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ACUTE LYMPHOBLASTIC LEUKEMIA 1 Running head: ACUTE LYMPHOBLASTIC LEUKEMIA Acute Lymphoblastic Leukemia Insert Name Here Insert Affiliation Here ACUTE LYMPHOBLASTIC LEUKEMIA 2 Acute lymphoblastic leukemia (ALL) is the one of the more prevalent forms of leukemia seen in the United States and the rest of the Western world, and is usually characterized by the presence and spread of malignant B-cells, which are leukocytes normally responsible for the creation and activation of antibodies, although a form with malignant T-cells also exists (Geyeregger et al., 2009). ALL can begin in childhood or adulthood, and it is the most common leukemia seen in children, while the adult form is somewhat rare (Leukemia- Acute Lymphocytic, 2010). This disease begins in the bone marrow, where leukocytes are produced, and spreads to other parts of the body integral to the immune system, including the lymph nodes, spleen, liver, nervous system, and, in males, the testicles; this disease is distinguished from lymphomas by the fact that lymphomas normally start in the lymph nodes, and spread to the bone marrow (Leukemia- Acute Lymphocytic, 2010). Unlike many forms of cancer, which are difficult to treat, ALL has an excellent survival rate, especially in children. There are genetic differences in the two forms of ALL, but phenotypical differences present as well. Childhood-onset ALL tends to exhibit a greater degree of cancerous T-cells, higher levels of hemoglobin, and fewer lymphomatous components (Nachman, 2005). Adults with ALL tend to display more heterogenous features, such as the rapid metastasis of the cancer to multiple tissues, and tend to have comorbidity with other diseases, which are both factors that complicate the treatment outlook (Nachman, 2005). Adult onset ALL usually involves uncontrolled reproduction of T-cells, instead of the more common B-cell variety, and is also characterized by extramedullary symptoms, and a propensity to affect men more often than women (Acute Lymphoblastic Leukemia, 2005). ACUTE LYMPHOBLASTIC LEUKEMIA 3 Diagnosis of ALL involves more than just the cataloguing of symptoms. The symptoms presented by this cancer are non-specific, and could signal the onset of any number of diseases. These symptoms can include fever, sweating, fatigue, weakness, loss of appetite, weight loss, susceptibility to infection, and a tendency to bruise or bleed easily (Leukemia- Acute Lymphocytic, 2010). Most of these symptoms are the result of a lack of blood cells, as the cancerous bone marrow cells deny space to cells producing normal platelets, erythrocytes, and leukocytes (Leukemia- Acute Lymphocytic, 2010). The way in which ALL affects other body systems can cause other symptoms, as well as reveal opportunities for diagnosis. If ALL manages to spread to the lymph nodes, it normally results in swelling, which can be palpated near the surface of the skin, or detected with MRI or CT scans if they are located deep within the abdomen (Leukemia- Acute Lymphocytic, 2010). If affected leukocytes accrete near the spinal cord, they can create central nervous system-related symptoms including seizures, vomiting, weakness, blurred vision, and balance problems. The 20 percent of ALL cases that affect T-cells usually spread to the thymus gland, causing swelling that can create pressure on the trachea, leading to wheezing and breathing difficulties (LeukemiaAcute Lymphocytic, 2010). Diagnosis can be obtained through a variety of methods. Bone marrow is obtained both by aspiration and biopsy, and is used to screen for the presence of cancerous cells (LeukemiaAcute Lymphocytic, 2010). Blood samples may also be drawn to check for cancerous leukocytes, and cerebrospinal fluid may be tapped in order to determine if the cancer has spread to the central nervous system. Generally, these tests look for an abundance of lymphoblasts, or immature leukocytes, and a lack of platelets and erythrocytes (Leukemia- Acute Lymphocytic, 2010). Lymphoblasts are also searched for in bone marrow tests; the presence of 20 to 30 percent ACUTE LYMPHOBLASTIC LEUKEMIA 4 lymphoblasts is required for a diagnosis of ALL; normally, lymphoblasts only account for around 5 percent of white blood cells in bone marrow (Leukemia- Acute Lymphocytic, 2010).While lymph node biopsies are often performed for other forms of cancers, they are only performed if the physician suspects that the ALL has spread to the lymph nodes (LeukemiaAcute Lymphocytic, 2010). In order to confirm that the cells discovered are cancerous, screening for certain chromosomal or genetic patterns may be performed by in-situ hybridization, or specific antigen patterns may be detected by immunochemistry (Leukemia- Acute Lymphocytic, 2010). There is a strong genetic component to this disease, with the Philadelphia chromosome serving as a predictor for adult onset ALL, which has a poorer outcome, regardless of the type of treatment used (Nachman, 2005). Pieces of chromosomes that have been duplicated or transposed are quite common in childhood ALL, whereas they are less frequently seen in the adult-onset form (Mullighan, 2009). In the adult form of ALL, instead, the genetic changes often seen involve the Philadelphia chromosome and deletions and lesions on genes, some of which seem to occur regularly enough to predict the way that ALL will manifest in patients (Mullighan, 2009). These changes, however, are not the entire cause of this leukemia; in animal models, the presence of these characteristic alterations do not create cases of leukemia, so there must be other environmental or biological events necessary to trigger the development of ALL (Mullighan , 2009). Some researchers have guessed that at least one of the gene alterations codes for a mutation or reduction in expression of a tumor suppressor gene, which would certainly contribute to the spread of ALL without being its origin (Mullighan, 2009). Other affected genes have been found to be involved in apoptosis, cell cycle control, and development of lymphoid cells. ACUTE LYMPHOBLASTIC LEUKEMIA 5 Although acute lymphoblastic leukemia was once extremely fatal, survival rates have improved in the last few decades, and medical advances have succeeded in about 75 percent of people with ALL obtaining long-term event-free survival rates (Moricke et al., 2008). Due to the diffuse nature of ALL, where cancer cells are not localized to a particular part of the body as they may be with other cancers, chemotherapy is the preferred form of treatment, with radiation therapy and surgery being used only under special circumstances (Leukemia- Acute Lymphocytic, 2010). Chemotherapy differs for children and adults with this disease; due to studies showing that the anticancer agents vincristine and L-asparaginase are toxic to older patients, they are generally only used in children, as a form of continuous therapy with steroids (Nachman, 2005). Chemotherapy is usually intensified in the pediatric treatment regimen shortly after the beginning of therapy, and at the end, which has been reported to yield more optimal results (Nachman, 2005). Older adults, on the other hand, have intermittent high-dose chemotherapy with myelosuppressive medications (Nachman, 2005). These medications often include tyrosine kinase inhibitors, which seem to have the best treatment results, and giving the patient the best chance for bone marrow transplant success after chemotherapy (Vitale, Grammatico, Capria, Fiocchi, Foa, & Meloni, 2009). Studies performed on young adults that could be treated via either method showed increased recovery rates when treated using the pediatric method of continuous chemotherapy, which could be part of the reason that the survival rate for ALL favors the childhood form over the adult form. The success of chemotherapy can be predicted by a test measuring prednisone response; a “good response” can predict a positive treatment outcome around 90 percent of the time, other responses to the test predict only a 50 percent chance of being cured (Moricke et al., 2008). Combinations of different chemotherapy drugs are being tested to try and reduce relapse rate in ACUTE LYMPHOBLASTIC LEUKEMIA 6 at-risk groups with ALL, and interleukin-based therapy may soon be employed for this purpose as well (Geyeregger et al., 2009). If the cancer has spread to bone, radiation therapy may be given as an adjunct to chemotherapy. Additionally, in adults, antibiotics may be given in conjunction with, or following, chemotherapy, since the person’s weakened immune system is less able to cope with infection; newer studies have shown that certain hormones like granulocyte stimulating factors can accomplish the same purpose of boosting the counts of certain immune system cells, specifically, neutrophils (Welte et al., 1996). If doctors are successful in forcing the cancer into remission after chemotherapy, a bone marrow transplant to replace the dead marrow cells is sometimes the next step. Bone marrow transplants in adults are more common, and generally come from the patient themselves, from undiseased marrow, although they can come from an outside source as well (Nachman, 2005). In contrast, children with ALL generally only receive bone marrow transplants if they are shown to have the presence of the Philadelphia chromosome, and, in this case, they would receive bone marrow from a matched sibling donor (Nachman, 2005). In many cases, transplants that come from another person are preferred, since while the new leukocytes produced by the body’s own stem cells won’t recognize cancerous leukocytes as foreign and attack them, leukocytes from transplanted marrow will, leading to a “graft vs. leukemia” effect (Leukemia- Acute Lymphocytic, 2010). Bone marrow transplants are about as successful, providing a 60 percent survival rate of more than 5 years, whether intermittent or continuous chemotherapy has preceded it (Chang et al., 2008). Bone marrow transplants are often performed if the bone has been exhibiting symptoms of pain, so that doctors can use radiation therapy on the area as an adjunct without jeopardizing leukocyte production to an extreme degree (Leukemia- Acute Lymphocytic, 2010). Although not as widespread a practice as the transplant of bone marrow, ACUTE LYMPHOBLASTIC LEUKEMIA 7 transplant of unrelated blood cord cells have yielded survival rates that are roughly equivalent (Jacobsohn, Hewlett, Ranalli, Seshadri, Duerst, & Kletzel, 2004). The success seen in the combinatorial approach to acute lymphocytic leukemia involving both chemotherapy and bone marrow or blood cord cell transplantation has led researchers to reverse their opinion that diffuse cancers could be incurable. Although more research must be performed in order to raise the survival rates of those that manifest this cancer in adulthood, research made in the direction of immunotherapy may yield positive results with fewer side effects. Acute lymphocytic leukemia has allowed researchers to delineate links between genetics and the risk of cancer, since it shows a much stronger, and much more clearly mapped, relationship than many other cancers. Although this disease remains difficult to treat, it is certainly not impossible, and successes in this realm have inspired researchers of other forms of cancer, that have revised their approach to chemotherapy in accordance with ALL treatment methods. ACUTE LYMPHOBLASTIC LEUKEMIA References Acute Lymphoblastic Leukemia. (2005). Medscape. Retrieved from http://www.medscape.com/viewarticle/498526_2 Chang, J. E., Medlin, S.C., Kahl, B.S., Longo, W.L., Williams, E.C., Lionberger, J., . . . kett, M.B.(2008). Augmented and standard Berlin-Frankfurt-Munster chemotherapy for treatment of adult acute lymphoblastic leukemia. Leukemia & Lymphoma, 49(12), 2298-2307. Geyeregger, R., Shehata, M., Zeyda, M., Kiefer, F.W., Stuhlmeyer, K.M., Porpaczy, E., Zlabinger,G.J., Jager, U., & Stulnig, T.M. (2009). Liver X receptors interfere with cytokine-induced proliferation and cell survival in normal and leukemic lymphocytes. Journal of Leukocyte Biology, 86, 1039-1048. Jacobsohn, D.A., Hewlett, B., Ranalli, M., Seshadri, R., Duerst, R., & Kletzel. M. (2004). Bone Marrow Transplantation, 34, 901-907. Leukemia, Acute Lymphocytic. (2010). American Cancer Society. Retrieved from http://www.cancer.org/Cancer/LeukemiaAcuteLymphocyticALLinAdults/DetailedGuide/leukemia-acute-lymphocytic-whatis-all Moricke, A., Reiter, A., Zimmerman, M., Gadner, H., Stanulla, M., Dordelmann, M., . . . Schrappe, M. (2008). Risk-adjusted therapy of acute lymphoblastic leukemia can decrease treatment burden and improve survival: Treatment results of 2169 Unselected pediatric and adolescent patients enrolled in the trial ALL-BFM 95. Blood, 111, 4477-4489. Mullighan, C.G. (2009). Genomic analysis of acute leukemia. International Journal of 8 ACUTE LYMPHOBLASTIC LEUKEMIA Laboratory Hematology, 31, 384-397. Nachman, J. (2005). Clinical characteristics, biologic features, and outcome for young adult patients with acute lymphoblastic leukemia. British Journal of Hematology, 130, 166-173. Vitale, A., Grammatico, S., Capria, S., Fiocchi, C., Foa, R., & Meloni, G. (2009). Advanced Philadelphia chromosome-positive leukemia patients relapsed after treatment with tyrosine kinase inhibitors. Haematologica, 94(10), 1471-1473. Welte, K., Reiter, A., Mempel, K., Pfetch, M., Schwab, G., Schrappe, M., & Riehm, H. (1996). A randomized phase-III study of granulocyte colony stimulating factor in children with high-risk acute lymphoblastic leukemia. Blood, 87(8), 3143-3150. 9
