Impact of Gene Expression Profiling Tests on Breast Cancer Outcomes
Impact of Gene Expression Profiling Tests on Breast Cancer Outcomes

Author: Luigi Marchionni

Publisher: DIANE Publishing

Published: 2009-05

Total Pages: 230

ISBN-13: 1437911048

DOWNLOAD EBOOK

Assesses the evidence that three marketed gene expression-based assays improve prognostic accuracy, treatment choice, and health outcomes in women diagnosed with early stage breast cancer. Three gene expression assays were evaluated; Oncotype DX¿, MammaPrint® and the Breast Cancer Profiling (BCP or H/I ratio) test, and for gene expression signatures underlying the assays. They sought evidence on: analytic performance of tests; clinical validity; clinical utility; harms; and impact on clinical decision making and health care costs. Conclusions: Oncotype DX is furthest along the validation pathway, with retrospective evidence that it predicts distant spread and chemotherapy benefit to a clinically relevant extent over standard predictors. Illus.

Economic Evaluation of Potential Applications of Gene Expression Profiling in Clinical Oncology
Economic Evaluation of Potential Applications of Gene Expression Profiling in Clinical Oncology

Author: Malek Hannouf

Publisher:

Published: 2014

Total Pages:

ISBN-13:

DOWNLOAD EBOOK

Histopathological analysis of tumor is currently the main tool used to guide cancer management. Gene expression profiling may provide additional valuable information for both classification and prognostication of individual tumors. A number of gene expression profiling assays have been developed recently to inform therapy decisions in women with early stage breast cancer and help identify the primary tumor site in patients with metastatic cancer of unknown primary. The impact of these assays on health and economic outcomes, if introduced into general practice, has not been determined. I aimed to conduct an economic evaluation of regulatory-approved gene expression profiling assays for breast cancer and cancer of unknown primary for the purpose of determining whether these technologies represent value for money from the perspective of the Canadian health care system. I developed decision-analytic models to project the lifetime clinical and economic consequences of early stage breast cancer and metastatic cancer of unknown primary. I used Manitoba Cancer Registry and Manitoba administrative health databases to model current real-world Canadian clinical practices. I applied available data about gene expression profiling assays from secondary sources on these models to predict the impact of these assays on current clinical and economic outcomes. In the base case, gene expression profiling assays in early stage breast cancer and cancer of unknown primary resulted in incremental cost effectiveness ratios of less than $100,000 per quality-adjusted life-year gained. These results were most sensitive to the uncertainty associated with the accuracy of the assay, patient-physician response to gene expression profiling information and patient survival. The potential application of these gene expression profiling assays in clinical oncology appears to be cost-effective in the Canadian healthcare system. Field evaluation of these assays to establish their impact on cancer management and patient survival may have a large societal impact and should be initiated in Canada to ensure their clinical utility and cost-effectiveness. The use of Canadian provincial administrative population data in decision modeling is useful to quantify uncertainty about gene expression profiling assays and guide the use of novel funding models such as conditional funding alongside a field evaluation.

Cancer Genomics
Cancer Genomics

Author: Moamen Bydoun

Publisher: Elsevier Inc. Chapters

Published: 2013-11-21

Total Pages: 52

ISBN-13: 0128061103

DOWNLOAD EBOOK

Breast cancer is the most common cancer in women worldwide and the second leading cause of cancer deaths. Although early diagnosis, outcome prediction and treatment options are the ultimate objectives when assessing breast cancer patients, the methodology behind this clinical assessment varies and has gradually evolved from using standard clinical criteria into incorporating high-throughput genome-wide analysis. Early methods involved evaluating tumor size and spread as well as histological assessment (tumor grade). Later, the expression of hormone/growth receptors (ER, PR, and HER2) was added to the standard stratification of breast cancer patients. More recently, molecular approaches, which are based on the expression of a well-defined set of genes, have subdivided patients into five clinically relevant subtypes which not only predict prognosis and dictate treatment choice but also complement standard assessment. The advent of genome-wide analysis has produced the most robust classification system of breast cancers by coupling specific genetic aberrations (single nucleotide mutations and gene copy number variations) with gene expression profiles. Although these genome-wide approaches offer a promising future for breast cancer prognosis and treatment options, they are still not clinically feasible for standard population-based screening. Nonetheless, these approaches are becoming faster and more reliable in understanding the molecular architecture of breast cancer and are slowly paving the way towards personalized treatments which are tailored to individual patients. In the light of a rapidly evolving field of breast cancer genomics, this chapter highlights key standard and upcoming approaches for diagnosis, prognosis and treatment and discusses the feasibility of genome-oriented personalized treatments.

Genomic Approaches to the Study of Breast Cancer
Genomic Approaches to the Study of Breast Cancer

Author: Jeffrey E. Green

Publisher: IOS Press

Published: 2004

Total Pages: 104

ISBN-13: 9781586034603

DOWNLOAD EBOOK

Based on cutting-edge research with more than 1,000 married couples, "Love Me Slender" shows you how to bolster your resolve by strengthening your relationship, offering a fresh approach to weight loss that will turn your spouse from diet saboteur into your most loyal health ally. Eat right. Stay active. Good health follows from a few simple habits, yet millions of us struggle every day to put these habits into practice. "Love Me Slender" offers new solutions based on a remarkable insight: The powerful connection we share with our mate can influence what we eat, how much we exercise, how well we age, and ultimately how long we live. Strengthening this connection, and using it to influence our daily habits, holds the key to better health. Over the course of their twenty-year collaboration, Drs. Thomas Bradbury and Benjamin Karney have witnessed how difficult it is for partners to give each other the support they both really need--especially around emotionally loaded topics like unhealthy eating habits and weight loss. As codirectors of the Relationship Institute at UCLA, they have analyzed hundreds of conversations between partners seeking to change their eating and exercise habits, and they have identified the specific principles that determine whether couples struggle--or succeed--in their quest to improve their health. Featuring case studies, self-assessments, and sound practical advice, "Love Me Slender" is an eye-opening, uplifting guide that shows relationship partners how to discover the right ways--and avoid the pitfalls--of supporting one another in their lifelong pursuit of better health.

The Application of Gene Expression Profiling to Clinical Breast Cancer Research
The Application of Gene Expression Profiling to Clinical Breast Cancer Research

Author: Sherene Loi

Publisher: LAP Lambert Academic Publishing

Published: 2009

Total Pages: 280

ISBN-13: 9783838329734

DOWNLOAD EBOOK

The book has three main results parts. Chapter 3 illustrates the first independent validation study of a 70-gene signature developed from gene expression profiling for use in breast cancer prognosis and demonstration of its ability to add independent prognostic information to the clinical prognostic factors currently used. The successful validation of this study preceded the design and implementation of a world-wide randomized clinical trial evaluating the gene signature's clinical utility. This trial has commenced and is currently recruiting in Europe. Chapter 4 describes the finding that proliferation-related genes can predict clinical outcome consistently in breast cancer and many gene signatures developed for predicting breast cancer prognosis derive a significant proportion of their prognostic power from these genes. Finally, chapter 5 describes the use of proliferation-related genes to define two distinct prognostic molecular subgroups within estrogen receptor positive breast cancers.

Gene Expression Profiling of the Breast Tumour Microenvironment
Gene Expression Profiling of the Breast Tumour Microenvironment

Author: Grzegorz Finak

Publisher:

Published: 2008

Total Pages:

ISBN-13:

DOWNLOAD EBOOK

"Breast cancer is a very heterogeneous disease. This heterogeneity can be observed at many levels, including gene expression, chromosomal aberrations, and disease pathology. A clear understanding of these differences is important since they impact upon treatment efficacy and clinical outcome. Recent studies have demonstrated that the tumour microenvironment also plays a critical role in cancer initiation and progression. Genomic technologies have been used to gain a better understanding of the impact of gene expression heterogeneity on breast cancer, and have identified gene expression signatures associated with clinical outcome, histopathological breast cancer subtypes, and a variety of cancer-related pathways and processes. However, little work has been done in this context to examine the role of the tumour microenvironment in determining breast cancer outcome, or in defining breast cancer heterogeneity. Additionally, little is known about gene expression in histologically normal tissue adjacent to breast tumour, if this is influenced by the tumour, and how this compares with non-tumour-bearing breast tissue. By applying laser--capture microdissection and gene expression profiling to clinical breast cancer specimens the research presented in this thesis addresses these questions. We have generated gene expression profiles of morphologically normal epithelial and stromal tissue, isolated using laser capture microdissection, from patients with breast cancer or undergoing breast reduction mammoplasty. We determined that morphologically normal epithelium and stroma exhibited distinct expression profiles, but molecular signatures that distinguished breast reduction tissue from tumour-adjacent normal tissue were absent. Stroma isolated from morphologically normal ducts adjacent to tumour tissue contained two distinct expression profiles that correlated with stromal cellularity, and shared similarities with soft tissue tumors with favourable outcome. Adjacent normal epithelium and stroma from breast cancer patients showed no significant association between expression profiles and standard clinical characteristics, but did cluster ER/PR/HER2-negative breast cancers with basal-like subtype expression profiles with poor prognosis. Our data reveal that morphologically normal tissue adjacent to breast carcinomas has not undergone significant gene expression changes when compared to breast reduction tissue, and provide an important gene expression data set for comparative studies of tumour expression profiles. We compared gene expression profiles of tumour stroma from primary breast tumors and derived signatures strongly associated with clinical outcome. We present a new stroma-derived prognostic predictor (SDPP) that stratifies disease outcome independently of standard clinical prognostic factors and published expression-based predictors. The SDPP predicts outcome in several published whole tumour--derived expression data sets, identifies poor-outcome individuals from multiple clinical subtypes, including lymph node--negative tumors, and shows increased accuracy with respect to previously published predictors, especially for HER2-positive tumors. Prognostic power increases substantially when the predictor is combined with existing outcome predictors. Genes represented in the SDPP reveal the strong prognostic capacity of differential immune responses as well as angiogenic and hypoxic responses, highlighting the importance of stromal biology in tumour progression. We show that gene expression in the breast tumour microenvironment is highly heterogeneous, identifying at least six different classes of tumour stroma with distinct expression patterns and distinct biological processes. Two of these classes recapitulate the processes identified in the stroma-derived prognostic predictor, while the others are new classes of stroma associated with distinct clinical outcomes. One of these is associated with matrix remodelling and is strongly associated with the basal molecular subtype of breast cancer. The remainder are independent of the previously published molecular subtypes of breast cancer. Additionally, based on independent data from over 800 tumors, the combinations of stroma classes and breast cancer subtypes identify new subgroups of breast tumors that show better discrimination between good and poor outcome individuals than the molecular breast cancer subtypes or the stroma classes alone, suggesting a novel classification scheme for breast cancer. This research demonstrates an important role for the tumour microenvironment in defining breast cancer heterogeneity, with a consequent impact upon clinical outcome. Novel therapies could be targeted at the processes that define the stroma classes suggesting new avenues for individualized treatment."--