Abstract: A method is provided for detecting a cancer in an individual, the method comprising detection of a deletion in the nucleic acid sequence between residues 10743 and 14125 in mitochondrial DNA by extracting the mitochondrial DNA (mtDNA) from the biological sample obtained from the individual and quantifying the amount of mtDNA in the sample having a deletion in the nucleic acid sequence between approximately residues 10743 and 14125 of the mtDNA genome, and comparing the amount of mtDNA in the sample having the deletion to at least one known reference sample. Kits for conducting the method are also provided.

Abstract: Mitochondrial DNA deletions useful for the detection of cancers and sun exposure are provided. In particular, methods and kits for detecting mitochondrial DNA deletions for the early detection, diagnosis and progression of prostate cancer, sun exposure and non-melonoma skin cancer are provided.

Abstract: A method is provided for detecting a cancer in an individual, the method comprising detection of a deletion in the nucleic acid sequence between residues 10743 and 14125 in mitochondrial DNA by extracting the mitochondrial DNA (mtDNA) from the biological sample obtained from the individual and quantifying the amount of mtDNA in the sample having a deletion in the nucleic acid sequence between approximately residues 10743 and 14125 of the mtDNA genome, and comparing the amount of mtDNA in the sample having the deletion to at least one known reference sample. Kits for conducting the method are also provided.

Abstract: A method for detecting cancer in an individual comprising detecting a deletion in the nucleic acid sequence between residues 10743 and 14125 in mitochondrial DNA, obtaining a biological sample from the individual, extracting the mitochondrial DNA (mtDNA) from the sample, quantifying the amount of mtDNA in the sample having a deletion in the nucleic acid sequence between residues 10743 and 14125 of the mtDNA genome, and comparing the amount of mtDNA in the sample having the deletion to at least one known reference sample.

Abstract: Mitochondrial DNA deletions useful for the detection of cancers and sun exposure are provided. In particular, methods and kits for detecting mitochondrial DNA deletions for the early detection, diagnosis and progression of prostate cancer, sun exposure and non-melonoma skin cancer are provided.

Abstract: A method for detecting cancer in an individual comprising detecting a deletion in the nucleic acid sequence between residues 10743 and 12125 in mitochondrial DNA, obtaining a biological sample from the individual, extracting the mitochondrial DNA (mtDNA) from the sample, quantifying the amount of mtDNA in the sample having a deletion in the nucleic acid sequence between residues 10743 and 14125 of the mtDNA genome, and comparing the amount of mtDNA in the sample having the deletion to at least one known reference sample.

Abstract: Mitochondrial DNA deletions useful for the detection of cancers and sun exposure are provided. In particular, methods and kits for detecting mitochondrial DNA deletions for the early detection, diagnosis and progression of prostate cancer, sun exposure and non-melonoma skin cancer are provided.

Abstract: A method for detecting cancer in an individual comprising detecting a deletion in the nucleic acid sequence between residues 10743 and 12125 in mitochondrial DNA, obtaining a biological sample from the individual, extracting the mitochondrial DNA (mtDNA) from the sample, quantifying the amount of mtDNA in the sample having a deletion in the nucleic acid sequence between residues 10743 and 14125 of the mtDNA genome, and comparing the amount of mtDNA in the sample having the deletion to at least one known reference sample.

Abstract: Mitochondrial DNA deletions useful for the detection of cancers and sun exposure are provided. In particular, methods and kits for detecting mitochondrial DNA deletions for the early detection, diagnosis and progression of prostate cancer, sun exposure and non-melonoma skin cancer are provided.

Abstract: The present invention broadly claims a method for detecting cancer in an individual. The method comprises detecting a deletion in the nucleic acid sequence between residues 10743 and 12125 in mitochondrial DNA. The method comprises obtaining a biological sample from the individual; extracting the mitochondrial DNA (mtDNA) from the sample; quantifying the amount of mtDNA in the sample having a deletion in the nucleic acid sequence between residues 10743 and 14125 of the mtDNA genome; and comparing the amount of mtDNA in the sample having the deletion to at least one known reference sample.

Abstract: The present invention broadly claims a method for detecting cancer in an individual. The method comprises detecting a deletion in the nucleic acid sequence between residues 10743 and 12125 in mitochondrial DNA. The method comprises obtaining a biological sample from the individual; extracting the mitochondrial DNA (mtDNA) from the sample; quantifying the amount of mtDNA in the sample having a deletion in the nucleic acid sequence between residues 10743 and 14125 of the mtDNA genome; and comparing the amount of mtDNA in the sample having the deletion to at least one known reference sample.

Abstract: Mitochondrial DNA deletions useful for the detection of cancers and sun exposure are provided. In particular, methods and kits for detecting mitochondrial DNA deletions for the early detection, diagnosis and progression of prostate cancer, sun exposure and non-melonoma skin cancer are provided.

Abstract: Mitochondrial DNA deletions useful for the detection of cancers and sun exposure are provided. In particular, methods and kits for detecting mitochondrial DNA deletions for the early detection, diagnosis and progression of prostate cancer, sun exposure and non-melanoma skin cancer are provided.

Abstract: The present invention relates to methods for predicting, diagnosing and monitoring skin states and skin diseases. The methods combine the use of non-invasive skin collecting techniques with one or more assays for determining mitochondrial DNA (mtDNA) aberrations and Melanocortin 1 Receptor (MC1R) variants, thereby providing a comprehensive tool for identifying, predicting and/or monitoring photoageing, ultraviolet radiation (UVR) damage or skin disease. The methods of the invention may also be effective in screening for new therapeutic agents, skin care products and treatment regimes, and may also be useful for monitoring the response of a subject to a preventative or therapeutic treatment.

Abstract: The present invention relates to methods for predicting, diagnosing and monitoring skin states and skin diseases. The methods combine the use of non-invasive skin collecting techniques with one or more assays for determining mitochondrial DNA (mtDNA) aberrations and Melanocortin 1 Receptor (MC1R) variants, thereby providing a comprehensive tool for identifying, predicting and/or monitoring photoageing, ultraviolet radiation (UVR) damage or skin disease. The methods of the invention may also be effective in screening for new therapeutic agents, skin care products and treatment regimes, and may also be useful for monitoring the response of a subject to a preventative or therapeutic treatment.

Abstract: A direct gas-fired heating unit is provided which uses an axial-bladed fan for generating a main air flow through a burner unit. The burner unit has a dedicated combustion air blower supplying combustion air to the burner separate from a main air flow generated by the main fan. The burner unit includes a dedicated blower which draws a small volume of outside air as combustion air. Further, the burner unit may include bypass ports which allows for discharge of bypass air from the burner unit.

Abstract: Mitochondrial DNA deletions useful for the detection of cancers and sun exposure are provided. In particular, methods and kits for detecting mitochondrial DNA deletions for the early detection, diagnosis and progression of prostate cancer, sun exposure and non-melonoma skin cancer are provided.

Abstract: A cluster analysis of mutations in the mitochondrial genomes from malignant, adjacent benign and distant benign tissues from a sample of men having prostate cancer has determined that mutations in ND1, ND2, COX1 and CytB are indicative of prostate cancer. 97% (30/31) of the samples contained synonymous and non-synonymous mutations in these genes. 65% (20/31) of the samples contained non-synonymous mutations in these genes.

Abstract: A method of distributing a plurality of documents includes associating a metadata file with each of the documents, applying a content attribute to each of the documents and appending the metadata file of each of the documents with the content attribute, and assigning a content group to each of the documents based on the content attribute of a respective one of the documents and modifying the metadata file of each of the documents to include the content group of the respective one of the documents. In addition, the method further includes defining a plurality of content categories and associating the content group with at least one of the content categories, and distributing for the at least one of the content categories each of the documents assigned the content group.

Abstract: The examination of mutations in the mitochondrial genome is used as a diagnostic system for diseases such as prostate cancer, and non melanoma skin cancer. Characteristic mutations and rearrangements including, point mutations (transitions, transversions), deletions, inversions, duplications, recombinations, insertions or combinations thereof in the mitochondrial genome are used as early indicators of prostate cancer, and non melanoma skin cancer. Moreover, the 4977 bp, or “common deletion” as well as other associated mutations and/or deletions are used as a measure of aging.