Thursday 14 February 2013

Famous Personalities - Anil Ambani




Anil Ambani


Born: June 4, 1959


Achievement: Chairman of Anil Dhirubhai Ambani Group; Chosen as the 'CEO of the Year 2004' in the Platts Global Energy Awards and MTV Youth Icon of the Year' in September 2003.

Anil Ambani is one of the foremost entrepreneurs of Independent India. He is the Chairman of Anil Dhirubhai Ambani Group. Earlier, before the split in the Reliance Group, Anil Ambani held the post of Vice Chairman and Managing Director in Reliance Industries Limited (RIL).

Born on June 4, 1959, Anil Ambani did his Bachelors in Science from the University of Bombay and Masters in Business Administration The Wharton School at the University of Pennsylvania.

Anil Ambani joined Reliance in 1983 as Co-Chief Executive Officer. He pioneered India Inc's forays into overseas capital markets with international public offerings of global depository receipts, convertibles and bonds. Starting from 1991, he led Reliance in its efforts to raise, around US$2 billion from overseas financial markets. In January 1997, the 100-year Yankee bond issue was launched under his stewardship.

After the split in Reliance Group, Anil Ambani founded Anil Dhirubhai Ambani Group. He is the Chairman of all listed Group companies, which include: Reliance Communications, Reliance Capital, Reliance Energy and Reliance Natural Resources Limited.

Anil Ambai was elected as an independent member Rajya Sabha MP in June 2004. But he resigned voluntarily on March 25, 2006.

Anil Ambani has won several awards and honours. Major among these include: 'CEO of the Year 2004' in the Platts Global Energy Awards, 'MTV Youth Icon of the Year' in September 2003, 'The Entrepreneur of the Decade Award' by the Bombay Management Association, and 'Businessman of the Year Award' by leading Business Magazine, Business India in 1997.

Wednesday 6 February 2013

Tumor Markers




Tumor Markers


·  What are tumor markers?

Tumor markers are substances that are produced by cancer or by other cells of the body in response to cancer or certain benign (noncancerous) conditions. Most tumor markers are made by normal cells as well as by cancer cells; however, they are produced at much higher levels in cancerous conditions. These substances can be found in the blood, urine, stool, tumor tissue, or other tissues or bodily fluids of some patients with cancer. Most tumor markers are proteins. However, more recently, patterns of gene expression and changes to DNA have also begun to be used as tumor markers. Markers of the latter type are assessed in tumor tissue specifically.
Thus far, more than 20 different tumor markers have been characterized and are in clinical use. Some are associated with only one type of cancer, whereas others are associated with two or more cancer types. There is no “universal” tumor marker that can detect any type of cancer.

There are some limitations to the use of tumor markers. Sometimes, noncancerous conditions can cause the levels of certain tumor markers to increase. In addition, not everyone with a particular type of cancer will have a higher level of a tumor marker associated with that cancer. Moreover, tumor markers have not been identified for every type of cancer.

·  How are tumor markers used in cancer care?

Tumor markers are used to help detect, diagnose, and manage some types of cancer. Although an elevated level of a tumor marker may suggest the presence of cancer, this alone is not enough to diagnose cancer. Therefore, measurements of tumor markers are usually combined with other tests, such as biopsies, to diagnose cancer.

Tumor marker levels may be measured before treatment to help doctors plan the appropriate therapy. In some types of cancer, the level of a tumor marker reflects the stage (extent) of the disease and/or the patient’s prognosis (likely outcome or course of disease).
Tumor markers may also be measured periodically during cancer therapy. A decrease in the level of a tumor marker or a return to the marker’s normal level may indicate that the cancer is responding to treatment, whereas no change or an increase may indicate that the cancer is not responding.

Tumor markers may also be measured after treatment has ended to check for recurrence (the return of cancer).

·  How are tumor markers measured? 

A doctor takes a sample of tumor tissue or bodily fluid and sends it to a laboratory, where various methods are used to measure the level of the tumor marker.

If the tumor marker is being used to determine whether treatment is working or whether there is a recurrence, the marker’s level will be measured in multiple samples taken over time. Usually these “serial measurements,” which show whether the level of a marker is increasing, staying the same, or decreasing, are more meaningful than a single measurement.

· What tumor markers are currently being used, and for which cancer types?

A number of tumor markers are currently being used for a wide range of cancer types. Although most of these can be tested in laboratories that meet standards set by the Clinical Laboratory Improvement Amendments, some cannot be and may therefore be considered experimental. Tumor markers that are currently in common use are listed below.

ALK gene rearrangements

  • Cancer types: Liver cancer and germ cell tumors
  • Tissue analyzed: Blood
  • How used: To help diagnose liver cancer and follow response to treatment; to assess stage, prognosis, and response to treatment of germ cell tumors


  • Cancer types: Choriocarcinoma and testicular cancer
  • Tissue analyzed: Urine or blood
  • How used: To assess stage, prognosis, and response to treatment

  • Cancer type: Chronic myeloid leukemia
  • Tissue analyzed: Blood and/or bone marrow
  • How used: To confirm diagnosis and monitor disease status

  • Cancer types: Cutaneous melanoma and colorectal cancer
  • Tissue analyzed: Tumor
  • How used: To predict response to targeted therapies

CA15-3/CA27.29
  • Cancer type: Breast cancer
  • Tissue analyzed: Blood
  • How used: To assess whether treatment is working or disease has recurred

CA19-9
  • Cancer types: Pancreatic cancer, gallbladder cancer, bile duct cancer, and gastric cancer
  • Tissue analyzed: Blood
  • How used: To assess whether treatment is working

  • Cancer type: Ovarian cancer
  • Tissue analyzed: Blood
  • How used: To help in diagnosis, assessment of response to treatment, and evaluation of recurrence

  • Cancer type: Medullary thyroid cancer
  • Tissue analyzed: Blood
  • How used: To aid in diagnosis, check whether treatment is working, and assess recurrence

  • Cancer types: Colorectal cancer and breast cancer
  • Tissue analyzed: Blood
  • How used: To check whether colorectal cancer has spread; to look for breast cancer recurrence and assess response to treatment

  • Cancer type: Non-Hodgkin lymphoma
  • Tissue analyzed: Blood
  • How used: To determine whether treatment with a targeted therapy is appropriate

  • Cancer type: Neuroendocrine tumors
  • Tissue analyzed: Blood
  • How used: To help in diagnosis, assessment of treatment response, and evaluation of recurrence

Chromosomes 3, 7, 17, and 9p21
  • Cancer type: Bladder cancer
  • Tissue analyzed: Urine
  • How used: To help in monitoring for tumor recurrence

Cytokeratin fragments 21-1
  • Cancer type: Lung cancer
  • Tissue analyzed: Blood
  • How used: To help in monitoring for recurrence

EGFR mutation analysis
  • Cancer type: Non-small cell lung cancer
  • Tissue analyzed: Tumor
  • How used: To help determine treatment and prognosis

  • Cancer type: Breast cancer
  • Tissue analyzed: Tumor
  • How used: To determine whether treatment with hormonal therapy (such as tamoxifen) is appropriate

Fibrin/fibrinogen
  • Cancer type: Bladder cancer
  • Tissue analyzed: Urine
  • How used: To monitor progression and response to treatment

HE4
  • Cancer type: Ovarian cancer
  • Tissue analyzed: Blood
  • How used: To assess disease progression and monitor for recurrence

  • Cancer types: Breast cancer, gastric cancer, and esophageal cancer
  • Tissue analyzed: Tumor
  • How used: To determine whether treatment with trastuzumab is appropriate

Immunoglobulins
  • Cancer types: Multiple myeloma and Waldenström macroglobulinemia
  • Tissue analyzed: Blood and urine
  • How used: To help diagnose disease, assess response to treatment, and look for recurrence

KIT

KRAS mutation analysis
  • Cancer types: Colorectal cancer and non-small cell lung cancer
  • Tissue analyzed: Tumor
  • How used: To determine whether treatment with a particular type of targeted therapy is appropriate

  • Cancer type: Germ cell tumors
  • Tissue analyzed: Blood
  • How used: To assess stage, prognosis, and response to treatment

Nuclear matrix protein 22
  • Cancer type: Bladder cancer
  • Tissue analyzed: Urine
  • How used: To monitor response to treatment

  • Cancer type: Prostate cancer
  • Tissue analyzed: Blood
  • How used: To help in diagnosis, assess response to treatment, and look for recurrence

  • Cancer type: Thyroid cancer
  • Tissue analyzed: Tumor
  • How used: To evaluate response to treatment and look for recurrence

Urokinase plasminogen activator (uPA) and plasminogen activator inhibitor (PAI-1)
  • Cancer type: Breast cancer
  • Tissue analyzed: Tumor
  • How used: To determine aggressiveness of cancer and guide treatment

5-Protein signature (Ova1)
  • Cancer type: Ovarian cancer
  • Tissue analyzed: Blood
  • How used: To pre-operatively assess pelvic mass for suspected ovarian cancer

21-Gene signature (Oncotype DX)
  • Cancer type: Breast cancer
  • Tissue analyzed: Tumor
  • How used: To evaluate risk of recurrence

70-Gene signature (Mammaprint)
  • Cancer type: Breast cancer
  • Tissue analyzed: Tumor
  • How used: To evaluate risk of recurrence

·  Can tumor markers be used in cancer screening? 

Because tumor markers can be used to assess the response of a tumor to treatment and for prognosis, researchers have hoped that they might also be useful in screening tests that aim to detect cancer early, before there are any symptoms. For a screening test to be useful, it should have very high sensitivity (ability to correctly identify people who have the disease) and specificity (ability to correctly identify people who do not have the disease). If a test is highly sensitive, it will identify most people with the disease—that is, it will result in very few false-negative results. If a test is highly specific, only a small number of people will test positive for the disease who do not have it—in other words, it will result in very few false-positive results.
Although tumor markers are extremely useful in determining whether a tumor is responding to treatment or assessing whether it has recurred, no tumor marker identified to date is sufficiently sensitive or specific to be used on its own to screen for cancer.
For example, the prostate-specific antigen (PSA) test, which measures the level of PSA in the blood, is often used to screen men for prostate cancer. However, an increased PSA level can be caused by benign prostate conditions as well as by prostate cancer, and most men with an elevated PSA level do not have prostate cancer. Initial results from two large randomized controlled trials, the NCI-conducted Prostate, Lung, Colorectal, and Ovarian Cancer Screening Trial, or PLCO, and the European Randomized Study of Screening for Prostate Cancer, showed that PSA testing at best leads to only a small reduction in the number of prostate cancer deaths. Moreover, it is not clear whether the benefits of PSA screening outweigh the harms of follow-up diagnostic tests and treatments for cancers that in many cases would never have threatened a man’s life.

Similarly, results from the PLCO trial showed that CA-125, a tumor marker that is sometimes elevated in the blood of women with ovarian cancer but can also be elevated in women with benign conditions, is not sufficiently sensitive or specific to be used together with transvaginal ultrasound to screen for ovarian cancer in women at average risk of the disease. An analysis of 28 potential markers for ovarian cancer in blood from women who later went on to develop ovarian cancer found that none of these markers performed even as well as CA-125 at detecting the disease in women at average risk.

·  What kind of research is under way to develop more accurate tumor markers? 

Cancer researchers are turning to proteomics (the study of protein structure, function, and patterns of expression) in hopes of developing new biomarkers that can be used to identify disease in its early stages, to predict the effectiveness of treatment, or to predict the chance of cancer recurrence after treatment has ended.

Scientists are also evaluating patterns of gene expression for their ability to help determine a patient’s prognosis or response to therapy. For example, the NCI-sponsored TAILORx trial assigned women with lymph node-negative, hormone receptor–positive breast cancer who have undergone surgery to different treatments based on their recurrence scores in the Oncotype DX test. One of the goals of the trial is to determine whether women whose score indicates that they have an intermediate risk of recurrence will benefit from the addition of chemotherapy to hormonal therapy or whether such women can safely avoid chemotherapy. The trial has accrued its required number of subjects and these subjects will be followed for several years before results are available.

NCI’s Early Detection Research Network is developing and testing a number of genomic- and proteomic-based biomarkers.

The Program for the Assessment of Clinical Cancer Tests (PACCT), an initiative of the Cancer Diagnosis Program of NCI’s Division of Cancer Diagnosis and Treatment, has been developed to ensure that development of the next generation of laboratory tests is efficient and effective. The PACCT strategy group, which includes scientists from academia, industry, and NCI, is developing criteria for assessing which markers are ready for further development. PACCT also aims to improve access to human specimens, make standardized reagents and control materials, and support validation studies. A new program, the Clinical Assay Development Program, allows NCI to assist in the development of promising assays that may predict which treatment may be better or that will help indicate a particular cancer’s aggressiveness.
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