A Doctor, a Mutation and a Potential Cure for AIDS


The startling case of an AIDS patient who underwent a bone marrow transplant to treat leukemia is stirring new hope that gene-therapy strategies on the far edges of AIDS research might someday cure the disease.

The patient, a 42-year-old American living in Berlin, is still recovering from his leukemia therapy, but he appears to have won his battle with AIDS. Doctors have not been able to detect the virus in his blood for more than 600 days, despite his having ceased all conventional AIDS medication. Normally when a patient stops taking AIDS drugs, the virus stampedes through the body within weeks, or days.

[Dr. Gero Hutter] Sixten Koerper

Dr. Gero Hütter isn't an AIDS specialist, but he 'functionally cured' a patient, who shows no sign of the disease.

"I was very surprised," said the doctor, Gero Hütter.

The breakthrough appears to be that Dr. Hütter, a soft-spoken hematologist who isn't an AIDS specialist, deliberately replaced the patient's bone marrow cells with those from a donor who has a naturally occurring genetic mutation that renders his cells immune to almost all strains of HIV, the virus that causes AIDS.

The development suggests a potential new therapeutic avenue and comes as the search for a cure has adopted new urgency. Many fear that current AIDS drugs aren't sustainable. Known as antiretrovirals, the medications prevent the virus from replicating but must be taken every day for life and are expensive for poor countries where the disease runs rampant. Last year, AIDS killed two million people; 2.7 million more contracted the virus, so treatment costs will keep ballooning.

While cautioning that the Berlin case could be a fluke, David Baltimore, who won a Nobel prize for his research on tumor viruses, deemed it "a very good sign" and a virtual "proof of principle" for gene-therapy approaches. Dr. Baltimore and his colleague, University of California at Los Angeles researcher Irvin Chen, have developed a gene therapy strategy against HIV that works in a similar way to the Berlin case. Drs. Baltimore and Chen have formed a private company to develop the therapy.

Back in 1996, when "cocktails" of antiretroviral drugs were proved effective, some researchers proposed that all cells harboring HIV might eventually die off, leading to eradication of HIV from the body -- in short, a cure. Those hopes foundered on the discovery that HIV, which integrates itself into a patient's own DNA, hides in so-called "sanctuary cells," where it lies dormant yet remains capable of reigniting an infection.

But that same year, researchers discovered that some gay men astonishingly remained uninfected despite engaging in very risky sex with as many as hundreds of partners. These men had inherited a mutation from both their parents that made them virtually immune to HIV.

The mutation prevents a molecule called CCR5 from appearing on the surface of cells. CCR5 acts as a kind of door for the virus. Since most HIV strains must bind to CCR5 to enter cells, the mutation bars the virus from entering. A new AIDS drug, Selzentry, made by Pfizer Inc., doesn't attack HIV itself but works by blocking CCR5.

About 1% of Europeans, and even more in northern Europe, inherit the CCR5 mutation from both parents. People of African, Asian and South American descent almost never carry it.

Dr. Hütter, 39, remembered this research when his American leukemia patient failed first-line chemotherapy in 2006. He was treating the patient at Berlin's Charité Medical University, the same institution where German physician Robert Koch performed some of his groundbreaking research on infectious diseases in the 19th century. Dr. Hütter scoured research on CCR5 and consulted with his superiors.

Finally, he recommended standard second-line treatment: a bone marrow transplant -- but from a donor who had inherited the CCR5 mutation from both parents. Bone marrow is where immune-system cells are generated, so transplanting mutant bone-marrow cells would render the patient immune to HIV into perpetuity, at least in theory.

There were a total of 80 compatible blood donors living in Germany. Luckily, on the 61st sample he tested, Dr. Hütter's colleague Daniel Nowak found one with the mutation from both parents.

To prepare for the transplant, Dr. Hütter first administered a standard regimen of powerful drugs and radiation to kill the patient's own bone marrow cells and many immune-system cells. This procedure, lethal to many cells that harbor HIV, may have helped the treatment succeed.

The transplant specialists ordered the patient to stop taking his AIDS drugs when they transfused the donor cells, because they feared the powerful drugs might undermine the cells' ability to survive in their new host. They planned to resume the drugs once HIV re-emerged in the blood.

But it never did. Nearly two years later, standard tests haven't detected virus in his blood, or in the brain and rectal tissues where it often hides.

The case was presented to scientists earlier this year at the Conference on Retroviruses and Opportunistic Infections. In September, the nonprofit Foundation for AIDS Research, or amFAR, convened a small scientific meeting on the case. Most researchers there believed some HIV still lurks in the patient but that it can't ignite a raging infection, most likely because its target cells are invulnerable mutants. The scientists agreed that the patient is "functionally cured."

Caveats are legion. If enough time passes, the extraordinarily protean HIV might evolve to overcome the mutant cells' invulnerability. Blocking CCR5 might have side effects: A study suggests that people with the mutation are more likely to die from West Nile virus. Most worrisome: The transplant treatment itself, given only to late-stage cancer patients, kills up to 30% of patients. While scientists are drawing up research protocols to try this approach on other leukemia and lymphoma patients, they know it will never be widely used to treat AIDS because of the mortality risk.

There is a potentially safer alternative: Re-engineering a patient's own cells through gene therapy. Due to some disastrous failures, gene therapy now "has a bad name," says Dr. Baltimore. In 1999, an 18-year-old patient died in a gene therapy trial. Even one of gene therapy's greatest successes -- curing children of the inherited "bubble boy" disease -- came at the high price of causing some patients to develop leukemia.

[Chart]

Gene therapy also faces daunting technical challenges. For example, the therapeutic genes are carried to cells by re-engineered viruses, and they must be made perfectly safe. Also, most gene therapy currently works by removing cells, genetically modifying them out of the body, then transfusing them back in -- a complicated procedure that would prove too expensive for the developing world. Dr. Baltimore and others are working on therapeutic viruses they could inject into a patient as easily as a flu vaccine. But, he says, "we're a long way from that."

Expecting that gene therapy will eventually play a major role in medicine, several research groups are testing different approaches for AIDS. At City of Hope cancer center in Duarte, Calif., John Rossi and colleagues actually use HIV itself, genetically engineered to be harmless, to deliver to patients' white blood cells three genes: one that inactivates CCR5 and two others that disable HIV. He has already completed the procedure on four patients and may perform it on another.

One big hurdle: doctors can't yet genetically modify all target cells. In theory, HIV would kill off the susceptible ones and, a victim of its own grim success, be left only with the genetically engineered cells that it can't infect. But so far that's just theory. All Dr. Rossi's patients remain on standard AIDS drugs, so it isn't yet known what would happen if they stopped taking them.

In 1989, Dr. Rossi had a case eerily similar to the one in Berlin. A 41-year-old patient with AIDS and lymphoma underwent radiation and drug therapy to ablate his bone marrow and received new cells from a donor. It is not known if those cells had the protective CCR5 mutation, because its relation to HIV hadn't been discovered yet. But after the transplant, HIV disappeared from the patient's blood. The patient died of his cancer 47 days after the procedure. Autopsy tests from eight organs and the tumor revealed no HIV.

Symptoms of hypercalcaemia


It is not always easy for a doctor to spot that you have hypercalcaemia. You may not have any specific symptoms. It may be that you just feel unwell or a bit “off colour”. And the severity of your symptoms doesn’t always match up to the calcium level in your blood. People with a mildly high calcium level can have very severe symptoms, and people with a very high calcium level may only have mild symptoms. Many of the symptoms are common in the advanced stages of cancer, even in people who do not have hypercalcaemia.
All this can make it difficult for your doctor to pick hypercalcaemia up. But generally speaking the first signs include

  • Extreme tiredness (fatigue) and lethargy
  • Feeling weak
  • Not wanting to eat much (anorexia)
  • Constipation
  • Loss of concentration and interest in doing things
  • Mild confusion

If the hypercalcaemia is not treated then the symptoms become much worse and can include

  • Feeling and being sick
  • Drowsiness
  • Passing large amounts of urine
  • Feeling very thirsty
  • Dehydration
  • Confusion
  • Agitation
  • Muscle spasms, tremors.
  • Bone pain and weakness
  • Irregular heart beat
  • Difficulty thinking and speaking clearly
  • Coma and finally death, if not treated

Because calcium plays a role in the normal working of the brain and spinal cord, patients with severe hypercalcaemia may also

  • Have fits
  • Be unable to coordinate muscle movement which can affect walking, talking and eating
  • Have changes in personality
  • Have hallucinations

If you have hypercalcaemia, you will need treatment from your specialist. It can be a life threatening condition if it is not treated. You may have to spend a day or two in hospital to get your calcium levels down.

Skin cancer patient 'cured' using his own blood cells



A 52-year-old man with advanced melanoma, the lethal form of skin cancer, has been successfully treated using just his own blood.

The development has been hailed by British experts as an "exciting advance" in the use of cancer immunotherapy, which harnesses the body's immune system to fight the disease.

Researchers in the US who were treating the patient extracted white blood cells, the key component of the immune system, and grew one type – the infection-fighting CD4+ T cells – in the laboratory. The cloned T cells, which had been vastly expanded, were then reinfused to the patient to fight the cancer.

The man was diagnosed with stage four melanoma, when death normally occurs within months. The cancer, triggered by sunburn, started in a mole on the skin and had spread to a lymph node in his groin and to his lungs. But, two months after the T-cell treatment, scans revealed no tumour. Two years later, when he was last checked, the man remained free of the disease. He had previously had surgery and drug treatment without any response.

Melanoma is the deadliest form of skin cancer, causing 1,800 deaths a year in the UK. It is the fastest rising cancer, with cases up 40 per cent in the past decade. The cancer is caused by intermittent, intense exposure to the sun. The typical victim is the office worker who spends two weeks broiling on a beach each summer. Adults with fair skin who suffered severe sunburn before the age of 15 are at highest risk.

Cassian Yee, who carried out the experimental treatment with colleagues at the Fred Hutchinson Cancer Research Centre in Seattle, said that one in four late-stage melanoma patients had the same type of immune system and tumour antigen as the patient, for whom the therapy could be effective. But he warned that they had only proved its success in one patient. "We were surprised by the anti-tumour effect of these CD4+ T cells and its duration of response. For this patient we were successful, but we would need to confirm the effectiveness of the therapy in a larger study."

The findings are published in The New England Journal of Medicine, which describes them in a commentary as a "novel strategy" which points to a "feasible new direction" for treatment.

Louis Weiner, the author of the commentary and director of the Lombardi Comprehensive Cancer Centre in Washington, said that although it was too early to be sure of the significance of this one case, the indications were that it will give a substantial boost to the technique of cancer immunotherapy. "I suspect that if the destination is not yet at hand, it is in sight. The endgame has begun," he said.

Cancer immunotherapy is a growing area of research which has proved successful in some other cancers, including kidney cancer. The aim is to developless toxic treatments which are at least as effective as chemotherapy and radiation.

Ed Yong, a health information manager at Cancer Research UK, said: "While it's always good news when anyone with cancer gets the all-clear, this treatment will need to be tested in large clinical trials to work out how widely it could be used."

Professor Peter Johnson, Cancer Research UK's chief clinician and a consultant in Southampton, said: "Although the technique is complex and difficult to use for all but a few patients, the principle that someone's own immune cells can be made to work in this way is very encouraging."

How immunotherapy works

* Cancer immunotherapy is the technique of harnessing the body's immune system to attack the cancer.

* The immune system normally responds to threats to the body by distinguishing between itself and foreign invaders.

* In the case of cancer, this is difficult because most tumours consist of the body's own cells growing out of control.

* However, many cancer cells display unusual antigens or receptors on their surface that allows them to be identified.

* Antibodies and cancer vaccines to stimulate the immune system are being developed to attack these tumour cells.

Cancer blood tests: Lab tests used in cancer diagnosis


Cancer blood tests and other laboratory tests may help your doctor make a cancer diagnosis. Reduce your anxiety by learning about cancer blood tests and how they're used.


Blood tests alone can rarely, if ever, show the presence or absence of cancer. If your doctor suspects you may have cancer, he or she may order certain cancer blood tests or other laboratory tests, such as an analysis of your urine, to help guide the diagnosis. While cancer blood tests generally can't tell whether you have cancer or some other noncancerous condition, they can give your doctor clues about what's going on inside your body.

Because your doctor has ordered cancer blood tests or other laboratory tests to look for signs of cancer doesn't mean that a cancer diagnosis has been made and you have cancer. Find out what your doctor might be looking for when cancer blood tests are done.

What your doctor is looking for

Your doctor may order cancer blood tests or other types of laboratory tests after conducting a physical exam. The signs and symptoms you report may give your doctor clues about what could be wrong. Tests to analyze your blood, urine or body tissues may give your doctor further information about your condition.

Blood and urine samples are analyzed in a lab. If the doctor finds cancer cells, too many or too few cells of a particular type, or abnormal types of cells, or if any of various other substances are detected, it may indicate cancer. For example, if you have leukemia — a blood cancer — cancerous white blood cells can be seen under a microscope. A common blood test called complete blood count (CBC) measures the amount of various types of blood cells in a sample of your blood. CBC may give your doctor an idea of what's causing your signs and symptoms.

Blood and urine samples may also be tested for various substances, called tumor markers, which may indicate cancer. Tumor markers are typically chemicals made by tumor cells, but tumor makers are also produced by some normal cells in your body.

For instance, prostate-specific antigen (PSA) is a tumor marker sometimes used to screen men for prostate cancer, though this is somewhat controversial. Any man who hasn't had his prostate removed has a detectable level of PSA in his blood. An abnormally elevated PSA level may prompt your doctor to recommend further testing for prostate cancer. Another tumor marker is cancer antigen 125 (CA 125), which may be elevated in women with ovarian cancer, though levels can be elevated in people with other types of cancer and with many benign conditions. A high CA 125 result may prompt your doctor to recommend further testing to determine the cause.

What the results mean

Test results must be interpreted carefully because several factors can influence test outcomes, such as variations in your own body or even what you eat. In addition, it's important to remember that noncancerous conditions can sometimes cause abnormal test results. And, in other cases, cancer may be present even though the blood test results are normal.

Your doctor usually uses your test results to determine whether your levels fall within a normal range. Or your doctor may compare your results with those from past tests.

What happens next

Though blood and urine tests can help give your doctor clues, other tests are usually necessary to make the diagnosis. For most forms of cancer, a biopsy — a procedure to obtain a sample of suspicious cells for testing — is usually necessary to make a definitive diagnosis.

In some cases, tumor marker levels are monitored over time. Your doctor may schedule follow-up testing in a few months. Cancer blood markers are most helpful after your cancer diagnosis. Your doctor may use these tests to determine whether your cancer is responding to treatment or whether your cancer is growing.

Cancer drugs my build and not tear down blood vessels


Scientists have thought that one way to foil a tumor from generating blood vessels to feed its growth – a process called angiogenesis – was by creating drugs aimed at stopping a key vessel growth-promoting protein. But now the opposite seems to be true.

Researchers at the Moores Cancer Center at the University of California, San Diego (UCSD) in La Jolla have found evidence that blocking that protein target, called VEGF, or vascular endothelial growth factor, doesn't really halt the process at all. Instead, cutting levels of VEGF in a tumor actually props up existing blood vessels, making them stronger and more normal, and in some cases the tumors larger. But as a result, the tumor is more vulnerable to the effects of chemotherapy drugs.

In a paper appearing online November 9, 2008 in the journal Nature, David Cheresh, Ph.D., professor and vice chair of pathology at the UC San Diego School of Medicine and the Moores UCSD Cancer Center and his co-workers mimicked the action of anti-angiogenesis drugs by genetically reducing VEGF levels in mouse tumors and inflammatory cells in various cancers, including pancreatic cancer. They also used drugs to inhibit VEGF receptor activity. In every case, blood vessels were made normal again.

The researchers say the findings provide an explanation for recent evidence showing that anti-angiogenesis drugs such as Avastin can be much more effective when combined with chemotherapy. The results may lead to better treatment strategies for a variety of cancers.

"We've discovered that when anti-angiogenesis drugs are used to lower the level of VEGF within a tumor, it's not so much a reduction in the endothelial cells and losing blood vessels as it is an activation of the tumor blood vessels supporting cells," said Cheresh. "This enables vessels to mature, providing a conduit for better drug delivery to the tumor. While the tumors initially get larger, they are significantly more sensitive to chemotherapeutic drugs."

As a result, Cheresh said, the findings may provide a new strategy for treating cancer. "It means that chemotherapy could be timed appropriately. We could first stabilize the blood vessels, and then come in with chemotherapy drugs that are able to treat the cancer."

Co-author Randall Johnson, Ph.D., professor of biology at UCSD, Cheresh and their colleagues showed in a related paper in the same journal that tumors were more susceptible to drugs after inflammatory cells lost the ability to express VEGF.

"These two papers define a new mechanism of action for VEGF and for anti-angiogenesis drugs," Cheresh said. "It appears that the drugs, in shutting down VEGF activity, are actively maturing blood vessels, causing them to become stable and more normal, as opposed to reducing blood vess

How can you cope with low blood cell counts?


Take steps to keep your body healthy when you have low blood cell counts. For example:

  • Eat a balanced diet. Your body needs all the vitamins and nutrients it can get to heal itself during and after your treatment. Eat plenty of fruits and vegetables. If treatment complications make eating difficult — for example, if you experience nausea and vomiting or mouth sores — experiment to find foods you can tolerate.
  • Avoid injury. Many everyday activities put you at risk of cuts and scrapes. A low platelet count makes even minor abrasions serious. A low white blood cell count can turn a small cut into a starting point for a serious infection. Use an electric shaver rather than a razor to avoid nicks. Ask someone else to cut up food in the kitchen. Be gentle when brushing your teeth and blowing your nose.
  • Avoid germs. It's impossible to avoid all germs, but avoid unnecessary exposure when you can. Wash your hands frequently. Avoid people who are sick and stay away from crowds. Have someone else clean the litter box, bird cage or fish tank. Don't eat raw meat or eggs.
  • Rest. If you feel tired, stop and rest. Your body is working hard to fight the cancer cells and heal the healthy cells damaged by your treatment. Don't feel guilty about taking time for yourself and asking others to help you. Plan your most important activities for the time of day when you feel most energetic.

Talk to your health care team about other ways you can cope with low blood cell counts.

What causes low blood cell counts?


Cancer-related causes of low blood cell counts include:

  • Chemotherapy. Certain chemotherapy drugs can damage your bone marrow — the spongy material found in your bones. Your bone marrow makes blood cells, which grow rapidly, making them very sensitive to the effects of chemotherapy. Chemotherapy kills many of the cells in your bone marrow, but the cells recover with time. Your doctor can tell you whether your specific chemotherapy treatment and dose will put you at risk of low blood cell counts.
  • Radiation therapy. If you receive radiation therapy to large areas of your body and especially to the large bones that contain the most bone marrow, such as your pelvis, legs and torso, you might experience low levels of red and white blood cells. Radiation therapy is less likely to have a significant effect on your platelet count. Radiation combined with chemotherapy increases your risk of low blood cell counts.
  • Cancers of the blood and bone marrow. Blood and bone marrow cancers, such as leukemia, attack different parts of your bone marrow. The cancerous cells can displace other cells in your bone marrow, making it difficult for your bone marrow to produce the blood cells your body needs.
  • Cancers that spread (metastasize). Cancer cells that break off from a tumor can spread to other parts of your body, including your bone marrow. Some examples of cancers that can spread to bone marrow include breast cancer, lung cancer and prostate cancer. This is an unusual cause of low blood counts.

What's measured in a blood cell count?


When checking your blood cell count, your doctor is looking at the numbers and types of:

  • White blood cells. These cells help your body fight infection. A low white blood cell count (leukopenia) leaves your body more open to infection. And if an infection does develop, your body may be unable to fight it off.
  • Red blood cells. Red blood cells carry oxygen throughout your body. Your red blood cells' ability to carry oxygen is measured by the amount of hemoglobin in your blood. If your level of hemoglobin is low, you're anemic and your body works much harder to supply oxygen to your tissues. This can make you feel fatigued and short of breath.
  • Platelets. Platelets help your blood clot. A low platelet count (thrombocytopenia) means your body can't stop itself from bleeding.

If you're undergoing certain cancer treatments that could cause low blood cell counts, your doctor will likely monitor your blood cell counts regularly using a test called a complete blood count (CBC). Low blood cell counts are detected by examining a blood sample taken from a vein in your arm.

What's being countedWhat's normalWhat's low
White blood cells (WBC)5,000-10,000Below normal, especially below 1,000
Hemoglobin14.5-18 for men
12-16 for women		Below 10
Platelets150,000-450,000Below 50,000

What does the future hold for patients with leukemia?


Doctors all over the country are conducting many types of clinical trials. These are research studies in which people take part voluntarily. Studies include new methods of treatment and supportive care for patients with leukemia. Research already has led to advances, and researchers continue to search for more effective approaches.

Patients who join these studies have the first chance to benefit from treatments that have shown promise in earlier research. They also make an important contribution to medical science by helping doctors learn more about the disease. Although clinical trials may pose some risks, researchers take very careful steps to protect their patients.

Researchers are testing new biological therapies and new anticancer drugs, doses, and treatment schedules. They also are working with various drugs and with combinations of drugs, biological therapy, radiation therapy, and stem cell transplantation.

Patients who are interested in being part of a clinical trial should talk with their doctor. They may want to read the NCI booklet Taking Part in Cancer Treatment Research Studies. It explains how clinical trials are carried out and explains their possible benefits and risks. NCI's Web site includes a section on clinical trials at http://www.cancer.gov/clinicaltrials. This section of the Web site provides general information about clinical trials. It also offers detailed information about ongoing studies of leukemia treatment. The Cancer Information Service at 1-800-4-CANCER can answer questions and provide information about clinical trials.

What resources are available to patients with leukemia?

National Cancer Institute booklets

National Cancer Institute (NCI) publications can be ordered by writing to the address below, and some can be viewed and downloaded from http://cancer.gov/publications on the Internet.

Publications Ordering Service
National Cancer Institute
Suite 3036A
6116 Executive Boulevard, MSC 8322
Bethesda, MD 20892-8322

In addition, people in the United States and its territories may order these and other NCI booklets by calling the Cancer Information Service at 1-800-4-CANCER. They may also order many NCI publications on-line at http://cancer.gov/publications.

National Cancer Institute information resources

You may want more information for yourself, your family, and your doctor. The following National Cancer Institute (NCI) services are available to help you.

Telephone

Cancer Information Service (CIS)
Provides accurate, up-to-date information on cancer to patients and their families, health professionals, and the general public. Information specialists translate the latest scientific information into understandable language and respond in English, Spanish, or on TTY equipment.

Toll-free: 1-800-4-CANCER (1-800-422-6237)
TTY (for deaf and hard of hearing callers): 1-800-332-8615

Candlelighters Childhood Cancer Foundation

Candlelighters is a national organization of parents whose children have or have had cancer. It operates a patient information service and publishes newsletters and other materials for parents and young people. Local chapters sponsor family support groups. The national office, at 1-800-366-CCCF (1-800-366-2223), can supply the telephone numbers of local chapters.

Leukemia Society of America (LSA)

The Leukemia Society of America supports cancer research and provides information and financial help to patients with leukemia. It also offers support groups for patients and their families and provides referrals to other sources of help in the community. Publications are available by calling 1-800-955-4LSA (1-800-955-4572) toll free. For information about services offered in local areas, call the number listed under Leukemia Society of America in the white pages of the telephone book.

What are the side effects of treatment for leukemia?


Because cancer treatment may damage healthy cells and tissues, unwanted side effects are common. Specific side effects depend on many factors, including the type and extent of the treatment. Side effects may not be the same for each person, and they may even change from one treatment session to the next. Before treatment starts, health care providers will explain possible side effects and suggest ways to manage them. For additional information, please read the Chemotherapy and Cancer Treatment, Coping With Side Effects article.

Chemotherapy

The side effects of chemotherapy depend mainly on the specific drugs and the dose. In general, anticancer drugs affect cells that divide rapidly, especially leukemia cells. Chemotherapy can also affect other rapidly dividing cells:

  • Blood cells: These cells fight infection, help the blood to clot, and carry oxygen to all parts of the body. When blood cells are affected, patients are more likely to get infections, may bruise or bleed easily, and may feel very weak and tired.


  • Cells in hair roots: Chemotherapy can lead to hair loss. The hair grows back, but the new hair may be somewhat different in color and texture.


  • Cells that line the digestive tract: Chemotherapy can cause mouth and lip sores, nausea and vomiting, diarrhea, and poor appetite. Many of these side effects can be controlled with drugs.

Some anticancer drugs can affect a patient's fertility. Women may have irregular menstrual periods or periods may stop altogether. Women may have symptoms of menopause, such as hot flashes and vaginal dryness. Men may stop producing sperm. Because these changes may be permanent, some men have their sperm frozen and stored before treatment. Most children treated for leukemia appear to have normal fertility when they grow up. However, depending on the drugs and doses used and the age of the patient, some boys and girls may be infertile when they mature.

Because targeted therapy (sometimes used for chronic myeloid leukemia) affects only leukemia cells, it causes fewer side effects than most other anticancer drugs. However, Gleevec may cause patients to retain water. This may cause swelling or bloating.

Biological therapy

The side effects of biological therapy differ with the types of substances used, and from patient to patient. Rashes or swelling where the biological therapy is injected are common. Flu-like symptoms also may occur. The health care team may monitor the blood for signs of anemia and other problems.

Radiation therapy

Radiation therapy may cause patients to become very tired as treatment continues. Resting is important, but doctors usually advise patients to try to stay as active as they can. In addition, when patients receive radiation therapy, it is common for their skin to become red, dry, and tender in the treated area. Other side effects depend on the area of the body that is treated. If chemotherapy is given at the same time, the side effects may be worse. The doctor can suggest ways to ease these problems.

Stem cell transplantation

Patients who have stem cell transplantation face an increased risk of infection, bleeding, and other side effects because of the large doses of chemotherapy and radiation they receive. In addition, graft-versus-host disease (GVHD) may occur in patients who receive stem cells from a donor's bone marrow. In GVHD, the donated stem cells react against the patient's tissues. Most often, the liver, skin, or digestive tract is affected. GVHD can be mild or very severe. It can occur any time after the transplant, even years later. Steroids or other drugs may help.

The NCI offers a fact sheet called "Questions and Answers About Bone Marrow Transplantation and Peripheral Blood Stem Cell Transplantation." It is available on the Internet at http://cancer.gov/publications. Also, information specialists at the NCI's Cancer Information Service at 1-800-4-CANCER can send this fact sheet and answer questions about stem cell transplantation.

What are symptoms of leukemia?


Like all blood cells, leukemia cells travel through the body. Depending on the number of abnormal cells and where these cells collect, patients with leukemia may have a number of symptoms.

Common symptoms of leukemia:

  • Fevers or night sweats


  • Frequent infections


  • Feeling weak or tired


  • Headache


  • Bleeding and bruising easily (bleeding gums, purplish patches in the skin, or tiny red spots under the skin)


  • Pain in the bones or joints


  • Swelling or discomfort in the abdomen (from an enlarged spleen)


  • Swollen lymph nodes, especially in the neck or armpit


  • Weight loss

Such symptoms are not sure signs of leukemia. An infection or another problem also could cause these symptoms. Anyone with these symptoms should see a doctor as soon as possible. Only a doctor can diagnose and treat the problem.

In the early stages of chronic leukemia, the leukemia cells function almost normally. Symptoms may not appear for a long time. Doctors often find chronic leukemia during a routine checkup—before there are any symptoms. When symptoms do appear, they generally are mild at first and get worse gradually.

In acute leukemia, symptoms appear and get worse quickly. People with this disease go to their doctor because they feel sick. Other symptoms of acute leukemia are vomiting, confusion, loss of muscle control, and seizures. Leukemia cells also can collect in the testicles and cause swelling. Also, some patients develop sores in the eyes or on the skin. Leukemia also can affect the digestive tract, kidneys, lungs, or other parts of the body.

How does leukemia develop?


The four types of leukemia each begin in a cell in the bone marrow. The cell undergoes a leukemic change and it multiplies into many cells. The leukemia cells grow and survive better than normal cells and, over time, they crowd out normal cells.

Normal stem cells in the marrow form three main cell-types: Red cells, platelets and white cells. There are two major types of white cells: germ-ingesting cells (neutrophils and monocytes) and lymphocytes, which are part of the body's immune system and help to fight to infection.

The rate at which leukemia progresses and how the cells replace the normal blood and marrow cells are different with each type of leukemia.

Stages of Adult Acute Myeloid Leukemia Key Points for This Section * Once adult acute myeloid leukemia (AML) has been diagnosed, tests are do


The extent or spread of cancer is usually described as stages. In adult acute myeloid leukemia (AML), the subtype of AML and whether the leukemia has spread outside the blood and bone marrow are used instead of the stage to plan treatment. The following tests and procedures may be used to determine if the leukemia has spread:

  • Chest x-ray: An x-ray of the organs and bones inside the chest. An x-ray is a type of energy beam that can go through the body and onto film, making a picture of areas inside the body.
  • Lumbar puncture: A procedure used to collect cerebrospinal fluid from the spinal column. This is done by placing a needle into the spinal column. This procedure is also called an LP or spinal tap.

    Enlarge
    Lumbar puncture; drawing shows a patient lying in a curled position on a table and a spinal needle (a long, thin needle) being inserted into the lower back. Inset shows a close-up of the spinal needle inserted into the cerebrospinal fluid (CSF) in the lower part of the spinal column.
    Lumbar puncture. A patient lies in a curled position on a table. After a small area on the lower back is numbed, a spinal needle (a long, thin needle) is inserted into the lower part of the spinal column to remove cerebrospinal fluid (CSF, shown in blue). The fluid may be sent to a laboratory for testing.

  • Ultrasound exam: A procedure in which high-energy sound waves (ultrasound) are bounced off internal tissues or organs in the abdomen and make echoes. The echoes form a picture of body tissues called a sonogram. The picture can be printed to be looked at later.

There are three ways that cancer spreads in the body.

When cancer cells spread outside the blood, a solid tumor may form. This process is called metastasis. The three ways that cancer cells spread in the body are:

  • Through the blood. Cancer cells travel through the blood, invade solid tissues in the body, such as the brain or heart, and form a solid tumor.
  • Through the lymph system. Cancer cells invade the lymph system, travel through the lymph vessels, and form a solid tumor in other parts of the body.
  • Through solid tissue. Cancer cells that have formed a solid tumor spread to tissues in the surrounding area.

The new (metastatic) tumor is the same type of cancer as the primary cancer. For example, if leukemia cells spread to the brain, the cancer cells in the brain are actually leukemia cells. The disease is metastatic leukemia, not brain cancer.

Adult acute myeloid leukemia (AML) is a type of cancer in which the bone marrow makes abnormal myeloblasts (a type of white blood cell), red blood cel


Adult acute myeloid leukemia (AML) is a cancer of the blood and bone marrow. This type of cancer usually gets worse quickly if it is not treated. It is the most common type of acute leukemia in adults. AML is also called acute myelogenous leukemia, acute myeloblastic leukemia, acute granulocytic leukemia, and acute nonlymphocytic leukemia.

Normally, the bone marrow makes blood stem cells (immature cells) that develop into mature blood cells over time. A blood stem cell may become a myeloid stem cell or a lymphoid stem cell. The lymphoid stem cell develops into a white blood cell. The myeloid stem cell develops into one of three types of mature blood cells:

Enlarge
Blood cell development; drawing shows the steps a blood stem cell goes through to become a red blood cell, platelet, or white blood cell. Drawing shows a myeloid stem cell becoming a red blood cell, platelet, or myeloblast, which then becomes a white blood cell. Drawing also shows a lymphoid stem cell becoming a lymphoblast and then one of several different types of white blood cells.
Blood cell development. A blood stem cell goes through several steps to become a red blood cell, platelet, or white blood cell.

In AML, the myeloid stem cells usually develop into a type of immature white blood cell called myeloblasts (or myeloid blasts). The myeloblasts in AML are abnormal and do not become healthy white blood cells. Sometimes in AML, too many stem cells develop into abnormal red blood cells or platelets. These abnormal white blood cells, red blood cells, or platelets are also called leukemia cells or blasts. Leukemia cells can build up in the bone marrow and blood so there is less room for healthy white blood cells, red blood cells, and platelets. When this happens, infection, anemia, or easy bleeding may occur. The leukemia cells can spread outside the blood to other parts of the body, including the central nervous system (brain and spinal cord), skin, and gums.

Treating Leukemia


Certain features of a child's leukemia, such as age and initial white blood cell count, are used in determining the intensity of treatment needed to achieve the best chance for cure. Although all children with ALL are treated with chemotherapy, the dosages and drug combinations may differ.

To decrease the chance that leukemia will invade the child's central nervous system, patients receive intrathecal chemotherapy, the administration of cancer-killing drugs into the cerebrospinal fluid around the brain and spinal cord. Radiation treatments, which use high-energy rays to shrink tumors and keep cancer cells from growing, may be used in addition to intrathecal chemotherapy for certain high-risk patients. Children then require continued close monitoring by a pediatric oncologist, a specialist in childhood cancer.

After treatment begins, the goal is remission of the leukemia (when there is no longer evidence of cancer cells in the body). Once remission has occurred, maintenance chemotherapy is usually used to keep the child in remission. Maintenance chemotherapy is given in cycles over a period of 2 to 3 years to keep the cancer from reoccurring. Leukemia will almost always relapse (reoccur) if this additional chemotherapy isn't given. Sometimes the cancer will return in spite of maintenance chemotherapy, and other forms of chemotherapy will then be necessary.

Sometimes a bone marrow transplant may be necessary in addition to - or instead of - chemotherapy, depending on the type of leukemia a child has. During a bone marrow transplant, healthy bone marrow is introduced into a child's body.

Intensive leukemia chemotherapy have certain side effects, including hair loss, nausea and vomiting in the short term, and potential health problems down the line. As your child is treated for leukemia, your child's cancer treatment team will monitor the child closely for those side effects.

But with the proper treatment, the outlook for kids who are diagnosed with leukemia is quite good. Some forms of childhood leukemia have a remission rate of up to 90%; all children then require regular maintenance chemotherapy and other treatment to continue to be cancer-free. Overall cure rates differ depending on the specific features of a child's disease. Most childhood leukemias have very high remission rates. And the majority of children can be cured - meaning that they are in permanent remission - of the disease.

Symptoms of Leukemia


Because infection-fighting white blood cells are defective in children with leukemia, these children may experience increased episodes of fevers and infections.

They may also become anemic because leukemia affects the bone marrow's production of oxygen-carrying red blood cells. This makes them appear pale, and they may become abnormally tired and short of breath while playing.

Children with leukemia may also bruise and bleed very easily, experience frequent nosebleeds, or bleed for an unusually long time after even a minor cut because leukemia destroys the bone marrow's ability to produce clot-forming platelets.

Other symptoms of leukemia may include:

  • pain in the bones or joints, sometimes causing a limp
  • swollen lymph nodes (sometimes called swollen glands) in the neck, groin, or elsewhere
  • an abnormally tired feeling
  • poor appetite

In about 12% of children with AML and 6% of children with ALL, spread of leukemia to the brain causes headaches, seizures, balance problems, or abnormal vision. If ALL spreads to the lymph nodes inside the chest, the enlarged gland can crowd the trachea (windpipe) and important blood vessels, leading to breathing problems and interference with blood flow to and from the heart.

Risk for Childhood Leukemia


The ALL form of the disease most commonly occurs in younger children ages 2 to 8, with a peak incidence at age 4. But it can affect all age groups.

Children have a 20% to 25% chance of developing ALL or AML if they have an identical twin who was diagnosed with the illness before age 6. In general, nonidentical twins and other siblings of children with leukemia have two to four times the average risk of developing this illness.

Children who have inherited certain genetic problems - such as Li-Fraumeni syndrome, Down syndrome, Kleinfelter syndrome, neurofibromatosis, ataxia telangectasia, or Fanconi's anemia - have a higher risk of developing leukemia, as do children who are receiving medical drugs to suppress their immune systems after organ transplants.

Children who have received prior radiation or chemotherapy for other types of cancer also have a higher risk for leukemia, usually within the first 8 years after treatment.

In most cases, neither parents nor children have control over the factors that trigger leukemia, although current studies are investigating the possibility that some environmental factors may predispose a child to develop the disease. Most leukemias arise from noninherited mutations (changes) in the genes of growing blood cells. Because these errors occur randomly and unpredictably, there is currently no effective way to prevent most types of leukemia.

To limit the risk of prenatal radiation exposure as a trigger for leukemia (especially ALL), women who are pregnant or who suspect that they might be pregnant should always inform their doctors before undergoing tests or medical procedures that involve radiation (such as X-rays).

Regular checkups can spot early symptoms of leukemia in the relatively rare cases where this cancer is linked to an inherited genetic problem, to prior cancer treatment, or to use of immunosuppressive drugs for organ transplants.

Types of Childhood Leukemia


In general, leukemias are classified into acute (rapidly developing) and chronic (slowly developing) forms. In children, about 98% of leukemias are acute.

Acute childhood leukemias are also divided into acute lymphocytic leukemia (ALL) and acute myelogenous leukemia (AML), depending on whether specific white blood cells called lymphyocytes (or myelocytes), which are linked to immune defenses, are involved.

Approximately 60% of children with leukemia have ALL, and about 38% have AML. Although slow-growing chronic myelogenous leukemia (CML) may also be seen in children, it is very rare, accounting for fewer than 50 cases of childhood leukemia each year in the United States.

Supportive Care


Leukemia and its treatment can lead to other health problems. Patients receive supportive care to prevent or control these problems and to improve their comfort and quality of life during treatment.

Because people with leukemia get infections very easily, they may receive antibiotics and other drugs to help protect them from infections. The health care team may advise them to stay away from crowds and from people with colds and other contagious diseases. If an infection develops, it can be serious and should be treated promptly. Patients may need to stay in the hospital for treatment.

Anemia and bleeding are other problems that often require supportive care. Patients may need transfusions of red blood cells to help them have more energy. Platelet transfusions can help reduce the risk of serious bleeding.

Dental care also is very important. Leukemia and chemotherapy can make the mouth sensitive, easily infected, and likely to bleed. Doctors often advise patients to have a complete dental exam and, if possible, undergo needed dental care before chemotherapy begins. Dentists show patients how to keep their mouth clean and healthy during treatment.

Treatment leukemia


Many people with leukemia want to take an active part in making decisions about their medical care. They want to learn all they can about their disease and their treatment choices. However, the shock and stress after a diagnosis of cancer can make it hard to think of everything to ask the doctor. Often it helps to make a list of questions before an appointment. To help remember what the doctor says, patients may take notes or ask whether they may use a tape recorder. Some also want to have a family member or friend with them when they talk to the doctor—to take part in the discussion, to take notes, or just to listen.

The doctor may refer patients to doctors who specialize in treating leukemia, or patients may ask for a referral. Specialists who treat leukemia include hematologists, medical oncologists, and radiation oncologists. Pediatric oncologists and hematologists treat childhood leukemia.

Whenever possible, patients should be treated at a medical center that has doctors experienced in treating leukemia. If this is not possible, the patient’s doctor may discuss the treatment plan with a specialist at such a center.

Diagnosis


If a person has symptoms that suggest leukemia, the doctor may do a physical exam and ask about the patient's personal and family medical history. The doctor also may order laboratory tests, especially blood tests.

The exams and tests may include the following:

  • Physical exam—The doctor checks for swelling of the lymph nodes, spleen, and liver.

  • Blood tests—The lab checks the level of blood cells. Leukemia causes a very high level of white blood cells. It also causes low levels of platelets and hemoglobin, which is found inside red blood cells. The lab also may check the blood for signs that leukemia has affected the liver and kidneys.

  • Biopsy—The doctor removes some bone marrow from the hipbone or another large bone. A pathologist examines the sample under a microscope. The removal of tissue to look for cancer cells is called a biopsy. A biopsy is the only sure way to know whether leukemia cells are in the bone marrow.

    There are two ways the doctor can obtain bone marrow. Some patients will have both procedures:

    Local anesthesia helps to make the patient more comfortable.

  • Cytogenetics—The lab looks at the chromosomes of cells from samples of peripheral blood, bone marrow, or lymph nodes.

  • Spinal tap—The doctor removes some of the cerebrospinal fluid (the fluid that fills the spaces in and around the brain and spinal cord). The doctor uses a long, thin needle to remove fluid from the spinal column. The procedure takes about 30 minutes and is performed with local anesthesia. The patient must lie flat for several hours afterward to keep from getting a headache. The lab checks the fluid for leukemia cells or other signs of problems.

  • Chest x-ray—The x-ray can reveal signs of disease in the chest.

A person who needs a bone marrow aspiration or bone marrow biopsy may want to ask the doctor the following questions:

  • Will you remove the sample of bone marrow from the hip or from another bone?

  • How long will the procedure take? Will I be awake? Will it hurt?

  • How soon will you have the results? Who will explain them to me?

  • If I do have leukemia, who will talk to me about treatment? When?

Symptoms leukemia


Like all blood cells, leukemia cells travel through the body. Depending on the number of abnormal cells and where these cells collect, patients with leukemia may have a number of symptoms.

Common symptoms of leukemia may include:

  • Fevers or night sweats

  • Frequent infections

  • Feeling weak or tired

  • Headache

  • Bleeding and bruising easily (bleeding gums, purplish patches in the skin, or tiny red spots under the skin)

  • Pain in the bones or joints

  • Swelling or discomfort in the abdomen (from an enlarged spleen)

  • Swollen lymph nodes, especially in the neck or armpit

  • Weight loss

Such symptoms are not sure signs of leukemia. An infection or another problem also could cause these symptoms. Anyone with these symptoms should see a doctor as soon as possible. Only a doctor can diagnose and treat the problem.

In the early stages of chronic leukemia, the leukemia cells function almost normally. Symptoms may not appear for a long time. Doctors often find chronic leukemia during a routine checkup—before there are any symptoms. When symptoms do appear, they generally are mild at first and get worse gradually.

In acute leukemia, symptoms appear and get worse quickly. People with this disease go to their doctor because they feel sick. Other symptoms of acute leukemia are vomiting, confusion, loss of muscle control, and seizures. Leukemia cells also can collect in the testicles and cause swelling. Also, some patients develop sores in the eyes or on the skin. Leukemia also can affect the digestive tract, kidneys, lungs, or other parts of the body.

What Is Leukemia?


Leukemia is a type of cancer. Cancer is a group of many related diseases. All cancers begin in cells, which make up blood and other tissues. Normally, cells grow and divide to form new cells as the body needs them. When cells grow old, they die, and new cells take their place.

Sometimes this orderly process goes wrong. New cells form when the body does not need them, and old cells do not die when they should. Leukemia is cancer that begins in blood cells.

Normal Blood Cells

Blood cells form in the bone marrow. Bone marrow is the soft material in the center of most bones.

Immature blood cells are called stem cells and blasts. Most blood cells mature in the bone marrow and then move into the blood vessels. Blood flowing through the blood vessels and heart is called the peripheral blood.

Diagram shows the pluripotent stem cells, branching off into myeloid and lymphoid stem cells, becoming blast cells, and then becoming red blood cells, white blood cells, or platelets.
Picture of blood cells maturing from stem cells.

The bone marrow makes different types of blood cells. Each type has a special function:

Image of a white blood cell. White blood cells help fight infection.
Image of a red blood cell. Red blood cells carry oxygen to tissues throughout the body.
Image of several platelets. Platelets help form blood clots that control bleeding.

Review of Prostate Cancer Prevention Study Shows No Benefit for Use of Selenium and Vitamin E Supplements


Initial, independent review of study data from the Selenium and Vitamin E Cancer Prevention Trial (SELECT), funded by the National Cancer Institute (NCI) and other institutes that comprise the National Institutes of Health shows that selenium and vitamin E supplements, taken either alone or together, did not prevent prostate cancer. The data also showed two concerning trends: a small but not statistically significant increase in the number of prostate cancer cases among the over 35,000 men age 50 and older in the trial taking only vitamin E and a small, but not statistically significant increase in the number of cases of adult onset diabetes in men taking only selenium. Because this is an early analysis of the data from the study, neither of these findings proves an increased risk from the supplements and both may be due to chance.

The Southwest Oncology Group (SWOG), an international network of research institutions, coordinates SELECT at more than 400 clinical sites in the United States, Puerto Rico, and Canada.

SELECT participants are receiving letters explaining the study review and telling them to stop taking their study supplements. Participants will continue to have their health monitored by study staff, which may include regular digital rectal exams and PSA (prostate-specific antigen) tests to detect prostate cancer. Investigators intend to follow the participants for about three years to determine the long-term effects of having taken either supplement or placebo and to complete a biorepository of blood samples that will be used in extensive molecular analyses to give researchers a better understanding of prostate cancer, other cancers, and other diseases of male aging. This additional data collection is a vital part of the study.

Selenium (l) and Vitamin E (r) used in SELECT

Neither the men nor their physicians know which supplements or placebos the men have been taking, a procedure known as blinding or masking. As followup of the SELECT participants continues, the participants will continue to be blinded. A blinded followup may avoid unintentional bias and potentially false conclusions. However, at the request of a participant, they will be informed which supplement, if any, they received.

“SELECT was always designed as a study that would answer more than a single question about prostate cancer,” said Eric Klein, M.D., a study co-chair for SELECT, and a physician at the Cleveland Clinic. “As we continue to monitor the health of these 35,000 men, this information may help us understand why two nutrients that showed strong initial evidence to be able to prevent prostate cancer did not do so.”

SELECT was undertaken to substantiate earlier, separate findings from studies in which prostate cancer was not the primary outcome: a 1998 study of 29,133 male smokers in Finland who took vitamin E to prevent lung cancer surprisingly showed 32 percent fewer prostate cancers in men who took the supplement, and a 1996 study of 1,312 men and women with skin cancer who took selenium for prevention of the disease showed that men who took the supplement had 52 percent fewer prostate cancers than men who did not take the supplement.

Based on these and other earlier findings, in 2001, men were recruited to participate in SELECT. They were randomly assigned to take one of four sets of supplements or placebos, with more than 8,000 men in each group. One group took both selenium and vitamin E; one took selenium and a vitamin E placebo; one took vitamin E and a selenium placebo; and the final group received placebos of both supplements.

It should be noted that in 2003, while SELECT was recruiting men, a different SWOG-sponsored study reported that the drug finasteride reduced the incidence of prostate cancer by 25 percent. When this was discovered, men on SELECT were informed and allowed to take finasteride. Finasteride has not yet been approved by the U.S. Food and Drug Administration for prostate cancer prevention.

Except for skin cancer, prostate cancer is the most common type of cancer in men in the United States. In 2008, there will be an estimated 186,320 new cases of prostate cancer and 28,660 deaths from this disease in the United States. “Finding methods to prevent and treat prostate cancer remains a priority for the NCI, and with the aid of new molecular diagnostic tools and applications, we hope to continue to make headway in reducing deaths and new cases of this disease,” said NCI director John E. Niederhuber, M.D. “The science of cancer prevention is also leading toward individualized, molecular prevention, in which we will calculate risk and design preventive steps based on an individual's genome.”

SELECT has been funded by NCI for $114 million, with additional monies from the National Center for Complementary and Alternative Medicine, and with substudies funded and conducted by the National Heart, Lung and Blood Institute, the National Institute of Aging and the National Eye Institute at NIH. The substudies were evaluating the effects of selenium and vitamin E on chronic obstructive pulmonary disease, the development of Alzheimer's disease, and the development of macular degeneration and cataracts, and will continue without participants taking study supplements. An NCI-funded substudy is looking at the effects of the supplements on men who developed colon polyps.

“The SELECT trial owes a tremendous debt to our volunteers, the thousands of men who offered their time and enthusiastic participation, all in the interest of a future when prostate cancer can be prevented,” said Laurence H. Baker, D.O., chairman of the Southwest Oncology Group. SELECT investigators are analyzing the data and will submit the analysis for publication in a peer-reviewed medical journal.

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