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ctDNA as a Biomarker for Immunotherapy Response: Monitoring Pseudoprogression and Resistance

This Nature Reviews Clinical Oncology paper evaluates the clinical potential of ctDNA in patients receiving immune checkpoint inhibitors. ctDNA analysis can detect residual disease, estimate tumour burden, and identify genetic predictors of immunotherapy response including TMB and microsatellite instability, all without invasive tissue biopsy. Early quantitative changes in ctDNA levels show particular promise for distinguishing true response from pseudoprogression, a critical challenge in immunotherapy management.

The original study

Clinical potential of circulating tumour DNA in patients receiving anticancer immunotherapy.

Authors
Cabel L, Proudhon C, Romano E, Girard N, Lantz O, Stern MH, et al.
Journal
Nature reviews. Clinical oncology
Type
Journal Article, Research Support, Non-U.S. Gov't, Review
PMID
30050094
Read the original study →

Original abstract

Considerable interest surrounds the use of immune-checkpoint inhibitors in patients with solid tumours following the demonstration of the impressive clinical efficacy of anti-programmed cell death protein 1 and anti-programmed cell death 1 ligand 1 antibodies in several tumour types. However, the emergence of unexpected tumour response patterns, such as pseudoprogression or hyperprogression, might complicate the management of patients receiving these agents. Analysis of circulating tumour DNA (ctDNA) has been shown to have prognostic value by enabling the detection of residual proliferating disease in the adjuvant setting and estimation of tumour burden in the metastatic setting, which are key stratification biomarkers for use of immune-checkpoint inhibition (ICI). Furthermore, examinations of ctDNA for genetic predictors of responsiveness to immunotherapy, such as mutations, tumour mutational load, and microsatellite instability provide a noninvasive surrogate for tumour biopsy sampling. Proof-of-concept reports have also demonstrated that quantitative changes in ctDNA levels early in the course of disease are a promising tool for the assessment of responsiveness to ICI that might complement standard imaging approaches. Other applications of this technology are also currently under investigation, such as early detection of resistance to immunotherapy and characterization of mechanisms of resistance. The aim of this Review is to summarize available data on the application of ctDNA in patients receiving immunotherapy and to discuss the most promising future directions.