we help with practical coordination — travel planning, hospital admission guidance, and local support.
If this option is not suitable, we help explore other relevant treatments, clinical trials, or advanced care pathways.
From inquiry through to follow-up, our coordinators provide a single point of contact for the family.
CancerFax does not guarantee treatment access, eligibility, or clinical outcome. Our role is to help patients access accurate information, structured review, and appropriate specialist pathways.
Are You Ready to Explore Stem Cell Transplant for Your Cancer?
Stem cell transplantation is one of the most critical decisions a cancer patient will face. CancerFax connects patients worldwide to leading haematology and transplant centres, guides donor search and access, and provides comprehensive support throughout the transplant journey.
This content is for informational purposes only and does not constitute medical advice. All transplant decisions must be made in consultation with a qualified haematologist and transplant physician with full access to the patient's clinical information. CancerFax connects patients with medical teams but does not provide direct medical care.