Is Amy Robach Making The Right Breast Cancer Treatment Choice At 40

Barron's Medical Journal Reporting From Duke University Medical School Durham, NC USA (Global Newswire )(AP News)

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Is Amy Robach Making The Right Breast Cancer Treatment Choice At 40

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Durham, NC (AP) After Good Morning America’s Amy Robach was diagnosed with Breast Cancer Barron’s Medical Journal Asked The CEO Of Sam Houston Biotech Inc Rose Conrad what she taught of the announcement ? Rose was happy to see that so many Women will now take notice and be willing to take a test at forty years of age to see if they are candidates for breast cancer. Conrad went on to say, why did Good Morning America not include A Genomic Test as part of the breast cancer testing process.

Genomics is a discipline in genetics that applies recombinant DNA, DNA sequencing methods, and bioinformatics to sequence, assemble, and analyze the function and structure of genomes (the complete set of DNA within a single cell of an organism). We then ask Rose is her company Doing any work with Genomics for breast cancer and if so explain the process. Genomics is the Gaussian processes in action, to predict the likelihood of chemotherapy benefit as well as recurrence, for patients with node-negative breast cancer that is estrogen-receptor positive and/or progesterone-receptor positive. Additionally, physicians use Sam Houston to make treatment recommendations for certain node-positive breast cancer patients, and the test report also provides quantitative scores for select individual genes. Sam Houston has been extensively evaluated in thirteen clinical studies involving more than 4,000 breast cancer patients worldwide, including a large validation study published in The New England Journal of Medicine and a chemotherapy benefit study published in the Journal of Clinical Oncology. Both Medicare and private health plans covering over 90 percent of U.S. insured lives provided reimbursement for Sam Houston for patients with node-negative breast cancer that is estrogen-receptor positive and/or progesterone-receptor positive through contracts, agreements or policy decisions.

Breast Cancer Researchers and Scientist are ahead of the curve with several new technologies based on Nanoparticles and Semi Conductors Namely Genomics and treatments. The field of genomics is caught in a data deluge. Targeted breast cancer DNA sequencing is becoming faster and cheaper at a pace far outstripping Moore’s law, which describes the rate at which computing gets faster and cheaper.

The result is that the ability to determine Targeted breast cancer DNA sequences is starting to outrun the ability of researchers to store, transmit and especially to analyze the data.

The cost of sequencing a human genome — all three billion bases of DNA in a set of human chromosomes — plunged to $10,000.00 which means genomics breast cancer DNA sequencing is around $3000.00.

The lower cost, along with increasing speed, has led to a huge increase in how much breast Cancer sequencing data is being produced.

Numerous investigations have shown that both tissue and cell distribution profiles of anticancer drugs can be controlled by their entrapment in submicronic colloidal systems (nanoparticles). The rationale behind this approach is to increase antitumor efficacy, while reducing systemic side-effects. This review provides an update of tumor targeting with conventional or long-circulating nanoparticles. The in vivo fate of these systems, after intravascular or tumoral administration, is discussed, as well as the mechanism involved in tumor regression. Nanoparticles are also of benefit for the selective delivery of oligonucleotides to tumor cells. Moreover, certain types of nanoparticles showed some interesting capacity to reverse MDR resistance, which is a major problem in chemotherapy. The first experiments, aiming to decorate nanoparticles with molecular ligand for active targeting of cancerous cells

Miniaturization will allow the tools for many different tests to be situated together on the same small device. Hybrid Sam Houston Researchers Say that nanotechnology will allow them to run many diagnostic tests simultaneously.

Nanoparticles nanoshells is use to antibodies that recognize cancer cells. Sam Houston scientist envision letting these nanoshells seek out their cancerous targets, then applying near-infrared light. The heat generated by the light-absorbing nanoshells can successfully killed breast cancer tumor cells while leaving neighboring cells intact.

A nanometer is a billionth of a meter. It's difficult to imagine anything so small, but think of something only 1/80,000 the width of a human hair. Ten hydrogen atoms could be laid side-by-side in a single nanometer.

Sam Houston minuscule molecule that will be used to detect breast cancer is a quantum dot. Quantum dots are tiny crystals that glow when they are stimulated by ultraviolet light. The wavelength, or color, of the light depends on the size of the crystal. Latex beads filled with these crystals can be designed to bind to specific DNA sequences. Hybrid Sam Houston understands that Hyperthermia gold nanoshell Targeted breast cancer genomics at 40 for high risk women will reduce breast cancer at 60 years of Age. Training Genomics Counselor and Storing DNA Analysis in the cloud will allow Hybrid Sam Houston to say that Chemotherapy will help their breast cancer outcome or if Chemotheraphy and Hyperthermia will extend their life.

The impact of genomics and pharmacogenomics in the current arena of clinical oncology is well-established. In breast cancer, mutations in the BRCA1 and BRCA2 genes have been well-characterized to carry a high risk of the disease during a woman's lifespan. However, these high risk genes contribute to only a small proportion of the familial cases of breast cancer. Hence, further efforts aimed to study the contribution of genetic mutations in other genes, including the estrogen receptor gene, TP53, CYP19, and mismatch repair genes to further investigate the genetic component of breast cancer.

Multiple pharmacogenomic studies have previously linked genetic variants in known pathways with treatment response in cancer patients. Currently, polymorphisms in drug metabolizing enzymes, efflux transporters, as well as, drug targets have shown correlations to variations in response and toxicity to commonly prescribed chemotherapeutic treatments of breast cancer. CYP2D6 variants have been correlated with tamoxifen response and interindividual variability seen. An emerging application of cancer genetics and pharmacogenetics involves the use of inherited or acquired genetic abnormalities to predict treatment toxicity or outcomes. Recently, methods that involve the scanning of entire genomes for common variants have begun to influence studies of cancer causation. Currently, treatment individualization for breast cancer can take place on the basis of few molecular targets including the estrogen receptor and the overexpression of the HER2 receptor. Overall, the current review summarizes the recent findings in the genetic and pharmacogenetic research of breast cancer and the advances made in personalization of treatment.

Women that use a Genomic Breast Cancer Test at 40 has a eighty seven percent chance to make sixty