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Developing a Highly Specific Blood Test for Early Cancer Detection

American Association for Cancer Research
17 Apr 2018
Jay Leech
Marketing / Sales

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Initial findings from the Circulating Cell-free Genome Atlas (CCGA) study showed that prototype sequencing assays tested in this analysis may facilitate the development of a highly specific blood test for early cancer detection, according to data presented at the AACR Annual Meeting 2018, April 14-18, in Chicago.

“The early results from our prototype assays suggest that it is feasible to design a comprehensive blood-based test that allows us to detect cancer in asymptomatic individuals,” said Alexander Aravanis, MD, PhD, vice president of research and development at GRAIL. “Our initial data suggest that it will be possible to develop a screening test for multiple cancers with very high specificity, potentially greater than 99 percent.”

Aravanis and colleagues utilized data from the CCGA study, a prospective, observational, longitudinal study at over 140 different sites around the United States that analyzes blood samples from participants with a recent cancer diagnosis and participants with no known cancer. The researchers plan to enroll 15,000 participants, noted Aravanis; the study has currently enrolled more than 10,000 individuals.

“Importantly, we designed the CCGA study to get a very representative cohort of individuals in the United States,” said Aravanis. “Additionally, we’re very careful not to exclude other pathologic conditions or diseases that we would ultimately encounter in a real-world setting.”

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The researchers used blood samples from 878 participants with newly diagnosed treatment-naïve cancer spanning 20 tumor types and across all clinical stages. Additionally, 580 participants with no clinical cancer diagnosis were enrolled and 169 technical assay controls were utilized. After isolating the cell-free DNA, samples were analyzed using three distinct sequencing methods: targeted sequencing, to measure nonsynonymous single nucleotide variants (SNVs) and indels in particular stretches of the genome; whole-genome sequencing, to measure changes in copy number across the genome; and whole-genome bisulfite sequencing, to measure aberrant methylation patterns. All three tests were performed from a single blood draw.

A “cancer-like” signal was found in less than one percent of participants who entered the study with no clinical diagnosis of cancer, suggesting the possibility of developing a test with a specificity higher than 99 percent. Aravanis explained that a positive result in the few participants without a clinical diagnosis of cancer could be suggestive of undiagnosed cancer. He also noted that additional data will be presented at the meeting showing that the prototype assays detected a strong biological signal in cancers that are typically unscreened. Across all three assays tested, the strength of the signal increased with stage of disease.

Aravanis explained that DNA variants besides those generated by a cancerous tumor can also be present in the cell-free DNA, which could lead to a false-positive signal. One source of these variants is clonal hematopoiesis, a common age-related process that results in variations in the DNA of the white blood cell (WBC) population. Because a large fraction of the cell-free DNA comes from WBCs, Aravanis and colleagues also sequenced the paired WBCs during targeted and whole-genome sequencing. In this way, they could subtract the signal generated from the WBCs to precisely focus on the tumor-related DNA variants.

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The SNVs/indels from the WBC population accounted for 66 and 78 percent of all variants from the participants with and without cancer, respectively. “This is an important scientific learning in the context of early cancer detection,” noted Aravanis. “We have the ability to identify these non-tumor derived DNA variants and remove them, resulting in a cleaner signal with results that are ultimately more specific.”

The researchers found an average of 1, 2.4, and 6.5 nonsynonymous SNVs/indels per megabase in participants without cancer, with stage 1-3 cancer, and with stage 4 cancer, respectively. Similarly, after whole-genome sequencing analysis, the researchers calculated a score of 0, 0.3, and 2 in participants without cancer, with stage 1-3 cancer, and with stage 4 cancer, respectively. Finally, after whole-genome bisulfite sequencing analysis, the researchers calculated a methylation score of 0, 1, and 3.9 in participants without cancer, with stage 1-3 cancer, and with stage 4 cancer, respectively.

“From our prototype training assays, we found encouraging results that allowed us to detect the presence of cancer using three distinct methods with very few false positives,” said Aravanis. “Taken together, this is a good first step towards the ultimate development of a blood-based early cancer detection test.”

Aravanis noted that these data are from a training set, and the next step will be to verify these results in an independent validation set.

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Data AnalysisData analysis hardware and software is available to make data processing straight-forward yet powerful. Data software can be used for math and stats, technical graphing and image analysis. In addition, software is available for specific data analysis of electrophoresis, densitometry, ELISA and DNA sequencing.DNA SequencingDNA sequencing, such as sanger sequencing, is a biological technique that determines the precise order of nucleotide bases in a fragment or template of DNA. DNA sequencers and genetic analyzers are based on capillary electrophoresis, where labeled DNA fragments are electrophoretically separated by size as they migrate through a polymer. Find the best DNA sequencing products, including DNA sequencing kits, genomic libraries and genetic identity kits in our peer-reviewed product directory: compare products, check customer reviews and receive pricing direct from manufacturers.BiomarkersBiomarkers are biological markers which can be measured and evaluated to indicate a biological state. The use of biomarkers in research and diagnosis can indicate a normal or disease state or drug response of cells / tissues. Biomarkers include genetic markers, cell surface markers such as antigens, antibodies or receptors and secreted molecules such as cytokines. An assay system is required for identification of biomarkers. :Clinical TrialsClinical Trials, an essential part of drug discovery process, assess the safety and effectiveness of a new medication or device in the pharmaceutical industry. Clinical Trials are a phased process (Phase 0, Phase I, Phase II, Phase III and Phase IV) which begins after initial preclinical testing.Clinical GeneticsMolecular Genetics covers the analysis of hereditary genetic disease and chromosomal abnormalities. Genetics can be analysed using DNA, RNA, and protein microarrays, PCR, RT PCR and DNA sequencing. Genetic equipment includes genetic workstations, thermal cyclers, cooling blocks and electrophoresis products. Diagnostic kits are used for DNA / RNA extraction and purification.Cancer DiagnosticsThere are a wide variety of diagnostic tests for cancer available, and this range continues to expand as our knowledge of cancer improves. Current diagnostic methods include biopsy, imaging and blood tests for known biomarkers. New methods in research development include liquid biopsies and cancer breathalyzers.DNADeoxyribonucleic Acid (DNA) is the main component of chromosomes and the carrier of genetic information of living organisms. Find out here about PCR, NGS, ChIP-Seq, gel imaging, and many other techniques which can be used for the analysis of DNA.Cancer ResearchCancer research aims to understand the mechanisms of cancer development and progression to improve prevention, diagnosis, and treatment. From molecular biology to clinical trials, research spans a wide range of disciplines, including immunotherapy, targeted therapies, and drug discovery. Explore the best cancer research products in our peer-reviewed product directory; compare products, check reviews, and get pricing directly from manufacturers.Assay DevelopmentThe process of proving an assay to be sensitive with respect to the target is known as assay development. The assay should be able to characterize novel compounds and measure the potency of these compounds against a validated biological target.ScreeningUsing robotics, data processing and control software, liquid handling devices and sensitive detectors, screening allows a researcher to quickly conduct millions of chemical, genetic or pharmacological tests.Blood AnalysisThe analysis of blood is vital for many areas of life sciences and forensic investigations. Blood samples can be tested for a number of different reasons such as diagnosis, glucose levels, cholesterol and drug testing.TumorsTumor research focuses on understanding abnormal cell growth that leads to cancer. Identifying biomarkers, studying tumor microenvironments, and developing targeted therapies are critical for advancing cancer treatment. Early detection and personalized treatment options are key to improving outcomes for patients. Browse our peer-reviewed product directory to explore tools for tumor research, diagnostics, and cancer therapies; compare products, read customer reviews, and get pricing directly from manufacturers.AACRThe American Association for Cancer Research (AACR) is a leading organization focused on cancer research and treatment. It provides a platform for scientists, healthcare professionals, and industry leaders to share knowledge and collaborate in the fight against cancer.

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