NGS-based cancer sequencing methods have expanded our understanding of cancer development, regulation, and progression to unlock new pathways for research. These techniques help detect changes in the cancer genome and identify their impact on the transcriptome, epigenome, and proteome.
Unlike other methods, such as PCR and Sanger sequencing, NGS has the ability to assess thousands of targets at once, greatly amplifying the discovery potential per sample. NGS can also detect low-frequency molecular events associated with carcinogenesis, cancer growth, and metastasis that could be missed using traditional molecular methods. Together, these advancements are paving the future towards improving translational medicine and therapies.
Researchers can leverage several approaches when studying biological “omes”: bulk-cell analysis, single-cell analysis, spatial analysis, and metagenomic analysis. Each method studies cancer at a different level of biological resolution and has a distinct use case depending on the research goals and objectives.
Bulk-cell analysis: Bulk-cell analysis allows scientists to study pooled cell populations, tissue sections, or biopsies.
Single-cell analysis: Single-cell analysis studies a given “ome” at the resolution of a single cell.
Spatial analysis (also called spatial genomics): Spatial analysis captures “omic” information at the cellular level within an intact tissue sample to link structure and activity.
Metagenomic analysis: Metagenomic analysis sequences every gene in every organism of a complex microbial community present within a tissue, organ, or tumor.
Multiomics (multiple omics) integrates data across genomics, transcriptomics, epigenetics, and proteomics to make insights into complex diseases such as cancer. This comprehensive approach aids researchers in understanding molecular changes driving normal development, cellular responses, and diseases.
Simple, comprehensive workflows for a broad range of cancer research applications. The new 2022 guide includes: Single-cell sequencing, spatial sequencing, methylation profiling, multiomics, cell-free RNA sequencing and more!
Download Free GuideMethod | Description and Use |
---|---|
Genomics | |
Cancer whole-genome sequencing | Identifies a comprehensive list of cancer-driving genetic events. |
Cancer whole-exome sequencing | A cost-effective and efficient sequencing method to find cancer-driving genes within the coding region of the genome compared to whole-genome sequencing. |
ctDNA sequencing | Used as a potential alternative to invasive tissue biopsies to detect cell-free circulating tumor DNA (ctDNA), which can act as a noninvasive cancer biomarker. |
Targeted NGS cancer panels | Targets known DNA and/or RNA variants from the same FFPE sample. |
Epigenomics | |
Methylome sequencing | Both genome-wide analysis and targeted approaches can provide insight into methylation patterns at the single nucleotide level. |
Cancer epigenetics | Identifies cellular biomarkers associated with regulation of cancer genes or drug resistance. |
ATAC-Seq | Determines chromatin accessibility across the genome without prior knowledge of regulatory elements. |
Transcriptomics | |
Cancer RNA-Seq | Measures the average RNA expression and transcriptome changes in cancer samples. |
Spatial transcriptomics | Analyzes gene expression within the natural tumor microenvironment and architecture. |
Single-cell RNA-Seq | Measures gene expression and explores the distinct biology of individual cancer cells in complex tissues. |
Proteomics + Transcriptomics | |
Cellular indexing of transcriptomes and epitopes (CITE-Seq) | Uses oligonucleotide-labeled antibodies to simultaneously measure proteins and RNA in single cells. This combined proteomics/transcriptomics approach links RNA expression to cancer phenotypes. |
The user-friendly "Recommended Links" feature allows you to easily find content and products relevant to cancer research and/or a variety of other fields. You can access this option from the top of any illumina.com page.
Learn HowLearn about specific cancer research applications and explore resources covering research developments, guides, products, and more.
See cancer research applicationsOur innovative platforms deliver exceptional data quality and accuracy at a massive scale. View sequencer comparison tables and find tools designed to help you choose the right platform for your needs.
View NGS and microarray products supporting multiple cancer research applications, including tools for analyzing DNA, RNA, epigenetics, and more.
User-friendly Illumina tools ease the process of analyzing sequencing data so you can spend more time doing research and less time configuring workflows.
This Methods Guide provides examples of multiomic research from recent literature and detailed, end-to-end workflows. Includes recommendations for sample isolation, library prep, sequencing depth, data analysis, and more.
This 20+ page eBook provides published, comprehensive workflows to thoroughly characterize liquid biopsy samples using NGS and microarrays.
In this webinar, experts cover essential background topics in NGS, achievements, challenges, and how an integrated multiomics approach can be used in cancer diagnosis and treatment.
Learn how researchers at the Ontario Institute for Cancer Research and United Health Network are linking the causes and consequences of complex phenotypes through multiomics to enable discoveries that weren’t possible before.
Learn the basics of next-generation sequencing and find tips for getting started.