Objectives Hematopoietic Stem Cell Transplant Karen Anderson, MN, RN, OCN University of Washington Medical Center Define HSCT Provide overview of HSCT process Discuss acute complications of HSCT Discuss chronic/late complications of HSCT Indications for HSCT Approaches to Transplant Malignant diseases: Acute and Chronic Leukemia Hodgkin's Disease and Non-Hodgkin's lymphoma Myelodysplastic Syndromes Multiple Myeloma Selected solid tumors Non-malignant diseases: Hematologic Disorders (Aplastic Anemia, Fanconi s Anemia, Sickle Cell Anemia) Congenital Immunodeficiencies (SCID, Wiskott Aldrich Syndrome) Inborn Errors of Metabolism (Hurler s Syndrome, Gaucher Disease) Autoimmune Diseases (ex: Systemic Sclerosis, Multiple Sclerosis) Autologous Standard allogeneic related or unrelated Non-myeloablative (allogeneic) Tandem Syngeneic Haploidentical 1
Bone Marrow (BM) Peripheral Blood (PBSC) Umbilical Cord Blood (UCB) Stem Cell Sources Advantages Good source of stem cells Lower rate of infections day + 100 to +365 Most abundant source of stem cells Faster Engraftment Lower rate of infections to Day +100 More graft versus leukemia effect than BM or UCB Readily available & lower costs HLA mismatch more acceptable Lack of donor risks Less risk of GVHD Disadvantages Anesthesia & surgical risks for donor Longer time to engraftment than PBSC Long-term effect of growth factors on healthy donors unknown Slightly higher risk of agvhd & cgvhd Delayed engraftment Smaller dose of stem cells Autologous HSCT: An Overview Theory behind therapy: The stem cell rescue of the ablated marrow allows for high dose chemo/and or radiation to treat the disease Approach often utilized for certain types of lymphomas, multiple myeloma, selected solid tumors and nonmalignant conditions Requires collection and cryopreservation of one s own stem cells Small risk of autologous GVHD, aka pseudo-gvhd Autologous HSCT: Mobilization and Apheresis Mobilization: A technique used to increase the number of circulating hematopoietic stem cells from the bone marrow into the bloodstream High dose chemotherapy + G-CSF ± plerixafor G-CSF Apheresis: The method for stem cell collection using a dialysistype machine with cell separators that are programmed to collect stem cells Allogeneic HSCT: An Overview Theory behind Therapy: Standard allogeneic: The stem cell rescue of the ablated marrow and re-set of the immune system by the donor s stem cells allows for a combination of the chemotherapy and/or radiation therapy plus the stem cells that create a graft versus tumor effect to cure the disease. Nonmyeloablative allogeneic: The donor stem cells provide a graft versus tumor effect that cures the disease. 2
Allogeneic HSCT: An Overview More common approach for acute leukemias. Also utilized to treat various hematological and immunological disorders, lymphomas, multiple myeloma, selected solid tumors Non-self source of stem cells: sibling, family member, unrelated donor, umbilical cord blood Immunosuppression necessary to prevent graft rejection and GVHD HSCT Process 1. Planning phase 2. Preparing for transplant 3. Conditioning 4. Transplant 5. Awaiting Engraftment 6. Post-engraftment recovery 7. Long-term follow-up Planning Phase Patient & Donor Planning Oncologist reviews transplant with patient & family Referral to transplant center for consultation Address fertility HLA type patient & siblings Search the donor registries Other Preparations Assess finances (insurance coverage or pay cash) Select transplant center (statistics on NMDP website) Select a caregiver Make plans for relocation if necessary HLA Typing Degree of compatibility between donor and patient Minimum match recommendations: - 6/8 loci for PBSC and BM donors - 4/6 loci for UCB 25% chance that each sibling will be an HLA-match 70% of people do not have suitable family donor Median search time for a PBSC or BM donor is 51 days, and 2 weeks for UCB 3
Preparative Phase Medical Evaluation Blood Work, Bone Marrow Aspirate & Biopsy, Lumbar Puncture, CT, PET, MRI Oral exam and gynecologic exam Nutritional, Psychosocial, and Spiritual Assessment Chest X-ray, PFTs and Cardiac Studies Family Conference & Informed Consent Process Discussion of protocol and plan, risks and benefits Sign consents Preparation of the Family and Caregiver Orientation to center; Caregiver classes & support groups Central Line Placement Chemotherapy Myeloablative Myelosuppressive Conditioning Common Drugs: Melphalan, Fludarabine, Cyclophosphamide, Etoposide, Busulfan Radiation Total Body Irradiation Mini TBI Transplant Stem cell infusion administered like an RBC transfusion Cryopreserved Preserved with DMSO Can cause hemolysis Causes garlic breath Transfusion reactions Fresh Awaiting Engraftment Nausea, Vomiting, Diarrhea Mucositis May effect the entire length of GI tract May need PCA & TPN for some length of time Infections Hepatic Sinusoidal Obstruction Syndrome (SOS) Risk factors include TBI, Cytoxan, prior liver disease Can be fatal Engraftment syndrome Fever and rash presents around time of engraftment, resembles GVHD 4
Allogeneic HSCT: Post Engraftment Recovery Patients are closely followed at the transplant center for several months Acute GVHD and infection are major concerns Seen daily to once/week for medical evaluation and blood tests Nursing management of symptoms Infusion therapy as needed At day +80, patients are completely evaluated for disease state and complications and prepared for discharge home Graft vs. Host Disease (GVHD) Donor T lymphocytes (the graft) recognize the antigens and cells in the transplant recipient (the host) as foreign and mount an immunologic attack Three conditions must be present Graft must have sufficient number of competent cells Host must have antigens that are not present in the graft Host must be incapable of mounting an effective response to destroy the transplanted cells Predictive Factors for agvhd Clinical Features of Acute GVHD Donor/Host Factors HLA disparity Sex mismatch (especially female to male) Age of donor and recipient HSC Source PBSC > BM > UCB Immunomodulation Omission of adequate agvhd prophylaxis TBI recipients Skin (most common) Maculopapular rash, often beginning with palmar/planter surfaces and extending to the face, abdomen and trunk Sunburned appearance to desquamation and loss of skin integrity Gut Profuse, watery diarrhea with anorexia, nausea and vomiting Diarrhea with intestinal bleeding and crampy abdominal pain to ileus Liver Elevated alkaline phosphatase and bilirubin RUQ pain, hepatomegaly and jaundice to ascites and encephalopathy 5
Prevention of agvhd Highest degree of histocompatibility from donor (when multiple donors are available) Prophylactic immunosuppression with methotrexate, cyclosporine, mycophenolate mofetil, tacrolimus alone or in combination Selective T-cell depletion Treatment of agvhd Primary Therapy Prednisone 1-2mg/kg/day followed by taper after response (may be given as IV methylprednisone) Secondary Therapy Monoclonal antibodies ATG Sirolimus PUVA (skin) or ECP (skin, liver and gut) Prognosis of agvhd Allogeneic HSCT: Long-term Follow-Up Follow guidelines from transplant center about safe living with impaired immune function Predicted by grade of agvhd and response to initial therapy Poor responders to treatment have a high-risk of non-relapse mortality rate by one year Late complications Chronic GVHD Late infectious complications Pulmonary complications Bronchiolitis obliterans, pulmonary fibrosis Neurological complications Psychological complications Cataracts Sexual disorders (ex: dry vaginal mucosa) and impaired fertility Orthopedic complications Fragile joints due to steroids Secondary malignancy 6
Infections and HSCT Pre-engraftment : HSV, gram negative bacilli, staphylococcus epidermidis, GI-tract streptococci, candida, aspergillus Early Engraftment: candida, staphylococcus epidermidis, aspergillus, CMV, pneumocystis jiroveci Late Phase: CMV, VZV, encapsulated bacteria, aspergillus, pneumocystis jiroveci Immune reconstitution after HSCT Innate immunity usually returns by day 100 Adaptive Immunity: CD4+ helper T-cells numbers may take months to return to normal levels Serum immunoglobulins may take months to years normalize and gain full functionality Immunosuppressants and chronic GVHD further impair immune reconstitution Chronic GVHD Chronic graft versus host disease (cgvhd) is a syndrome caused by donor immune competent T cells recognizing and mounting an immune response against host cells which differ by histocompatability antigens Predictive factors for cgvhd Previous agvhd PBSC Older donor or recipient HLA disparity Resembles autoimmune or collagen vascular disorder 7
Clinical Manifestations of Chronic GVHD Oral Symptoms GI Tract Skin Liver Nails Lung Scalp & Body Hair Muscles/Fascia/Joints Eyes Hematopoietic/Immune Genitalia Treatment of cgvhd Primary Prednisone 1mg/kg/day with a slow taper after improvement usually in combination with: Daily cyclosporine or Daily tacrolimus Salvage Methotrexate Mycophenolate Mofetil Sirolimus Tacrolimus Azathioprine Infliximab Pentostatin PUVA (cutaneous agvhd) ECP (cutaneous and liver agvhd) Supportive Care in cgvhd Infection prophylaxis Symptom palliation Manage dry skin and protect from sun Artificial tears Oral care Gynecology consult Nutritional intervention PT and OT Massage Psychosocial support Prognosis of cgvhd Mortality in cgvhd is largely attributed to infection. Major morbidity is often present with extensive chronic GVHD and requires longterm therapy. 8
Factors influencing HSCT Outcomes Type of disease Disease status at time of transplant Co-morbidities Severity of GVHD Web resources for outcome statistics: www.bmtinfonet.org www.marrow.org www.cibmtr.org http://bloodcell.transplant.hrsa.gov/index.htm Summary HSCT indicated for a variety of malignant and non-malignant conditions, may be only potentially curative option for some conditions Major risks associated with HSCT in the acute and late phases are infection and GVHD Management of treatment side effects for transplant survivors can persist for years Resources: National Marrow Donor Program www.marrow.org Understanding Cancer topics www.cancer.gov Questions? Karen Anderson, MN, RN, OCN andersk@u.washington.edu Seattle Cancer Care Alliance www.seattlecca.org 9
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