Abstract: Sensitive biomarker(s) to identify individuals with past exposure to tobacco smoke based on gene expression are disclosed. Such biomarkers may be used, for example, for epidemiological studies related to smoke exposure, to provide insights into the mechanisms leading to reversible and persistent effects of tobacco smoke that may explain former smokers’ increased risk for developing tobacco-induced lung disease, and/or to provide novel targets for chemoprophylaxis.

Abstract: The technology described herein is directed to methods of treating and diagnosing bronchial premalignant lesions, e.g. by determining the lesion subtype using one or more biomarkers described herein.

Abstract: The technology described herein is directed to methods of treating and diagnosing bronchial premalignant lesions, e.g. by determining the lesion subtype using one or more biomarkers described herein.

Abstract: Disclosed herein are assays and methods for the identification of premalignant lesions, as well as methods of determining the likelihood that such premalignant lesions will progress to lung cancer. Also disclosed are methods and assays that are useful for monitoring the progression of premalignant lesions to lung cancer. The assays and methods disclosed herein provide minimally invasive means of accurately detecting and monitoring the presence or absence of premalignant lesions, thus providing novel insights into the earliest stages of lung cancer and facilitating early detection and early intervention.

Abstract: Disclosed herein are assays and methods for the identification of premalignant lesions, as well as methods of determining the likelihood that such premalignant lesions will progress to lung cancer. Also disclosed are methods and assays that are useful for monitoring the progression of premalignant lesions to lung cancer. The assays and methods disclosed herein provide minimally invasive means of accurately detecting and monitoring the presence or absence of premalignant lesions, thus providing novel insights into the earliest stages of lung cancer and facilitating early detection and early intervention.

Abstract: The present invention provides methods for diagnosis and prognosis of lung cancer using expression analysis of one or more groups of genes, and a combination of expression analysis with bronchoscopy. The methods of the invention provide far superior detection accuracy for lung cancer when compared to any other currently available method for lung cancer diagnostic or prognosis. The invention also provides methods of diagnosis and prognosis of other lung diseases, particularly in individuals who are exposed to air pollutants, such as cigarette or cigar smoke, smog, asbestos and the like air contaminants or pollutants.

Abstract: The present invention provides methods for diagnosis and prognosis of lung cancer using expression analysis of one or more groups of genes, and a combination of expression analysis with bronchoscopy or via nasal epithelial cells. The methods of the invention provide far superior detection accuracy for lung cancer when compared to any other currently available method for lung cancer diagnostic or prognosis. The invention also provides methods of diagnosis and prognosis of other lung diseases, particularly in individuals who are exposed to air pollutants, such as cigarette or cigar smoke, smog, asbestos and the like air contaminants or pollutants via more accessible clinical samples from a bronchoscope or nasal sample.

Abstract: The technology described herein is directed to methods of treating and diagnosing bronchial premalignant lesions, e.g. by determining the lesion subtype using one or more biomarkers described herein.

Abstract: The present invention provides methods for diagnosis and prognosis of lung cancer using expression analysis of one or more groups of genes, and a combination of expression analysis with bronchoscopy. The methods of the invention provide far superior detection accuracy for lung cancer when compared to any other currently available method for lung cancer diagnostic or prognosis. The invention also provides methods of diagnosis and prognosis of other lung diseases, particularly in individuals who are exposed to air pollutants, such as cigarette or cigar smoke, smog, asbestos and the like air contaminants or pollutants.

Abstract: The present invention provides methods for diagnosis and prognosis of lung cancer using expression analysis of one or more groups of genes, and a combination of expression analysis with bronchoscopy. The methods of the invention provide far superior detection accuracy for lung cancer when compared to any other currently available method for lung cancer diagnostic or prognosis. The invention also provides methods of diagnosis and prognosis of other lung diseases, particularly in individuals who are exposed to air pollutants, such as cigarette or cigar smoke, smog, asbestos and the like air contaminants or pollutants.

Abstract: The present invention provides methods for diagnosis and prognosis of lung cancer using expression analysis of one or more groups of genes, and a combination of expression analysis with bronchoscopy. The methods of the invention provide far superior detection accuracy for lung cancer when compared to any other currently available method for lung cancer diagnostic or prognosis. The invention also provides methods of diagnosis and prognosis of other lung diseases, particularly in individuals who are exposed to air pollutants, such as cigarette or cigar smoke, smog, asbestos and the like air contaminants or pollutants.

Abstract: Disclosed herein are assays and methods for the identification of premalignant lesions, as well as methods of determining the likelihood that such premalignant lesions will progress to lung cancer. Also disclosed are methods and assays that are useful for monitoring the progression of premalignant lesions to lung cancer. The assays and methods disclosed herein provide minimally invasive means of accurately detecting and monitoring the presence or absence of premalignant lesions, thus providing novel insights into the earliest stages of lung cancer and facilitating early detection and early intervention.

Abstract: The present invention provides methods for diagnosis and prognosis of lung cancer using expression analysis of one or more groups of genes, and a combination of expression analysis with bronchoscopy. The methods of the invention provide far superior detection accuracy for lung cancer when compared to any other currently available method for lung cancer diagnostic or prognosis. The invention also provides methods of diagnosis and prognosis of other lung diseases, particularly in individuals who are exposed to air pollutants, such as cigarette or cigar smoke, smog, asbestos and the like air contaminants or pollutants.

Abstract: Described herein are multifactorial methods for detecting, diagnosing or aiding in the diagnosis of lung disorders or disease, e.g., lung cancer. The methods disclosed utilize multiple diagnostic paradigms, for example, to improve diagnostic sensitivity, specificity, negative predictive value and/or positive predictive value over each of the paradigms alone. For example, a clinicogenomic model is disclosed for lung cancer diagnosis which combines clinical factors and gene expression, particularly a sensitive and specific gene expression biomarker.