Opportunities for Early Cancer Detection: The Rise of ctDNA Methylation-Based Pan-Cancer Screening Technologies

Constantin, N.; Sina, Abu Ali Ibn; Korbie, Darren; Trau, Matt

doi:10.3390/epigenomes6010006

Cited by 21 publications

(12 citation statements)

References 78 publications

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“…Compared to the SCED model, the MCED model has the following advantages: (1) Having a broader cancer screening spectrum and aggregated prevalence 20 . (2) Significant improving mental health and decrease subsequent medical costs with reduction in false-positive results 20 . (3) Having a higher early cancer detection rate 50,51 .…”

Section: Discussionmentioning

confidence: 99%

“…However, the screening model of existing cancer screening tests does not fulfill the need for "Universal cancer screening". This screening model 20 can be referred to as the model of "Single-Cancer Early Detection (SCED)" , which refers to the application of existing cancer screening tests (e.g., CT, ultrasound, gastroscopy, colonoscopy, blood TPSA, etc.) to screen for one site-specific cancer at a time (e.g., CT scan for lung cancer, mammogram for breast cancer, TPSA for blood, etc.…”

Section: Introductionmentioning

confidence: 99%

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Evaluation of the Multi-Cancer Early Detection (MCED) value of YiDiXie^™-HS and YiDiXie^™-SS

Sun,

Lu,

Zhang

et al. 2024

Preprint

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BackgroundCancer is a serious threat to the whole of humanity. The Multi-Cancer Early Detection (MCED) test is expected to solve the problem of “Universal cancer screening”. The purpose of this study is to evaluate the screening performance of two MCED tests, YiDiXie™-HS and YiDiXie™-SS, in multiple cancer types.Patients and methods11094 subjects were finally included in this study (the malignant tumor group, n = 4405; the normal control group, n = 6689). The malignant tumor group included all solid and hematological malignant tumor types covered in “China cancer registry annual report” by the National Cancer Center of China. The sensitivity and specificity of YiDiXie™-HS and YiDiXie™-SS were evaluated, respectively.ResultsThe overall sensitivity of YiDiXie™-HS for different cancer types and stages was 90.1% (89.2% - 90.9%; 3971/4405), and its specificity was 89.7% (89.0% - 90.4%; 6002/6689). Its sensitivity increases with clinical stage: stage I, 85.6% (83.9% - 87.1%); stage II, 91.4% (89.6% - 93.0%); stage III, 93.9% (92.0% - 95.4%); and stage IV, 98.4% (96.9% - 99.2%). The overall sensitivity of YiDiXie™-SS for different cancer types and stages was 99.1% (98.8% - 99.3%; 4365/4405), and its specificity was 65.2% (64.0% - 66.3%; 4358/6689). Its sensitivity was basically comparable in each clinical stage: stage I, 98.6% (98.0% - 99.1%); stage II, 99.5% (98.9% - 99.8%); stage III, 99.5% (98.6% - 99.8%); stage IV, 99.8% (98.9% - 100.0%).ConclusionYiDiXie™-HS has a high sensitivity in all clinical stages of all cancer types and can be a powerful complement to existing cancer screening tests. YiDiXie™-SS has an extremely high sensitivity in all clinical stages of all cancer types and is expected to solve the world problem of “Universal cancer screening”.Clinical trial numberChiCTR2200066840.

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Section: Discussionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Evaluation of the Multi-Cancer Early Detection (MCED) value of YiDiXie^™-HS and YiDiXie^™-SS

Sun,

Lu,

Zhang

et al. 2024

Preprint

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“…The cfDNA methylation analysis in cancer has the potential of clinical applications, e.g., investigating single-gene methylation profiles in different cancer types [ 168 ]. Recently emerged the possibility to develop a single test for early cancer detection (stMCED) by using ctDNA methylation fingerprints as a biomarker of malignancies [ 169 ]. The “methylome” leads to a better understanding of the onset and the phenotype evolution of a cancer.…”

Section: The Circulating Tumor Dna (Ctdna)mentioning

confidence: 99%

The Role of Cell-Free DNA in Cancer Treatment Decision Making

Telekes

Horváth

2022

Cancers

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The aim of this review is to evaluate the present status of the use of cell-free DNA and its fraction of circulating tumor DNA (ctDNA) because this year July 2022, an ESMO guideline was published regarding the application of ctDNA in patient care. This review is for clinical oncologists to explain the concept, the terms used, the pros and cons of ctDNA; thus, the technical aspects of the different platforms are not reviewed in detail, but we try to help in navigating the current knowledge in liquid biopsy. Since the validated and adequately sensitive ctDNA assays have utility in identifying actionable mutations to direct targeted therapy, ctDNA may be used for this soon in routine clinical practice and in other different areas as well. The cfDNA fragments can be obtained by liquid biopsy and can be used for diagnosis, prognosis, and selecting among treatment options in cancer patients. A great proportion of cfDNA comes from normal cells of the body or from food uptake. Only a small part (<1%) of it is related to tumors, originating from primary tumors, metastatic sites, or circulating tumor cells (CTCs). Soon the data obtained from ctDNA may routinely be used for finding minimal residual disease, detecting relapse, and determining the sites of metastases. It might also be used for deciding appropriate therapy, and/or emerging resistance to the therapy and the data analysis of ctDNA may be combined with imaging or other markers. However, to achieve this goal, further clinical validations are inevitable. As a result, clinicians should be aware of the limitations of the assays. Of course, several open questions are still under research and because of it cfDNA and ctDNA testing are not part of routine care yet.

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“…In recent years, there has been considerable interest in exploring the potential of ctDNA alterations for early detection of cancer and localization of the tissue of origin (TOO) (11,12). One such approach is the PanSeer test, which uses 477 differentially methylated regions (DMRs) in ctDNA to detect five different types of cancer up to four years prior to conventional diagnosis (13).…”

Section: Introductionmentioning

confidence: 99%

Multimodal analysis of methylomics and fragmentomics in plasma cell-free DNA for multi-cancer early detection and localization

Nguyen¹,

Nguyễn²,

Doan³

et al. 2023

Preprint

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The non-invasive approach for early cancer detection promises a screening assay accessible for everyone. However, the delivery of this promise is limited due mostly to the high sequencing cost associated with available assays. Here, we developed a multimodal assay called SPOT-MAS (Screening for the Presence Of Tumor by Methylation And Size) to simultaneously profile methylomics, fragmentomics, copy number, and end motifs in a single workflow using targeted and shallow genome-wide sequencing of cell-free DNA. We applied SPOT-MAS to 738 nonmetastatic patients with breast, colorectal, gastric, lung and liver cancer, and 1,550 healthy controls. SPOT-MAS detected the five cancer types with a sensitivity of 72.4% and specificity of 97.0%, with AUC of 0.95 (95% CI 0.93-0.96). For tumor-of-origin, a graph convolutional neural network was adopted and could achieve an accuracy of 0.7. In conclusion, our study demonstrates comparable performance to other early cancer detection assays while requiring significantly lower sequencing depth, making it economically feasible for population-wide screening.

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Opportunities for Early Cancer Detection: The Rise of ctDNA Methylation-Based Pan-Cancer Screening Technologies

Cited by 21 publications

References 78 publications

Evaluation of the Multi-Cancer Early Detection (MCED) value of YiDiXie^™-HS and YiDiXie^™-SS

Evaluation of the Multi-Cancer Early Detection (MCED) value of YiDiXie^™-HS and YiDiXie^™-SS

The Role of Cell-Free DNA in Cancer Treatment Decision Making

Multimodal analysis of methylomics and fragmentomics in plasma cell-free DNA for multi-cancer early detection and localization

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Opportunities for Early Cancer Detection: The Rise of ctDNA Methylation-Based Pan-Cancer Screening Technologies

Cited by 21 publications

References 78 publications

Evaluation of the Multi-Cancer Early Detection (MCED) value of YiDiXie™-HS and YiDiXie™-SS

Evaluation of the Multi-Cancer Early Detection (MCED) value of YiDiXie™-HS and YiDiXie™-SS

The Role of Cell-Free DNA in Cancer Treatment Decision Making

Multimodal analysis of methylomics and fragmentomics in plasma cell-free DNA for multi-cancer early detection and localization

Contact Info

Product

Resources

About

Evaluation of the Multi-Cancer Early Detection (MCED) value of YiDiXie^™-HS and YiDiXie^™-SS

Evaluation of the Multi-Cancer Early Detection (MCED) value of YiDiXie^™-HS and YiDiXie^™-SS