Your search keyword '"Mouliere F"' showing total 88 results

1. Author Correction: Results of the phase IIa RADICAL trial of the FGFR inhibitor AZD4547 in endocrine resistant breast cancer

Author

Coombes, R. C., Badman, P. D., Lozano-Kuehne, J. P., Liu, X., Macpherson, I. R., Zubairi, I., Baird, R. D., Rosenfeld, N., Garcia-Corbacho, J., Cresti, N., Plummer, R., Armstrong, A., Allerton, R., Landers, D., Nicholas, H., McLellan, L., Lim, A., Mouliere, F., Pardo, O. E., Ferguson, V., and Seckl, M. J.

Published

2023

2. Recommendations for a practical implementation of circulating tumor DNA mutation testing in metastatic non-small-cell lung cancer

Author

Heitzer, E., van den Broek, D., Denis, M.G., Hofman, P., Hubank, M., Mouliere, F., Paz-Ares, L., Schuuring, E., Sültmann, H., Vainer, G., Verstraaten, E., de Visser, L., and Cortinovis, D.

Published

2022

3. Results of the phase IIa RADICAL trial of the FGFR inhibitor AZD4547 in endocrine resistant breast cancer

Author

Coombes, R. C., Badman, P. D., Lozano-Kuehne, J. P., Liu, X., Macpherson, I. R., Zubairi, I., Baird, R. D., Rosenfeld, N., Garcia-Corbacho, J., Cresti, N., Plummer, R., Armstrong, A., Allerton, R., Landers, D., Nicholas, H., McLellan, L., Lim, A., Mouliere, F., Pardo, O. E., and Seckl, M. J.

Published

2022

4. Recommendations for a practical implementation of circulating tumor DNA mutation testing in metastatic non-small-cell lung cancer

Author

Heitzer, E, van den Broek, D, Denis, M, Hofman, P, Hubank, M, Mouliere, F, Paz-Ares, L, Schuuring, E, Sültmann, H, Vainer, G, Verstraaten, E, de Visser, L, Cortinovis, D, Heitzer E, van den Broek D, Denis MG, Hofman P, Hubank M, Mouliere F, Paz-Ares L, Schuuring E, Sültmann H, Vainer G, Verstraaten E, de Visser L, Cortinovis D, Heitzer, E, van den Broek, D, Denis, M, Hofman, P, Hubank, M, Mouliere, F, Paz-Ares, L, Schuuring, E, Sültmann, H, Vainer, G, Verstraaten, E, de Visser, L, Cortinovis, D, Heitzer E, van den Broek D, Denis MG, Hofman P, Hubank M, Mouliere F, Paz-Ares L, Schuuring E, Sültmann H, Vainer G, Verstraaten E, de Visser L, and Cortinovis D

Abstract

Background: Liquid biopsy (LB) is a rapidly evolving diagnostic tool for precision oncology that has recently found its way into routine practice as an adjunct to tissue biopsy (TB). The concept of LB refers to any tumor-derived material, such as circulating tumor DNA (ctDNA) or circulating tumor cells that are detectable in blood. An LB is not limited to the blood and may include other fluids such as cerebrospinal fluid, pleural effusion, and urine, among others. Patients and methods: The objective of this paper, devised by international experts from various disciplines, is to review current challenges as well as state-of-the-art applications of ctDNA mutation testing in metastatic non-small-cell lung cancer (NSCLC). We consider pragmatic scenarios for the use of ctDNA from blood plasma to identify actionable targets for therapy selection in NSCLCs. Results: Clinical scenarios where ctDNA mutation testing may be implemented in clinical practice include complementary tissue and LB testing to provide the full picture of patients’ actual predictive profiles to identify resistance mechanism (i.e. secondary mutations), and ctDNA mutation testing to assist when a patient has a discordant clinical history and is suspected of showing intertumor or intratumor heterogeneity. ctDNA mutation testing may provide interesting insights into possible targets that may have been missed on the TB. Complementary ctDNA LB testing also provides an option if the tumor location is hard to biopsy or if an insufficient sample was taken. These clinical use cases highlight practical scenarios where ctDNA LB may be considered as a complementary tool to TB analysis. Conclusions: Proper implementation of ctDNA LB testing in routine clinical practice is envisioned in the near future. As the clinical evidence of utility expands, the use of LB alongside tissue sample analysis may occur in the patient cases detailed here.

Published

2022

5. The landscape of cell-free mitochondrial DNA in liquid biopsy for cancer detection

Author

van der Pol, Y, Moldovan, N, Ramaker, J, Bootsma, S, Lenos, KJ, Vermeulen, L, Sandhu, S, Bahce, I, Pegtel, DM, Wong, SQ, Dawson, S-J, Chandrananda, D, Mouliere, F, van der Pol, Y, Moldovan, N, Ramaker, J, Bootsma, S, Lenos, KJ, Vermeulen, L, Sandhu, S, Bahce, I, Pegtel, DM, Wong, SQ, Dawson, S-J, Chandrananda, D, and Mouliere, F

Abstract

BACKGROUND: Existing methods to detect tumor signal in liquid biopsy have focused on the analysis of nuclear cell-free DNA (cfDNA). However, non-nuclear cfDNA and in particular mitochondrial DNA (mtDNA) has been understudied. We hypothesize that an increase in mtDNA in plasma could reflect the presence of cancer, and that leveraging cell-free mtDNA could enhance cancer detection. RESULTS: We survey 203 healthy and 664 cancer plasma samples from three collection centers covering 12 cancer types with whole genome sequencing to catalogue the plasma mtDNA fraction. The mtDNA fraction is increased in individuals with cholangiocarcinoma, colorectal, liver, pancreatic, or prostate cancer, in comparison to that in healthy individuals. We detect almost no increase of mtDNA fraction in individuals with other cancer types. The mtDNA fraction in plasma correlates with the cfDNA tumor fraction as determined by somatic mutations and/or copy number aberrations. However, the mtDNA fraction is also elevated in a fraction of patients without an apparent increase in tumor-derived cfDNA. A predictive model integrating mtDNA and copy number analysis increases the area under the curve (AUC) from 0.73 when using copy number alterations alone to an AUC of 0.81. CONCLUSIONS: The mtDNA signal retrieved by whole genome sequencing has the potential to boost the detection of cancer when combined with other tumor-derived signals in liquid biopsies.

Published

2023

6. Prediction of pathologic complete response after single-dose MR-guided partial breast irradiation in low-risk breast cancer patients: the ABLATIVE-2 trial-a study protocol.

Author

Civil, Y.A., Oei, A.L.M., Duvivier, K.M., Bijker, N., Meijnen, P., Donkers, L., Verheijen, S., Kesteren, Z. van, Palacios, M.A., Schijf, L.J., Barbé, E., Konings, Irene B. M., Menke-van der Houven van Oordt, C.W., Westhoff, P.G., Meijer, H.J.M., Diepenhorst, G.M., Thijssen, V., Mouliere, F., Slotman, B.J., Velde, S. van de, Bongard, H.J.G.D. van den, Civil, Y.A., Oei, A.L.M., Duvivier, K.M., Bijker, N., Meijnen, P., Donkers, L., Verheijen, S., Kesteren, Z. van, Palacios, M.A., Schijf, L.J., Barbé, E., Konings, Irene B. M., Menke-van der Houven van Oordt, C.W., Westhoff, P.G., Meijer, H.J.M., Diepenhorst, G.M., Thijssen, V., Mouliere, F., Slotman, B.J., Velde, S. van de, and Bongard, H.J.G.D. van den

Abstract

Contains fulltext : 292749.pdf (Publisher’s version ) (Open Access), BACKGROUND: Partial breast irradiation (PBI) is standard of care in low-risk breast cancer patients after breast-conserving surgery (BCS). Pre-operative PBI can result in tumor downstaging and more precise target definition possibly resulting in less treatment-related toxicity. This study aims to assess the pathologic complete response (pCR) rate one year after MR-guided single-dose pre-operative PBI in low-risk breast cancer patients. METHODS: The ABLATIVE-2 trial is a multicenter prospective single-arm trial using single-dose ablative PBI in low-risk breast cancer patients. Patients ≥ 50 years with non-lobular invasive breast cancer ≤ 2 cm, grade 1 or 2, estrogen receptor-positive, HER2-negative, and tumor-negative sentinel node procedure are eligible. A total of 100 patients will be enrolled. PBI treatment planning will be performed using a radiotherapy planning CT and -MRI in treatment position. The treatment delivery will take place on a conventional or MR-guided linear accelerator. The prescribed radiotherapy dose is a single dose of 20 Gy to the tumor, and 15 Gy to the 2 cm of breast tissue surrounding the tumor. Follow-up MRIs, scheduled at baseline, 2 weeks, 3, 6, 9, and 12 months after PBI, are combined with liquid biopsies to identify biomarkers for pCR prediction. BCS will be performed 12 months after radiotherapy or after 6 months, if MRI does not show a radiologic complete response. The primary endpoint is the pCR rate after PBI. Secondary endpoints are radiologic response, toxicity, quality of life, cosmetic outcome, patient distress, oncological outcomes, and the evaluation of biomarkers in liquid biopsies and tumor tissue. Patients will be followed up to 10 years after radiation therapy. DISCUSSION: This trial will investigate the pathological tumor response after pre-operative single-dose PBI after 12 months in patients with low-risk breast cancer. In comparison with previous trial outcomes, a longer interval between PBI and BCS of 12 months is exp

Published

2023

7. Characteristics, origin, and potential for cancer diagnostics of ultrashort plasma cell-free DNA

Author

Hudecova, I, Smith, CG, Hansel-Hertsch, R, Chilamakuri, CS, Morris, JA, Vijayaraghavan, A, Heider, K, Chandrananda, D, Cooper, WN, Gale, D, Garcia-Corbacho, J, Pacey, S, Baird, RD, Rosenfeld, N, Mouliere, F, Hudecova, I, Smith, CG, Hansel-Hertsch, R, Chilamakuri, CS, Morris, JA, Vijayaraghavan, A, Heider, K, Chandrananda, D, Cooper, WN, Gale, D, Garcia-Corbacho, J, Pacey, S, Baird, RD, Rosenfeld, N, and Mouliere, F

Abstract

Current evidence suggests that plasma cell-free DNA (cfDNA) is fragmented around a mode of 166 bp. Data supporting this view has been mainly acquired through the analysis of double-stranded cfDNA. The characteristics and diagnostic potential of single-stranded and damaged double-stranded cfDNA in healthy individuals and cancer patients remain unclear. Here, through a combination of high-affinity magnetic bead-based DNA extraction and single-stranded DNA sequencing library preparation (MB-ssDNA), we report the discovery of a large proportion of cfDNA fragments centered at ∼50 bp. We show that these "ultrashort" cfDNA fragments have a greater relative abundance in plasma of healthy individuals (median = 19.1% of all sequenced cfDNA fragments, n = 28) than in plasma of patients with cancer (median = 14.2%, n = 21, P < 0.0001). The ultrashort cfDNA fragments map to accessible chromatin regions of blood cells, particularly in promoter regions with the potential to adopt G-quadruplex (G4) DNA secondary structures. G4-positive promoter chromatin accessibility is significantly enriched in ultrashort plasma cfDNA fragments from healthy individuals relative to patients with cancers (P < 0.0001), in whom G4-cfDNA enrichment is inversely associated with copy number aberration-inferred tumor fractions. Our findings redraw the landscape of cfDNA fragmentation by identifying and characterizing a novel population of ultrashort plasma cfDNA fragments. Sequencing of MB-ssDNA libraries could facilitate the characterization of gene regulatory regions and DNA secondary structures via liquid biopsy. Our data underline the diagnostic potential of ultrashort cfDNA through classification for cancer patients.

Published

2022

8. Protective effect of BDNF against beta-amyloid induced neurotoxicity in vitro and in vivo in rats

Author

Arancibia, S., Silhol, M., Moulière, F., Meffre, J., Höllinger, I., Maurice, T., and Tapia-Arancibia, L.

Published

2008

9. Fragmentation patterns and personalized sequencing of cell-free DNA in urine and plasma of glioma patients

Author

Mouliere, F, Smith, CG, Heider, K, Su, J, van der Pol, Y, Thompson, M, Morris, J, Wan, JCM, Chandrananda, D, Hadfield, J, Grzelak, M, Hudecova, I, Couturier, D-L, Cooper, W, Zhao, H, Gale, D, Eldridge, M, Watts, C, Brindle, K, Rosenfeld, N, Mair, R, Mouliere, F, Smith, CG, Heider, K, Su, J, van der Pol, Y, Thompson, M, Morris, J, Wan, JCM, Chandrananda, D, Hadfield, J, Grzelak, M, Hudecova, I, Couturier, D-L, Cooper, W, Zhao, H, Gale, D, Eldridge, M, Watts, C, Brindle, K, Rosenfeld, N, and Mair, R

Abstract

Glioma-derived cell-free DNA (cfDNA) is challenging to detect using liquid biopsy because quantities in body fluids are low. We determined the glioma-derived DNA fraction in cerebrospinal fluid (CSF), plasma, and urine samples from patients using sequencing of personalized capture panels guided by analysis of matched tumor biopsies. By sequencing cfDNA across thousands of mutations, identified individually in each patient's tumor, we detected tumor-derived DNA in the majority of CSF (7/8), plasma (10/12), and urine samples (10/16), with a median tumor fraction of 6.4 × 10-3 , 3.1 × 10-5 , and 4.7 × 10-5 , respectively. We identified a shift in the size distribution of tumor-derived cfDNA fragments in these body fluids. We further analyzed cfDNA fragment sizes using whole-genome sequencing, in urine samples from 35 glioma patients, 27 individuals with non-malignant brain disorders, and 26 healthy individuals. cfDNA in urine of glioma patients was significantly more fragmented compared to urine from patients with non-malignant brain disorders (P = 1.7 × 10-2 ) and healthy individuals (P = 5.2 × 10-9 ). Machine learning models integrating fragment length could differentiate urine samples from glioma patients (AUC = 0.80-0.91) suggesting possibilities for truly non-invasive cancer detection.

Published

2021

10. ctDNA monitoring using patient-specific sequencing and integration of variant reads

Author

Wan, JCM, Heider, K, Gale, D, Murphy, S, Fisher, E, Mouliere, F, Ruiz-Valdepenas, A, Santonja, A, Morris, J, Chandrananda, D, Marshall, A, Gill, AB, Chan, PY, Barker, E, Young, G, Cooper, WN, Hudecova, I, Marass, F, Mair, R, Brindle, KM, Stewart, GD, Abraham, JE, Caldas, C, Rassl, DM, Rintoul, RC, Alifrangis, C, Middleton, MR, Gallagher, FA, Parkinson, C, Durrani, A, McDermott, U, Smith, CG, Massie, C, Corrie, PG, Rosenfeld, N, Wan, JCM, Heider, K, Gale, D, Murphy, S, Fisher, E, Mouliere, F, Ruiz-Valdepenas, A, Santonja, A, Morris, J, Chandrananda, D, Marshall, A, Gill, AB, Chan, PY, Barker, E, Young, G, Cooper, WN, Hudecova, I, Marass, F, Mair, R, Brindle, KM, Stewart, GD, Abraham, JE, Caldas, C, Rassl, DM, Rintoul, RC, Alifrangis, C, Middleton, MR, Gallagher, FA, Parkinson, C, Durrani, A, McDermott, U, Smith, CG, Massie, C, Corrie, PG, and Rosenfeld, N

Abstract

Circulating tumor-derived DNA (ctDNA) can be used to monitor cancer dynamics noninvasively. Detection of ctDNA can be challenging in patients with low-volume or residual disease, where plasma contains very few tumor-derived DNA fragments. We show that sensitivity for ctDNA detection in plasma can be improved by analyzing hundreds to thousands of mutations that are first identified by tumor genotyping. We describe the INtegration of VAriant Reads (INVAR) pipeline, which combines custom error-suppression methods and signal-enrichment approaches based on biological features of ctDNA. With this approach, the detection limit in each sample can be estimated independently based on the number of informative reads sequenced across multiple patient-specific loci. We applied INVAR to custom hybrid-capture sequencing data from 176 plasma samples from 105 patients with melanoma, lung, renal, glioma, and breast cancer across both early and advanced disease. By integrating signal across a median of >105 informative reads, ctDNA was routinely quantified to 1 mutant molecule per 100,000, and in some cases with high tumor mutation burden and/or plasma input material, to parts per million. This resulted in median area under the curve (AUC) values of 0.98 in advanced cancers and 0.80 in early-stage and challenging settings for ctDNA detection. We generalized this method to whole-exome and whole-genome sequencing, showing that INVAR may be applied without requiring personalized sequencing panels so long as a tumor mutation list is available. As tumor sequencing becomes increasingly performed, such methods for personalized cancer monitoring may enhance the sensitivity of cancer liquid biopsies.

Published

2020

11. EP-1368 Circulating cell free DNA during chemoradiotherapy in non-small cell lung cancer patients

Author

Nygaard, L., primary, Ahlborn, L., additional, Persson, G., additional, Chandrananda, D., additional, Langer, J., additional, Fischer, B.M., additional, Aznar, M., additional, Langer, S., additional, Gabrielaite, M., additional, Kjær, A., additional, Rosenfeld, N., additional, Mouliere, F., additional, Østrup, O., additional, Vogelius, I., additional, and Bentzen, S., additional

Published

2019

12. PO-483 Improved sensitivity for non-invasive diagnosis of high-grade serous ovarian cancer

Author

Moore, E., primary, Chandrananda, D., additional, Piskorz, A., additional, Mouliere, F., additional, Goranova, T., additional, Addley, H., additional, Crawford, R., additional, Parkinson, C., additional, Rosenfeld, N., additional, and Brenton, J., additional

Published

2018

13. The value of cell-free DNA for molecular pathology

Author

Stewart, CM, Kothari, PD, Mouliere, F, Mair, R, Somnay, S, Benayed, R, Zehir, A, Weigelt, B, Dawson, S-J, Arcila, ME, Berger, MF, Tsui, DWY, Stewart, CM, Kothari, PD, Mouliere, F, Mair, R, Somnay, S, Benayed, R, Zehir, A, Weigelt, B, Dawson, S-J, Arcila, ME, Berger, MF, and Tsui, DWY

Published

2018

14. Association Of Plasma And Urinary Mutant DNA With Clinical Outcomes In Muscle Invasive Bladder Cancer

Author

Patel, K. M., primary, van der Vos, K. E., additional, Smith, C. G., additional, Mouliere, F., additional, Tsui, D., additional, Morris, J., additional, Chandrananda, D., additional, Marass, F., additional, van den Broek, D., additional, Neal, D. E., additional, Gnanapragasam, V. J., additional, Forshew, T., additional, van Rhijn, B. W., additional, Massie, C. E., additional, Rosenfeld, N., additional, and van der Heijden, M. S., additional

Published

2017

15. Monitoring metastatic melanoma treatment resistance using circulating tumour DNA

Author

Murphy, S., primary, Wan, J., additional, Gale, D., additional, Morris, J., additional, Mouliere, F., additional, Bignell, G., additional, Alifrangis, C., additional, Parkinson, C., additional, Durrani, A., additional, McDermott, U., additional, Massie, C., additional, Corrie, P., additional, and Rosenfeld, N., additional

Published

2016

16. Circulating cell free DNA: Preanalytical considerations

Author

Messaoudi, S. El, Rolet, F., Mouliere, F., Thierry, A.R., Messaoudi, S. El, Rolet, F., Mouliere, F., and Thierry, A.R.

Abstract

Item does not contain fulltext, Despite the growing interest in circulating cell-free DNA (ccfDNA) analysis in various clinical fields, especially oncology and prenatal diagnosis, few studies on sample handling have been reported and no analytical consensus is available. The lack of consistency between the various protocols for sample handling and the techniques used for ccfDNA analysis is one of the major obstacles in translating ccfDNA analysis to clinical practice. Although this point is highlighted regularly in the published reviews on ccfDNA analysis, no standard operating procedure currently exists despite several ongoing clinical studies on ccfDNA analysis. This review examines the preanalytical parameters potentially affecting ccfDNA concentration and fragmentation at each preanalytical step from blood drawing to the storage of ccfDNA extracts. Analysis of data in the literature and our own observations revealed the influence of preanalytical factors on ccfDNA analysis. Based on these data, we determined the optimal preanalytical protocols for ccfDNA analysis and ultimately, a guideline for the translation of ccfDNA analysis in routine clinical practice.

Published

2013

17. Circulating Cell-Free DNA from Colorectal Cancer Patients May Reveal High KRAS or BRAF Mutation Load

Author

Mouliere, F., Messaoudi, S. El, Gongora, C., Guedj, A.S., Robert, B., Rio, M. del, Molina, F., Lamy, P.J., Lopez-Crapez, E., Mathonnet, M., Ychou, M., Pezet, D., Thierry, A.R., Mouliere, F., Messaoudi, S. El, Gongora, C., Guedj, A.S., Robert, B., Rio, M. del, Molina, F., Lamy, P.J., Lopez-Crapez, E., Mathonnet, M., Ychou, M., Pezet, D., and Thierry, A.R.

Abstract

Contains fulltext : 119240.pdf (publisher's version ) (Open Access), We used a novel method based on allele-specific quantitative polymerase chain reaction (Intplex) for the analysis of circulating cell.free DNA (ccfDNA) to compare total ccfDNA and KRAS- or BRAF-mutated ccfDNA concentrations in blood samples from mice xenografted with the human SW620 colorectal cancer (CRC) cell line and from patients with CRC. Intplex enables single-copy detection of variant alleles down to a sensitivity of >/=0.005 mutant to wild-type ratio. The proportion of mutant allele corresponding to the percentage of tumor-derived ccfDNA was elevated in xenografted mice with KRAS homozygous mutation and varied highly from 0.13% to 68.7% in samples from mutation-positive CRC patients (n = 38). Mutant ccfDNA alleles were quantified in the plasma of every patient at stages II/III and IV with a mean of 8.4% (median, 8.4%) and 21.8% (median, 12.4%), respectively. Twelve of 38 (31.6%) and 5 of 38 (13.2%) samples showed a mutation load higher than 25%and 50%, respectively. This suggests that an important part of ccfDNA may originate from tumor cells. In addition, we observed that tumor-derived (mutant) ccfDNA was more fragmented than ccfDNA from normal tissues. This observation suggests that the form of tumor-derived and normal ccfDNA could differ. Our approach revealed that allelic dilution is much less pronounced than previously stated, considerably facilitating the noninvasive molecular analysis of tumors.

Published

2013

18. 853 - Monitoring metastatic melanoma treatment resistance using circulating tumour DNA

Author

Murphy, S., Wan, J., Gale, D., Morris, J., Mouliere, F., Bignell, G., Alifrangis, C., Parkinson, C., Durrani, A., McDermott, U., Massie, C., Corrie, P., and Rosenfeld, N.

Published

2016

19. Lectures

Author

Chen, D. S., primary, Feltquate, D. M., additional, Smothers, F., additional, Hoos, A., additional, Langermann, S., additional, Marshall, S., additional, May, R., additional, Fleming, M., additional, Hodi, F. S., additional, Senderowicz, A., additional, Wiman, K. G., additional, de Dosso, S., additional, Fiedler, W., additional, Gianni, L., additional, Cresta, S., additional, Schulze-Bergkamen, H. B., additional, Gurrieri, L., additional, Salzberg, M., additional, Dietrich, B., additional, Danielczyk, A., additional, Baumeister, H., additional, Goletz, S., additional, Sessa, C., additional, Strumberg, D., additional, Schultheis, B., additional, Santel, A., additional, Gebhardt, F., additional, Meyer-Sabellek, W., additional, Keil, O., additional, Giese, K., additional, Kaufmann, J., additional, Maio, M., additional, Choy, G., additional, Covre, A., additional, Parisi, G., additional, Nicolay, H., additional, Fratta, E., additional, Fonsatti, E., additional, Sigalotti, L., additional, Coral, S., additional, Taverna, P., additional, Azab, M., additional, Deutsch, E., additional, Lepechoux, C., additional, Pignon, J. P., additional, Tao, Y. T., additional, Rivera, S., additional, Bourgier, B. C., additional, Angokai, M., additional, Bahleda, R., additional, Slimane, K., additional, Angevin, E., additional, Besse, B. B., additional, Soria, J. C., additional, Dragnev, K., additional, Beumer, J. H., additional, Anyang, B., additional, Ma, T., additional, Galimberti, F., additional, Erkmen, C. P., additional, Nugent, W., additional, Rigas, J., additional, Abraham, K., additional, Johnstone, D., additional, Memoli, V., additional, Dmitrovsky, E., additional, Voest, E. E., additional, Siu, L., additional, Janku, F., additional, Tsimberidou, A., additional, Kurzrock, R., additional, Tabernero, J., additional, Rodon, J., additional, Berger, R., additional, Onn, A., additional, Batist, G., additional, Bresson, C., additional, Lazar, V., additional, Molenaar, J. J., additional, Koster, J., additional, Ebus, M., additional, Zwijnenburg, D. A., additional, van Sluis, P., additional, Lamers, F., additional, Schild, L., additional, van der Ploeg, I., additional, Caron, H. N., additional, Versteeg, R., additional, Pouyssegur, J., additional, Marchiq, I., additional, Chiche, J., additional, Roux, D., additional, Le Floch, R., additional, Critchlow, S. E., additional, Wooster, R. F., additional, Agresta, S., additional, Yen, K. E., additional, Janne, P. A., additional, Plummer, E. R., additional, Trinchieri, G., additional, Ellis, L., additional, Chan, S. L., additional, Yeo, W., additional, Chan, A. T., additional, Mouliere, F., additional, El Messaoudi, S., additional, Gongora, C., additional, Lamy, P. J., additional, del Rio, M., additional, Lopez-Crapez, E., additional, Gillet, B., additional, Mathonnet, M., additional, Pezet, D., additional, Ychou, M., additional, Thierry, A. R., additional, Ribrag, V., additional, Vainchenker, W., additional, Constantinescu, S., additional, Keilhack, H., additional, Umelo, I. A., additional, Noeparast, A., additional, Chen, G., additional, Renard, M., additional, Geers, C., additional, Vansteenkiste, J., additional, Teugels, E., additional, de Greve, J., additional, Rixe, O., additional, Qi, X., additional, Chu, Z., additional, Celerier, J., additional, Leconte, L., additional, Minet, N., additional, Pakradouni, J., additional, Kaur, B., additional, Cuttitta, F., additional, Wagner, A. J., additional, Zhang, Y. X., additional, Sicinska, E., additional, Czaplinski, J. T., additional, Remillard, S. P., additional, Demetri, G. D., additional, Weng, S., additional, Debussche, L., additional, Agoni, L., additional, Reddy, E. P., additional, Guha, C., additional, Silence, K., additional, Thibault, A., additional, de Haard, H., additional, Dreier, T., additional, Ulrichts, P., additional, Moshir, M., additional, Gabriels, S., additional, Luo, J., additional, Carter, C., additional, Rajan, A., additional, Khozin, S., additional, Thomas, A., additional, Lopez-Chavez, A., additional, Brzezniak, C., additional, Doyle, L., additional, Keen, C., additional, Manu, M., additional, Raffeld, M., additional, Giaccone, G., additional, Lutzker, S., additional, Melief, J. M., additional, Eckhardt, S. G., additional, Trusolino, L., additional, Migliardi, G., additional, Zanella, E. R., additional, Cottino, F., additional, Galimi, F., additional, Sassi, F., additional, Marsoni, S., additional, Comoglio, P. M., additional, Bertotti, A., additional, Hidalgo, M., additional, Weroha, S. J., additional, Haluska, P., additional, Becker, M. A., additional, Harrington, S. C., additional, Goodman, K. M., additional, Gonzalez, S. E., additional, al Hilli, M., additional, Butler, K. A., additional, Kalli, K. R., additional, Oberg, A. L., additional, Huijbers, I. J., additional, Bin Ali, R., additional, Pritchard, C., additional, Cozijnsen, M., additional, Proost, N., additional, Song, J. Y., additional, Krimpenfort, P., additional, Michalak, E., additional, Jonkers, J., additional, Berns, A., additional, Banerji, U., additional, Stewart, A., additional, Thavasu, P., additional, Banerjee, S., additional, and Kaye, S. B., additional

Published

2013

20. Personalized Medicine by Analyzing Circulating DNA: Application to the Management Care of Colorectal Cancer Patients

Author

Mouliere, F., primary, El Messaoudi, S., additional, Gongora, C., additional, Lamy, P.J., additional, del Rio, M., additional, Lopez-Crapez, E., additional, Gillet, B., additional, Mathonnet, M., additional, Pezet, D., additional, Ychou, M., additional, and Thierry, A.R., additional

Published

2013

21. Technology & tools development

Author

Pefani, E., primary, Panoskaltsis, N., additional, Mantalaris, A., additional, Georgiadis, M. C., additional, Pistikopoulos, E. N., additional, Aguilar-Mahecha, A., additional, Lafleur, J., additional, Seguin, C., additional, Rosenbloom, M., additional, Przybytkowski, E., additional, Pelmus, M., additional, Diaz, Z., additional, Batist, G., additional, Basik, M., additional, Tavernier, J., additional, Brunet, L., additional, Bazot, J., additional, Chemelle, M., additional, Dalban, C., additional, Guiu, S., additional, di Martino, C., additional, Lehtio, J., additional, Branca, M., additional, Johansson, H., additional, Orre, M., additional, Granholm, V., additional, Forshed, J., additional, Perez-Bercoff, M., additional, Kall, L., additional, Nielsen, K. V., additional, Andresen, L., additional, Muller, S., additional, Matthiesen, S., additional, Schonau, A., additional, Oktriani, R., additional, Wahyono, A., additional, Haryono, S., additional, Utomo, A., additional, Aryandono, T., additional, Gagnon-Kugler, T., additional, Rousseau, C., additional, Alcindor, T., additional, Aloyz, R., additional, Assouline, S., additional, Bachvarov, D., additional, Belanger, L., additional, Camlioglu, E., additional, Cartillone, M., additional, Chabot, B., additional, Christodoulopoulos, R., additional, Courtemanche, C., additional, Constantin, A., additional, Benlimame, N., additional, Dao, I., additional, Dalfen, R., additional, Gosselin, L., additional, Habbab, F., additional, Hains, M., additional, Haliotis, T., additional, Nielsen, T. H., additional, Joncas, M., additional, Kavan, P., additional, Klink, R., additional, Langlaben, A., additional, Lebel, M., additional, Lesperance, B., additional, Mann, K., additional, Masson, J., additional, Metrakos, P., additional, McNamara, S., additional, Miller, W. H., additional, Orain, M., additional, Panasci, L., additional, Paquet, E., additional, Phillie, M., additional, Qureshi, S., additional, Rodrigue, D., additional, Salman, A., additional, Spatz, A., additional, Tetu, B., additional, Tosikyan, A., additional, Tsatoumas, M., additional, Vuong, T., additional, Ruijtenbeek, R., additional, Houtman, R., additional, de Wijn, R., additional, Boender, P., additional, Hilhorst, R., additional, Cohen, Y., additional, Onn, A., additional, Lax, A., additional, Yosepovich, A., additional, Litz, S., additional, Kalish, S., additional, Felemovicius, R., additional, Hout-Silony, G., additional, Gutman, M., additional, Shabtai, M., additional, Rosin, D., additional, Valeanu, A., additional, Winkler, E., additional, Sklair-Levy, M., additional, Kaufman, B., additional, Barshack, I., additional, Canu, V., additional, Sacconi, A., additional, Biagioni, F., additional, Mori, F., additional, di Benedetto, A., additional, Lorenzon, L., additional, di Agostino, S., additional, Cambria, A., additional, Germoni, S., additional, Grasso, G., additional, Blandino, R., additional, Panebianco, V., additional, Ziparo, V., additional, Federici, O., additional, Muti, P., additional, Strano, S., additional, Carboni, F., additional, Mottolese, M., additional, Diodoro, M. G., additional, Pescarmona, E., additional, Garofalo, A., additional, Blandino, G., additional, Ho, T., additional, Feng, L., additional, Lintula, S., additional, Orpana, K. A., additional, Stenman, J., additional, El Messaoudi, S., additional, Mouliere, F., additional, del Rio, M., additional, Guedj, A. S., additional, Gongora, C., additional, Molina, F. M., additional, Lamy, P. J., additional, Lopez-Crapez, E., additional, Rolet, F., additional, Mathonnet, M., additional, Ychou, M., additional, Pezet, D., additional, Thierry, A. R., additional, Manuarii, M., additional, Tredan, O., additional, Bachelot, T., additional, Clapisson, G., additional, Courtier, A., additional, Parmentier, G., additional, Rabeony, T., additional, Grives, A., additional, Perez, S., additional, Mouret, J. F., additional, Perol, D., additional, Chabaud, S., additional, Ray-Coquard, I., additional, Labidi-Galy, I., additional, Heudel, P., additional, Pierga, J. Y., additional, Caux, C., additional, Blay, J. Y., additional, Pasqual, N., additional, and Menetrier-Caux, C., additional

Published

2012

22. P3.12 Circulating Dna Analysis in The Era of Personalized Cancer Medicine: Application to Kras/Braf Point Mutations Detection in Colorectal Cancer

Author

El Messaoudi, S., primary, Mouliere, F., additional, del Rio, M., additional, Guedj, A.S., additional, Gongora, C., additional, Molina, F.M., additional, Lamy, P.J., additional, Lopez-Crapez, E., additional, Rolet, F., additional, Mathonnet, M., additional, Ychou, M., additional, Pezet, D., additional, and Thierry, A.R., additional

Published

2012

23. L06.06 - Personalized Medicine by Analyzing Circulating DNA: Application to the Management Care of Colorectal Cancer Patients

Author

Mouliere, F., El Messaoudi, S., Gongora, C., Lamy, P.J., del Rio, M., Lopez-Crapez, E., Gillet, B., Mathonnet, M., Pezet, D., Ychou, M., and Thierry, A.R.

Published

2013

24. R86: Origine et quantification des ADN circulants dans des souris xénogreffées et chez des patients atteints de cancer colorectal

Author

Arnau Peyrotte, E., Moulière, F., Robert, B., Ollier, J., Del Rio, M., Ychou, M., Gongora, C., Molina, F., and Thierry, A.R.

Published

2010

25. Liquid biopsies come of age: towards implementation of circulating tumour DNA

Author

Wan, JCM, Massie, C, Garcia-Corbacho, J, Mouliere, F, Brenton, J, Caldas, C, Pacey, S, Baird, RD, and Rosenfeld, N

Subjects

cancer genomics, cancer screening, DNA, personalized medicine, cancer therapeutic resistance, 3. Good health

Abstract

Improvements in genomic and molecular methods are expanding the range of potential applications for circulating tumour DNA (ctDNA), both in a research setting and as a ‘liquid biopsy’ for cancer management. Proof-of-principle studies have demonstrated the translational potential of ctDNA for prognostication, molecular profiling and monitoring. The field is now in an exciting transitional period in which ctDNA analysis is beginning to be applied clinically, although there is still much to learn about the biology of cell-free DNA. This is an opportune time to appraise potential approaches to ctDNA analysis, and to consider their applications in personalized oncology and in cancer research.

26. Association Of Plasma And Urinary Mutant DNA With Clinical Outcomes In Muscle Invasive Bladder Cancer

Author

Patel, KM, Van Der Vos, KE, Smith, CG, Mouliere, F, Tsui, D, Morris, J, Chandrananda, D, Marass, F, Van Den Broek, D, Neal, DE, Gnanapragasam, VJ, Forshew, T, Van Rhijn, BW, Massie, CE, Rosenfeld, N, and Van Der Heijden, MS

Subjects

Male, Genome, Human, DNA, Neoplasm, Middle Aged, Neoadjuvant Therapy, 3. Good health, Treatment Outcome, Urinary Bladder Neoplasms, Mutation, Humans, Female, Neoplasm Recurrence, Local, Aged, Follow-Up Studies

Abstract

Muscle Invasive Bladder Cancer (MIBC) has a poor prognosis. Whilst patients can achieve a 6% improvement in overall survival with Neo-Adjuvant Chemotherapy (NAC), many do not respond. Body fluid mutant DNA (mutDNA) may allow non-invasive identification of treatment failure. We collected 248 liquid biopsy samples including plasma, cell pellet (UCP) and supernatant (USN) from spun urine, from 17 patients undergoing NAC. We assessed single nucleotide variants and copy number alterations in mutDNA using Tagged-Amplicon- and shallow Whole Genome- Sequencing. MutDNA was detected in 35.3%, 47.1% and 52.9% of pre-NAC plasma, UCP and USN samples respectively, and urine samples contained higher levels of mutDNA (p =

27. Results of the phase IIa RADICAL trial of the FGFR inhibitor AZD4547 in endocrine resistant breast cancer

Author

R. C. Coombes, P. D. Badman, J. P. Lozano-Kuehne, X. Liu, I. R. Macpherson, I. Zubairi, R. D. Baird, N. Rosenfeld, J. Garcia-Corbacho, N. Cresti, R. Plummer, A. Armstrong, R. Allerton, D. Landers, H. Nicholas, L. McLellan, A. Lim, F. Mouliere, O. E. Pardo, V. Ferguson, M. J. Seckl, CCA - Cancer Treatment and quality of life, Coombes, RC [0000-0002-4811-1100], Badman, PD [0000-0002-0337-3190], Lozano-Kuehne, JP [0000-0002-7372-0725], Macpherson, IR [0000-0003-4295-8885], Baird, RD [0000-0001-7071-6483], Rosenfeld, N [0000-0002-2825-4788], Garcia-Corbacho, J [0000-0002-6109-8449], Cresti, N [0000-0002-0495-4472], Landers, D [0000-0001-8376-9779], Mouliere, F [0000-0001-7043-0514], Pardo, OE [0000-0003-2223-1435], Seckl, MJ [0000-0003-4078-2599], and Apollo - University of Cambridge Repository

Subjects

Multidisciplinary, Treatment Outcome, Benzamides, General Physics and Astronomy, Humans, Pyrazoles, Antineoplastic Agents, Breast Neoplasms, Female, General Chemistry, General Biochemistry, Genetics and Molecular Biology, Piperazines

Abstract

We conducted a phase IIa, multi-centre, open label, single arm study (RADICAL; NCT01791985) of AZD4547 (a potent and selective inhibitor of Fibroblast Growth Factor Receptor (FGFR)-1, 2 and 3 receptor tyrosine kinases) administered with anastrozole or letrozole in estrogen receptor positive metastatic breast cancer patients who had become resistant to aromatase inhibitors. After a safety run-in study to assess safety and tolerability, we recruited 52 patients. The primary endpoint was change in tumour size at 12 weeks, and secondary endpoints were to assess response at 6 weeks, 20 weeks and every 8 weeks thereafter and tolerability of the combined treatment. Two partial responses (PR) and 19 stable disease (SD) patients were observed at the 12-week time point. At 28 weeks, according to centrally reviewed Response Evaluation Criteria in Solid Tumours (RECIST) criteria, five PR and 8 SD patients were observed in 50 assessable cases. Overall, objective response rate (5 PR) was of 10%, meeting the pre-specified endpoint. Fourteen patients discontinued due to adverse events. Eleven patients had retinal pigment epithelial detachments which was asymptomatic and reversible in all but one patient. Exploratory ribonucleic acid sequencing (RNA-Seq) analysis was done on patients’ samples: 6 differentially-expressed-genes could distinguish those who benefited from the addition of AZD4547.

Published

2022

28. Nanopore-based consensus sequencing enables accurate multimodal tumor cell-free DNA profiling.

Author

Chen LT, Jager M, Rebergen D, Brink GJ, van den Ende T, Vanderlinden W, Kolbeck P, Pagès-Gallego M, van der Pol Y, Besselink N, Moldovan N, Hami N, Kloosterman WP, van Laarhoven H, Mouliere F, Zweemer R, Lipfert J, Derks S, Marcozzi A, and de Ridder J

Abstract

Shallow genome-wide cell-free DNA (cfDNA) sequencing holds great promise for non-invasive cancer monitoring by providing reliable copy number alteration (CNA) and fragmentomic profiles. Single nucleotide variations (SNVs) are, however, much harder to identify with low sequencing depth due to sequencing errors. Here we present Nanopore Rolling Circle Amplification (RCA)-enhanced Consensus Sequencing (NanoRCS), which leverages RCA and consensus calling based on genome-wide long-read nanopore sequencing to enable simultaneous multimodal tumor fraction estimation through SNVs, CNAs, and fragmentomics. Efficacy of NanoRCS is tested on 18 cancer patient samples and seven healthy controls, demonstrating its ability to reliably detect tumor fractions as low as 0.24%. In vitro experiments confirm that SNV measurements are essential for detecting tumor fractions below 3%. NanoRCS provides the opportunity for cost-effective and rapid processing, which aligns well with clinical needs, particularly in settings where quick and accurate cancer monitoring is essential for personalized treatment strategies., (Published by Cold Spring Harbor Laboratory Press.)

Published

2025

29. Cell-free and extrachromosomal DNA profiling of small cell lung cancer.

Author

Behrouzi R, Clipson A, Simpson KL, Blackhall F, Rothwell DG, Dive C, and Mouliere F

Subjects

Humans, Liquid Biopsy methods, DNA Methylation, Mutation, Small Cell Lung Carcinoma genetics, Small Cell Lung Carcinoma diagnosis, Small Cell Lung Carcinoma blood, Small Cell Lung Carcinoma pathology, Lung Neoplasms genetics, Lung Neoplasms diagnosis, Lung Neoplasms blood, Lung Neoplasms pathology, Cell-Free Nucleic Acids genetics, Cell-Free Nucleic Acids blood, Biomarkers, Tumor genetics, Circulating Tumor DNA genetics, Circulating Tumor DNA blood

Abstract

Small cell lung cancer (SCLC) is highly aggressive with poor prognosis. Despite a relative prevalence of circulating tumour DNA (ctDNA) in SCLC, liquid biopsies are not currently implemented, unlike non-SCLC where cell-free DNA (cfDNA) mutation profiling in the blood has utility for guiding targeted therapies and assessing minimal residual disease. cfDNA methylation profiling is highly sensitive for SCLC detection and holds promise for disease monitoring and molecular subtyping; cfDNA fragmentation profiling has also demonstrated clinical potential. Extrachromosomal DNA (ecDNA), that is often observed in SCLC, promotes tumour heterogeneity and chemotherapy resistance and can be detected in blood. We discuss how these cfDNA profiling modalities can be harnessed to expand the clinical applications of liquid biopsy in SCLC., Competing Interests: Declaration of interests F.M. is a coinventor on patents related to fragmentomic methods. F.M has consulted for Roche Dx. C.D. receives research grants/support from AstraZeneca, Astex Pharmaceuticals, Bioven, Amgen, Carrick Therapeutics, Merck AG, Taiho Oncology, GSK, Bayer, Boehringer Ingelheim, Roche, BMS, Novartis, Celgene, Epigene Therapeutics Inc, Angle PLC, Menarini, Clearbridge Biomedics, Thermo Fisher Scientific, and Neomed Therapeutics. C.D. has received/receives honoraria/consultancy fees from Biocartis, Merck, AstraZeneca, and GRAIL. F.B. has consulted for AstraZeneca, Boehringer Ingelheim, and Amgen. The other authors declare no competing interests., (Copyright © 2024 The Author(s). Published by Elsevier Ltd.. All rights reserved.)

Published

2025

30. Integrating Clinical Variables, Radiomics, and Tumor-derived Cell-Free DNA for Enhanced Prediction of Resectable Esophageal Adenocarcinoma Outcomes.

Author

Ende TVD, Kuijper SC, Widaatalla Y, Noortman WA, van Velden FHP, Woodruff HC, van der Pol Y, Moldovan N, Pegtel DM, Derks S, Bijlsma MF, Mouliere F, de Geus-Oei LF, Lambin P, and van Laarhoven HWM

Subjects

Humans, Male, Female, Middle Aged, Aged, Retrospective Studies, Chemoradiotherapy, Neoadjuvant Therapy, Treatment Outcome, Adult, Radiomics, Esophageal Neoplasms pathology, Esophageal Neoplasms diagnostic imaging, Esophageal Neoplasms therapy, Esophageal Neoplasms mortality, Esophageal Neoplasms blood, Adenocarcinoma diagnostic imaging, Adenocarcinoma pathology, Adenocarcinoma blood, Adenocarcinoma therapy, Adenocarcinoma mortality, Adenocarcinoma genetics, Adenocarcinoma surgery, Cell-Free Nucleic Acids blood

Abstract

Purpose: The value of integrating clinical variables, radiomics, and tumor-derived cell-free DNA (cfDNA) for the prediction of survival and response to chemoradiation of patients with resectable esophageal adenocarcinoma is not yet known. Our aim was to investigate if radiomics and cfDNA metrics combined with clinical variables can improve personalized predictions., Methods and Materials: A cohort of 111 patients with resectable esophageal adenocarcinoma from 2 centers treated with neoadjuvant chemoradiation therapy was used for exploratory retrospective analyses. Models combining the clinical variables of the SOURCE survival model with radiomic features and cfDNA were built using elastic net regression and internally validated using 5-fold cross-validation. Model performance for overall survival (OS) and time to progression (TTP) were evaluated with the C-index and the area under the curve for pathologic complete response., Results: The best-performing baseline models for OS and TTP were based on the combination of SOURCE-cfDNA that reached a C-index of 0.55 and 0.59 compared with 0.44 to 0.45 with SOURCE alone. The addition of restaging positron emission tomography radiomics to SOURCE was the most promising addition for predicting OS (C-index: 0.65) and TTP (C-index: 0.60). Baseline risk stratification was achieved for OS and TTP by combining SOURCE with radiomics or cfDNA, log-rank P < .01. The best-performing combination model for the prediction of pathologic complete response reached an area under the curve of 0.61 compared with 0.47 with SOURCE variables alone., Conclusions: The addition of radiomics and cfDNA can improve the performance of an established survival model. External validity needs to be further assessed in future studies together with the optimization of radiomic pipelines., (Copyright © 2024 The Author(s). Published by Elsevier Inc. All rights reserved.)

Published

2025

31. Mining nucleic acid "omics" to boost liquid biopsy in cancer.

Author

Tivey A, Lee RJ, Clipson A, Hill SM, Lorigan P, Rothwell DG, Dive C, and Mouliere F

Subjects

Humans, Liquid Biopsy methods, Precision Medicine methods, Epigenomics methods, Nucleic Acids genetics, Transcriptome genetics, Neoplasms genetics, Neoplasms pathology, Neoplasms diagnosis, Biomarkers, Tumor genetics, Genomics methods

Abstract

Treatments for cancer patients are becoming increasingly complex, and there is a growing desire from clinicians and patients for biomarkers that can account for this complexity to support informed decisions about clinical care. To achieve precision medicine, the new generation of biomarkers must reflect the spatial and temporal heterogeneity of cancer biology both between patients and within an individual patient. Mining the different layers of 'omics in a multi-modal way from a minimally invasive, easily repeatable, liquid biopsy has increasing potential in a range of clinical applications, and for improving our understanding of treatment response and resistance. Here, we detail the recent developments and methods allowing exploration of genomic, epigenomic, transcriptomic, and fragmentomic layers of 'omics from liquid biopsy, and their integration in a range of applications. We also consider the specific challenges that are posed by the clinical implementation of multi-omic liquid biopsies., Competing Interests: Declaration of interests F.M. is a co-inventor on multiple patents related to cfDNA analysis and has consulted for Roche Dx. A.C., S.M.H., D.G.R., and C.D. are co-inventors on a patent relating to cfDNA analysis. R.J.L. has received a speaker fee from Pierre Fabre and research funding from Bristol Myers Squibb, AstraZeneca, and Pierre Fabre. C.D. has received research funding/educational research grants since 2020 from the following: AstraZeneca, Amgen, Carrick Therapeutics, Merck AG, Bayer, Boehringer Ingelheim, BMS, Novartis, Celgene, Epigene Therapeutics Inc, and Menarini. C.D. has received honoraria for consultancy and/or advisory boards from Merck, AstraZeneca, GRAIL, and Boehringer Ingelheim., (Copyright © 2024 The Author(s). Published by Elsevier Inc. All rights reserved.)

Published

2024

32. Comparison of cell-free and small extracellular-vesicle-associated DNA by sequencing plasma of lung cancer patients.

Author

Moldovan N, Verkuijlen S, van der Pol Y, Bosch L, van Weering JRT, Bahce I, Pegtel DM, and Mouliere F

Abstract

Blood contains multiple analytes that can be used as liquid biopsy to analyze cancer. Mutations have been detected in DNA associated with small extracellular vesicles (sEVs). The genome-wide composition and structure of sEV DNA remains poorly characterized, and whether sEVs are enriched in tumor signal compared to cell-free DNA (cfDNA) is unclear. Here, using whole-genome sequencing from lung cancer patients we determined that the tumor fraction and heterogeneity are comparable between DNA associated with sEV (<200 nm) and matched plasma cfDNA. sEV DNA, obtained with size-exclusion chromatography, is composed of short ∼150-180 bp fragments and long >1000 bp fragments poor in tumor signal. The structural patterns of sEV DNA are related to plasma cfDNA. Mitochondrial DNA is relatively enriched in the sEV fractions. Our results suggest that DNA associated to sEV (including exosomes) is not preferentially enriched in tumor signal and is less abundant than cfDNA., Competing Interests: F.M. is coinventor on patents related to cfDNA fragmentation analysis. F.M. has consulted for Roche Dx. D.M.P. is co-founder and CSO of ExBiome BV. Other coauthors have no relevant conflict of interests., (© 2024 The Author(s).)

Published

2024

33. Turning the tide in aggressive lymphoma: liquid biopsy for risk-adapted treatment strategies.

Author

Wang S, Mouliere F, Pegtel DM, and Chamuleau MED

Subjects

Humans, Liquid Biopsy methods, Prognosis, Precision Medicine methods, Lymphoma, Large B-Cell, Diffuse diagnosis, Lymphoma, Large B-Cell, Diffuse drug therapy, Lymphoma, Large B-Cell, Diffuse pathology, Biomarkers, Tumor

Abstract

Diffuse large B cell lymphoma (DLBCL) exhibits significant biological and clinical heterogeneity that presents challenges for risk stratification and disease surveillance. Existing tools for risk stratification, including the international prognostic index (IPI), tissue molecular analyses, and imaging, have limited accuracy in predicting outcomes. The therapeutic landscape for aggressive lymphoma is rapidly evolving, and there is a pressing need to identify patients at risk of refractory or relapsed (R/R) disease in the context of personalized therapy. Liquid biopsy, a minimally invasive method for cancer signal detection, has been explored to address these challenges. We review advances in liquid biopsy strategies focusing on circulating nucleic acids in DLBCL patients and highlight their clinical potential. We also provide recommendations for biomarker-guided trials to support risk-adapted treatment modalities., Competing Interests: Declaration of interests The authors declare no competing interests., (Copyright © 2024 Elsevier Ltd. All rights reserved.)

Published

2024

34. Molecular analysis for ovarian cancer detection in patient-friendly samples.

Author

Wever BMM, Schaafsma M, Bleeker MCG, van den Burgt Y, van den Helder R, Lok CAR, Dijk F, van der Pol Y, Mouliere F, Moldovan N, van Trommel NE, and Steenbergen RDM

Abstract

Background: High ovarian cancer mortality rates motivate the development of effective and patient-friendly diagnostics. Here, we explored the potential of molecular testing in patient-friendly samples for ovarian cancer detection., Methods: Home-collected urine, cervicovaginal self-samples, and clinician-taken cervical scrapes were prospectively collected from 54 patients diagnosed with a highly suspicious ovarian mass (benign n = 25, malignant n = 29). All samples were tested for nine methylation markers, using quantitative methylation-specific PCRs that were verified on ovarian tissue samples, and compared to non-paired patient-friendly samples of 110 age-matched healthy controls. Copy number analysis was performed on a subset of urine samples of ovarian cancer patients by shallow whole-genome sequencing., Results: Three methylation markers are significantly elevated in full void urine of ovarian cancer patients as compared to healthy controls (C2CD4D, P = 0.008; CDO1, P = 0.022; MAL, P = 0.008), of which two are also discriminatory in cervical scrapes (C2CD4D, P = 0.001; CDO1, P = 0.004). When comparing benign and malignant ovarian masses, GHSR shows significantly elevated methylation levels in the urine sediment of ovarian cancer patients (P = 0.024). Other methylation markers demonstrate comparably high methylation levels in benign and malignant ovarian masses. Cervicovaginal self-samples show no elevated methylation levels in patients with ovarian masses as compared to healthy controls. Copy number changes are identified in 4 out of 23 urine samples of ovarian cancer patients., Conclusions: Our study reveals increased methylation levels of ovarian cancer-associated genes and copy number aberrations in the urine of ovarian cancer patients. Our findings support continued research into urine biomarkers for ovarian cancer detection and highlight the importance of including benign ovarian masses in future studies to develop a clinically useful test., (© 2024. The Author(s).)

Published

2024

35. Multi-modal cell-free DNA genomic and fragmentomic patterns enhance cancer survival and recurrence analysis.

Author

Moldovan N, van der Pol Y, van den Ende T, Boers D, Verkuijlen S, Creemers A, Ramaker J, Vu T, Bootsma S, Lenos KJ, Vermeulen L, Fransen MF, Pegtel M, Bahce I, van Laarhoven H, and Mouliere F

Subjects

Humans, Biomarkers, Tumor genetics, Genomics, Liquid Biopsy, ROC Curve, Cell-Free Nucleic Acids genetics, Neoplasms

Abstract

The structure of cell-free DNA (cfDNA) is altered in the blood of patients with cancer. From whole-genome sequencing, we retrieve the cfDNA fragment-end composition using a new software (FrEIA [fragment end integrated analysis]), as well as the cfDNA size and tumor fraction in three independent cohorts (n = 925 cancer from >10 types and 321 control samples). At 95% specificity, we detect 72% cancer samples using at least one cfDNA measure, including 64% early-stage cancer (n = 220). cfDNA detection correlates with a shorter overall (p = 0.0086) and recurrence-free (p = 0.017) survival in patients with resectable esophageal adenocarcinoma. Integrating cfDNA measures with machine learning in an independent test set (n = 396 cancer, 90 controls) achieve a detection accuracy of 82% and area under the receiver operating characteristic curve of 0.96. In conclusion, harnessing the biological features of cfDNA can improve, at no extra cost, the diagnostic performance of liquid biopsies., Competing Interests: Declaration of interests F.M. is co-inventor on multiple patents related to cfDNA analysis. Other co-authors have no relevant conflict of interests., (Copyright © 2023 The Author(s). Published by Elsevier Inc. All rights reserved.)

Published

2024

36. Real-time analysis of the cancer genome and fragmentome from plasma and urine cell-free DNA using nanopore sequencing.

Author

van der Pol Y, Tantyo NA, Evander N, Hentschel AE, Wever BM, Ramaker J, Bootsma S, Fransen MF, Lenos KJ, Vermeulen L, Schneiders FL, Bahce I, Nieuwenhuijzen JA, Steenbergen RD, Pegtel DM, Moldovan N, and Mouliere F

Subjects

Humans, Genomics methods, Sequence Analysis, DNA, DNA genetics, Biomarkers, Tumor genetics, Cell-Free Nucleic Acids genetics, Nanopore Sequencing, Lung Neoplasms diagnosis, Lung Neoplasms genetics

Abstract

Cell-free DNA (cfDNA) can be isolated and sequenced from blood and/or urine of cancer patients. Conventional short-read sequencing lacks deployability and speed and can be biased for short cfDNA fragments. Here, we demonstrate that with Oxford Nanopore Technologies (ONT) sequencing we can achieve delivery of genomic and fragmentomic data from liquid biopsies. Copy number aberrations and cfDNA fragmentation patterns can be determined in less than 24 h from sample collection. The tumor-derived cfDNA fraction calculated from plasma of lung cancer patients and urine of bladder cancer patients was highly correlated (R = 0.98) with the tumor fraction calculated from short-read sequencing of the same samples. cfDNA size profile, fragmentation patterns, fragment-end composition, and nucleosome profiling near transcription start sites in plasma and urine exhibited the typical cfDNA features. Additionally, a high proportion of long tumor-derived cfDNA fragments (> 300 bp) are recovered in plasma and urine using ONT sequencing. ONT sequencing is a cost-effective, fast, and deployable approach for obtaining genomic and fragmentomic results from liquid biopsies, allowing the analysis of previously understudied cfDNA populations., (© 2023 The Authors. Published under the terms of the CC BY 4.0 license.)

Published

2023

37. Genome-wide and panel-based cell-free DNA characterization of patients with resectable esophageal adenocarcinoma.

Author

van den Ende T, van der Pol Y, Creemers A, Moldovan N, Boers D, van Berge Henegouwen MI, Hulshof MC, Cillessen SA, van Grieken NC, Pegtel DM, Derks S, Bijlsma MF, Mouliere F, and van Laarhoven HW

Subjects

Humans, Biomarkers, Tumor genetics, Mutation, Cell-Free Nucleic Acids genetics, Circulating Tumor DNA genetics, Adenocarcinoma genetics, Adenocarcinoma therapy, Adenocarcinoma diagnosis, Esophageal Neoplasms genetics, Esophageal Neoplasms therapy

Abstract

Circulating tumor DNA (ctDNA) holds promise in resectable esophageal adenocarcinoma (EAC) to predict patient outcome but is not yet sensitive enough to be clinically applicable. Our aim was to combine ctDNA mutation data with shallow whole-genome sequencing (sWGS)-derived copy number tumor fraction estimates (ichorCNA) to improve pathological response and survival prediction in EAC. In total, 111 stage II/III EAC patients with baseline (n = 111), post-neoadjuvant chemoradiotherapy (nCRT) (n = 68), and pre-surgery (n = 92) plasma samples were used for ctDNA characterization. sWGS (<5× coverage) was performed on all time-point samples, and copy number aberrations were estimated using ichorCNA. Baseline and pre-surgery samples were sequenced using a custom amplicon panel for mutation detection. Detection of baseline ctDNA was successful in 44.3% of patients by amplicon sequencing and 10.5% by ichorCNA. Combining both, ctDNA could be detected in 50.5% of patients. Baseline ctDNA positivity was related to higher T stage (cT3, 4) (p = 0.017). There was no relationship between pathological response and baseline ctDNA positivity. However, baseline ctDNA metrics (variant allele frequency > 1% or ichorCNA > 3%) were associated with a high risk of disease progression [HR = 2.23 (95% CI 1.22-4.07), p = 0.007]. The non-clearance of a baseline variant or ichorCNA > 3% in pre-surgery samples was related to early progression [HR = 4.58 (95% CI 2.22-9.46), p < 0.001]. Multi-signal analysis improves detection of ctDNA and can be used for prognostication of resectable EAC patients. Future studies should explore the potential of multi-modality sequencing for risk stratification and treatment adaptation based on ctDNA results. © 2023 The Authors. The Journal of Pathology published by John Wiley & Sons Ltd on behalf of The Pathological Society of Great Britain and Ireland., (© 2023 The Authors. The Journal of Pathology published by John Wiley & Sons Ltd on behalf of The Pathological Society of Great Britain and Ireland.)

Published

2023

38. Integrated radiogenomics models predict response to neoadjuvant chemotherapy in high grade serous ovarian cancer.

Author

Crispin-Ortuzar M, Woitek R, Reinius MAV, Moore E, Beer L, Bura V, Rundo L, McCague C, Ursprung S, Escudero Sanchez L, Martin-Gonzalez P, Mouliere F, Chandrananda D, Morris J, Goranova T, Piskorz AM, Singh N, Sahdev A, Pintican R, Zerunian M, Rosenfeld N, Addley H, Jimenez-Linan M, Markowetz F, Sala E, and Brenton JD

Subjects

Humans, Female, Neoadjuvant Therapy methods, Biomarkers, Tumor genetics, Ovarian Neoplasms diagnostic imaging, Ovarian Neoplasms drug therapy, Ovarian Neoplasms genetics

Abstract

High grade serous ovarian carcinoma (HGSOC) is a highly heterogeneous disease that typically presents at an advanced, metastatic state. The multi-scale complexity of HGSOC is a major obstacle to predicting response to neoadjuvant chemotherapy (NACT) and understanding critical determinants of response. Here we present a framework to predict the response of HGSOC patients to NACT integrating baseline clinical, blood-based, and radiomic biomarkers extracted from all primary and metastatic lesions. We use an ensemble machine learning model trained to predict the change in total disease volume using data obtained at diagnosis (n = 72). The model is validated in an internal hold-out cohort (n = 20) and an independent external patient cohort (n = 42). In the external cohort the integrated radiomics model reduces the prediction error by 8% with respect to the clinical model, achieving an AUC of 0.78 for RECIST 1.1 classification compared to 0.47 for the clinical model. Our results emphasize the value of including radiomics data in integrative models of treatment response and provide methods for developing new biomarker-based clinical trials of NACT in HGSOC., (© 2023. Springer Nature Limited.)

Published

2023

39. The landscape of cell-free mitochondrial DNA in liquid biopsy for cancer detection.

Author

van der Pol Y, Moldovan N, Ramaker J, Bootsma S, Lenos KJ, Vermeulen L, Sandhu S, Bahce I, Pegtel DM, Wong SQ, Dawson SJ, Chandrananda D, and Mouliere F

Subjects

Male, Humans, Liquid Biopsy, Mitochondria genetics, DNA, Mitochondrial genetics, Biomarkers, Tumor genetics, Cell-Free Nucleic Acids, Prostatic Neoplasms genetics

Abstract

Background: Existing methods to detect tumor signal in liquid biopsy have focused on the analysis of nuclear cell-free DNA (cfDNA). However, non-nuclear cfDNA and in particular mitochondrial DNA (mtDNA) has been understudied. We hypothesize that an increase in mtDNA in plasma could reflect the presence of cancer, and that leveraging cell-free mtDNA could enhance cancer detection., Results: We survey 203 healthy and 664 cancer plasma samples from three collection centers covering 12 cancer types with whole genome sequencing to catalogue the plasma mtDNA fraction. The mtDNA fraction is increased in individuals with cholangiocarcinoma, colorectal, liver, pancreatic, or prostate cancer, in comparison to that in healthy individuals. We detect almost no increase of mtDNA fraction in individuals with other cancer types. The mtDNA fraction in plasma correlates with the cfDNA tumor fraction as determined by somatic mutations and/or copy number aberrations. However, the mtDNA fraction is also elevated in a fraction of patients without an apparent increase in tumor-derived cfDNA. A predictive model integrating mtDNA and copy number analysis increases the area under the curve (AUC) from 0.73 when using copy number alterations alone to an AUC of 0.81., Conclusions: The mtDNA signal retrieved by whole genome sequencing has the potential to boost the detection of cancer when combined with other tumor-derived signals in liquid biopsies., (© 2023. BioMed Central Ltd., part of Springer Nature.)

Published

2023

40. Prediction of pathologic complete response after single-dose MR-guided partial breast irradiation in low-risk breast cancer patients: the ABLATIVE-2 trial-a study protocol.

Author

Civil YA, Oei AL, Duvivier KM, Bijker N, Meijnen P, Donkers L, Verheijen S, van Kesteren Z, Palacios MA, Schijf LJ, Barbé E, Konings IRHM, -van der Houven van Oordt CWM, Westhoff PG, Meijer HJM, Diepenhorst GMP, Thijssen V, Mouliere F, Slotman BJ, van der Velde S, and van den Bongard HJGD

Subjects

Humans, Female, Middle Aged, Aged, Breast Neoplasms pathology, Breast Neoplasms radiotherapy, Breast Neoplasms surgery, Radiosurgery, Mastectomy, Segmental adverse effects

Abstract

Background: Partial breast irradiation (PBI) is standard of care in low-risk breast cancer patients after breast-conserving surgery (BCS). Pre-operative PBI can result in tumor downstaging and more precise target definition possibly resulting in less treatment-related toxicity. This study aims to assess the pathologic complete response (pCR) rate one year after MR-guided single-dose pre-operative PBI in low-risk breast cancer patients., Methods: The ABLATIVE-2 trial is a multicenter prospective single-arm trial using single-dose ablative PBI in low-risk breast cancer patients. Patients ≥ 50 years with non-lobular invasive breast cancer ≤ 2 cm, grade 1 or 2, estrogen receptor-positive, HER2-negative, and tumor-negative sentinel node procedure are eligible. A total of 100 patients will be enrolled. PBI treatment planning will be performed using a radiotherapy planning CT and -MRI in treatment position. The treatment delivery will take place on a conventional or MR-guided linear accelerator. The prescribed radiotherapy dose is a single dose of 20 Gy to the tumor, and 15 Gy to the 2 cm of breast tissue surrounding the tumor. Follow-up MRIs, scheduled at baseline, 2 weeks, 3, 6, 9, and 12 months after PBI, are combined with liquid biopsies to identify biomarkers for pCR prediction. BCS will be performed 12 months after radiotherapy or after 6 months, if MRI does not show a radiologic complete response. The primary endpoint is the pCR rate after PBI. Secondary endpoints are radiologic response, toxicity, quality of life, cosmetic outcome, patient distress, oncological outcomes, and the evaluation of biomarkers in liquid biopsies and tumor tissue. Patients will be followed up to 10 years after radiation therapy., Discussion: This trial will investigate the pathological tumor response after pre-operative single-dose PBI after 12 months in patients with low-risk breast cancer. In comparison with previous trial outcomes, a longer interval between PBI and BCS of 12 months is expected to increase the pCR rate of 42% after 6-8 months. In addition, response monitoring using MRI and biomarkers will help to predict pCR. Accurate pCR prediction will allow omission of surgery in future patients., Trial Registration: The trial was registered prospectively on April 28th 2022 at clinicaltrials.gov (NCT05350722)., (© 2023. The Author(s).)

Published

2023

41. A hitchhiker's guide to cell-free DNA biology.

Author

Mouliere F

Abstract

Liquid biopsy provides a noninvasive window to the cancer genome and physiology. In particular, cell-free DNA (cfDNA) is a versatile analyte for guiding treatment, monitoring treatment response and resistance, tracking minimal residual disease, and detecting cancer earlier. Despite certain successes, brain cancer diagnosis is amongst those applications that has so far resisted clinical implementation. Recent approaches have highlighted the clinical gain achievable by exploiting cfDNA biological signatures to boost liquid biopsy or unlock new applications. However, the biology of cfDNA is complex, still partially understood, and affected by a range of intrinsic and extrinsic factors. This guide will provide the keys to read, decode, and harness cfDNA biology: the diverse sources of cfDNA in the bloodstream, the mechanism of cfDNA release from cells, the cfDNA structure, topology, and why accounting for cfDNA biology matters for clinical applications of liquid biopsy., (© The Author(s) 2022. Published by Oxford University Press, the Society for Neuro-Oncology and the European Association of Neuro-Oncology.)

Published

2022

42. The Effect of Preanalytical and Physiological Variables on Cell-Free DNA Fragmentation.

Author

van der Pol Y, Moldovan N, Verkuijlen S, Ramaker J, Boers D, Onstenk W, de Rooij J, Bahce I, Pegtel DM, and Mouliere F

Subjects

DNA Fragmentation, Humans, Liquid Biopsy methods, Cell-Free Nucleic Acids genetics

Abstract

Background: Assays that account for the biological properties and fragmentation of cell-free DNA (cfDNA) can improve the performance of liquid biopsy. However, preanalytic and physiological differences between individuals on fragmentomic analysis are poorly defined., Methods: We analyzed the impact of collection tube, plasma processing time, and physiology on the size distribution of cfDNA, their genome-wide representation, and sequence diversity at the cfDNA fragment ends using shallow whole-genome sequencing., Results: Neither different stabilizing collection tubes nor processing times affected the cfDNA fragment sizes, but could impact the genome-wide fragmentation patterns and fragment-end sequences of cfDNA. In addition, beyond differences depending on the gender, the physiological conditions tested between 63 individuals (age, body mass index, use of medication, and chronic conditions) minimally influenced the outcome of fragmentomic methods., Conclusions: Fragmentomic approaches have potential for implementation in the clinic, pending clear traceability of analytical and physiological factors., (© American Association for Clinical Chemistry 2022.)

Published

2022

43. Refined characterization of circulating tumor DNA through biological feature integration.

Author

Markus H, Chandrananda D, Moore E, Mouliere F, Morris J, Brenton JD, Smith CG, and Rosenfeld N

Subjects

Biomarkers, Tumor blood, Case-Control Studies, Circulating Tumor DNA blood, Female, Gene Dosage, Genetic Predisposition to Disease, Humans, Neoplasm Grading, Ovarian Neoplasms blood, Ovarian Neoplasms pathology, Phenotype, Predictive Value of Tests, Whole Genome Sequencing, Biomarkers, Tumor genetics, Circulating Tumor DNA genetics, Ovarian Neoplasms genetics

Abstract

Circulating tumor DNA (ctDNA) in blood plasma is present at very low concentrations compared to cell-free DNA (cfDNA) of non-tumor origin. To enhance ctDNA detection, recent studies have been focused on understanding the non-random fragmentation pattern of cfDNA. These studies have investigated fragment sizes, genomic position of fragment end points, and fragment end motifs. Although these features have been described and shown to be aberrant in cancer patients, there is a lack of understanding of how the individual and integrated analysis of these features enrich ctDNA fraction and enhance ctDNA detection. Using whole genome sequencing and copy number analysis of plasma samples from 5 high grade serious ovarian cancer patients, we observed that (1) ctDNA is enriched not only in fragments shorter than mono-nucleosomes (~ 167 bp), but also in those shorter than di-nucleosomes (~ 240-330 bp) (28-159% enrichment). (2) fragments that start and end at the border or within the nucleosome core are enriched in ctDNA (5-46% enrichment). (3) certain DNA motifs conserved in regions 10 bp up- and down- stream of fragment ends (i.e. cleavage sites) could be used to detect tumor-derived fragments (10-44% enrichment). We further show that the integrated analysis of these three features resulted in a higher enrichment of ctDNA when compared to using fragment size alone (additional 7-25% enrichment after fragment size selection). We believe these genome wide features, which are independent of genetic mutational changes, could allow new ways to analyze and interpret cfDNA data, as significant aberrations of these features from a healthy state could improve its utility as a diagnostic biomarker., (© 2022. The Author(s).)

Published

2022

44. Characteristics, origin, and potential for cancer diagnostics of ultrashort plasma cell-free DNA.

Author

Hudecova I, Smith CG, Hänsel-Hertsch R, Chilamakuri CS, Morris JA, Vijayaraghavan A, Heider K, Chandrananda D, Cooper WN, Gale D, Garcia-Corbacho J, Pacey S, Baird RD, Rosenfeld N, and Mouliere F

Subjects

Biomarkers, Tumor genetics, DNA genetics, DNA, Single-Stranded, Humans, Sequence Analysis, DNA, Cell-Free Nucleic Acids genetics, Neoplasms diagnosis, Neoplasms genetics

Abstract

Current evidence suggests that plasma cell-free DNA (cfDNA) is fragmented around a mode of 166 bp. Data supporting this view has been mainly acquired through the analysis of double-stranded cfDNA. The characteristics and diagnostic potential of single-stranded and damaged double-stranded cfDNA in healthy individuals and cancer patients remain unclear. Here, through a combination of high-affinity magnetic bead-based DNA extraction and single-stranded DNA sequencing library preparation (MB-ssDNA), we report the discovery of a large proportion of cfDNA fragments centered at ∼50 bp. We show that these "ultrashort" cfDNA fragments have a greater relative abundance in plasma of healthy individuals (median = 19.1% of all sequenced cfDNA fragments, n = 28) than in plasma of patients with cancer (median = 14.2%, n = 21, P < 0.0001). The ultrashort cfDNA fragments map to accessible chromatin regions of blood cells, particularly in promoter regions with the potential to adopt G-quadruplex (G4) DNA secondary structures. G4-positive promoter chromatin accessibility is significantly enriched in ultrashort plasma cfDNA fragments from healthy individuals relative to patients with cancers ( P < 0.0001), in whom G4-cfDNA enrichment is inversely associated with copy number aberration-inferred tumor fractions. Our findings redraw the landscape of cfDNA fragmentation by identifying and characterizing a novel population of ultrashort plasma cfDNA fragments. Sequencing of MB-ssDNA libraries could facilitate the characterization of gene regulatory regions and DNA secondary structures via liquid biopsy. Our data underline the diagnostic potential of ultrashort cfDNA through classification for cancer patients., (© 2022 Hudecova et al.; Published by Cold Spring Harbor Laboratory Press.)

Published

2022

45. Cell-free DNA technologies for the analysis of brain cancer.

Author

Mair R and Mouliere F

Subjects

Animals, Brain Neoplasms genetics, Brain Neoplasms metabolism, Cell-Free Nucleic Acids genetics, Cell-Free Nucleic Acids metabolism, Humans, Precision Medicine, Biomarkers, Tumor analysis, Brain Neoplasms diagnosis, Cell-Free Nucleic Acids analysis, Early Detection of Cancer methods, Liquid Biopsy methods, Neoplastic Cells, Circulating pathology

Abstract

Survival for glioma patients has shown minimal improvement over the past 20 years. The ability to detect and monitor gliomas relies primarily upon imaging technologies that lack sensitivity and specificity, especially during the post-surgical treatment phase. Treatment-response monitoring with an effective liquid-biopsy paradigm may also provide the most facile clinical scenario for liquid-biopsy integration into brain-tumour care. Conceptually, liquid biopsy is advantageous when compared with both tissue sampling (less invasive) and imaging (more sensitive and specific), but is hampered by technical and biological problems. These problems predominantly relate to low concentrations of tumour-derived DNA in the bloodstream of glioma patients. In this review, we highlight methods by which the neuro-oncological scientific and clinical communities have attempted to circumvent this limitation. The use of novel biological, technological and computational approaches will be explored. The utility of alternate bio-fluids, tumour-guided sequencing, epigenomic and fragmentomic methods may eventually be leveraged to provide the biological and technological means to unlock a wide range of clinical applications for liquid biopsy in glioma., (© 2021. The Author(s).)

Published

2022

46. PCR-Free Shallow Whole Genome Sequencing for Chromosomal Copy Number Detection from Plasma of Cancer Patients Is an Efficient Alternative to the Conventional PCR-Based Approach.

Author

Beagan JJ, Drees EEE, Stathi P, Eijk PP, Meulenbroeks L, Kessler F, Middeldorp JM, Pegtel DM, Zijlstra JM, Sie D, Heideman DAM, Thunnissen E, Smit L, de Jong D, Mouliere F, Ylstra B, Roemer MGM, and van Dijk E

Subjects

Biomarkers, Tumor blood, Biomarkers, Tumor genetics, Blood Specimen Collection methods, Carcinoma, Non-Small-Cell Lung diagnosis, Case-Control Studies, Circulating Tumor DNA blood, Circulating Tumor DNA genetics, Feasibility Studies, Humans, Leukemia, Myeloid, Acute diagnosis, Limit of Detection, Liquid Biopsy, Longitudinal Studies, Lung Neoplasms diagnosis, Lymphoma, B-Cell diagnosis, Carcinoma, Non-Small-Cell Lung blood, Carcinoma, Non-Small-Cell Lung genetics, DNA Copy Number Variations, Leukemia, Myeloid, Acute blood, Leukemia, Myeloid, Acute genetics, Lung Neoplasms blood, Lung Neoplasms genetics, Lymphoma, B-Cell blood, Lymphoma, B-Cell genetics, Polymerase Chain Reaction methods, Whole Genome Sequencing methods

Abstract

Somatic copy number alterations can be detected in cell-free DNA (cfDNA) by shallow whole genome sequencing (sWGS). PCR is typically included in library preparations, but a PCR-free method could serve as a high-throughput alternative. To evaluate a PCR-free method for research and diagnostics, archival peripheral blood or bone marrow plasma samples, collected in EDTA- or lithium-heparin-containing tubes, were collected from patients with non-small-cell lung cancer (n = 10 longitudinal samples; 4 patients), B-cell lymphoma (n = 31), and acute myeloid leukemia (n = 15), or from healthy donors (n = 14). sWGS was performed on PCR-free and PCR library preparations, and the mapping quality, percentage of unique reads, genome coverage, fragment lengths, and copy number profiles were compared. The percentage of unique reads was significantly higher for PCR-free method compared with PCR method, independent of the type of collection tube: EDTA PCR-free method, 96.4% (n = 35); EDTA PCR method, 85.1% (n = 32); heparin PCR-free method, 94.5% (n = 25); and heparin PCR method, 89.4% (n = 10). All other evaluated metrics were highly comparable for PCR-free and PCR library preparations. These results demonstrate the feasibility of somatic copy number alteration detection by PCR-free sWGS using cfDNA from plasma collected in EDTA- or lithium-heparin-containing tubes and pave the way for an automated cfDNA analysis workflow for samples from cancer patients., (Copyright © 2021 Association for Molecular Pathology and American Society for Investigative Pathology. Published by Elsevier Inc. All rights reserved.)

Published

2021

47. Fragmentation patterns and personalized sequencing of cell-free DNA in urine and plasma of glioma patients.

Author

Mouliere F, Smith CG, Heider K, Su J, van der Pol Y, Thompson M, Morris J, Wan JCM, Chandrananda D, Hadfield J, Grzelak M, Hudecova I, Couturier DL, Cooper W, Zhao H, Gale D, Eldridge M, Watts C, Brindle K, Rosenfeld N, and Mair R

Subjects

Biomarkers, Tumor, Humans, Liquid Biopsy, Mutation, Plasma, Sequence Analysis, DNA, Cell-Free Nucleic Acids, Glioma genetics

Abstract

Glioma-derived cell-free DNA (cfDNA) is challenging to detect using liquid biopsy because quantities in body fluids are low. We determined the glioma-derived DNA fraction in cerebrospinal fluid (CSF), plasma, and urine samples from patients using sequencing of personalized capture panels guided by analysis of matched tumor biopsies. By sequencing cfDNA across thousands of mutations, identified individually in each patient's tumor, we detected tumor-derived DNA in the majority of CSF (7/8), plasma (10/12), and urine samples (10/16), with a median tumor fraction of 6.4 × 10 -3 , 3.1 × 10 -5 , and 4.7 × 10 -5 , respectively. We identified a shift in the size distribution of tumor-derived cfDNA fragments in these body fluids. We further analyzed cfDNA fragment sizes using whole-genome sequencing, in urine samples from 35 glioma patients, 27 individuals with non-malignant brain disorders, and 26 healthy individuals. cfDNA in urine of glioma patients was significantly more fragmented compared to urine from patients with non-malignant brain disorders (P = 1.7 × 10 -2 ) and healthy individuals (P = 5.2 × 10 -9 ). Machine learning models integrating fragment length could differentiate urine samples from glioma patients (AUC = 0.80-0.91) suggesting possibilities for truly non-invasive cancer detection., (© 2021 The Authors. Published under the terms of the CC BY 4.0 license.)

Published

2021

48. Cell-Free DNA Fragmentomics: The New "Omics" on the Block.

Author

Chiu RWK, Heitzer E, Lo YMD, Mouliere F, and Tsui DWY

Subjects

Humans, Cell-Free Nucleic Acids genetics

Published

2020

49. ctDNA monitoring using patient-specific sequencing and integration of variant reads.

Author

Wan JCM, Heider K, Gale D, Murphy S, Fisher E, Mouliere F, Ruiz-Valdepenas A, Santonja A, Morris J, Chandrananda D, Marshall A, Gill AB, Chan PY, Barker E, Young G, Cooper WN, Hudecova I, Marass F, Mair R, Brindle KM, Stewart GD, Abraham JE, Caldas C, Rassl DM, Rintoul RC, Alifrangis C, Middleton MR, Gallagher FA, Parkinson C, Durrani A, McDermott U, Smith CG, Massie C, Corrie PG, and Rosenfeld N

Subjects

Biomarkers, Tumor, High-Throughput Nucleotide Sequencing, Humans, Liquid Biopsy, Mutation genetics, Circulating Tumor DNA genetics, DNA, Neoplasm genetics

Abstract

Circulating tumor-derived DNA (ctDNA) can be used to monitor cancer dynamics noninvasively. Detection of ctDNA can be challenging in patients with low-volume or residual disease, where plasma contains very few tumor-derived DNA fragments. We show that sensitivity for ctDNA detection in plasma can be improved by analyzing hundreds to thousands of mutations that are first identified by tumor genotyping. We describe the INtegration of VAriant Reads (INVAR) pipeline, which combines custom error-suppression methods and signal-enrichment approaches based on biological features of ctDNA. With this approach, the detection limit in each sample can be estimated independently based on the number of informative reads sequenced across multiple patient-specific loci. We applied INVAR to custom hybrid-capture sequencing data from 176 plasma samples from 105 patients with melanoma, lung, renal, glioma, and breast cancer across both early and advanced disease. By integrating signal across a median of >10 5 informative reads, ctDNA was routinely quantified to 1 mutant molecule per 100,000, and in some cases with high tumor mutation burden and/or plasma input material, to parts per million. This resulted in median area under the curve (AUC) values of 0.98 in advanced cancers and 0.80 in early-stage and challenging settings for ctDNA detection. We generalized this method to whole-exome and whole-genome sequencing, showing that INVAR may be applied without requiring personalized sequencing panels so long as a tumor mutation list is available. As tumor sequencing becomes increasingly performed, such methods for personalized cancer monitoring may enhance the sensitivity of cancer liquid biopsies., (Copyright © 2020 The Authors, some rights reserved; exclusive licensee American Association for the Advancement of Science. No claim to original U.S. Government Works.)

Published

2020

50. Circulating cell free DNA during definitive chemo-radiotherapy in non-small cell lung cancer patients - initial observations.

Author

Nygård L, Ahlborn LB, Persson GF, Chandrananda D, Langer JW, Fischer BM, Langer SW, Gabrielaite M, Kjær A, Rosenfeld N, Mouliere F, Østrup O, Vogelius IR, and Bentzen SM

Subjects

Adenocarcinoma drug therapy, Adenocarcinoma genetics, Adenocarcinoma radiotherapy, Aged, Aged, 80 and over, Antineoplastic Agents therapeutic use, Carcinoma, Non-Small-Cell Lung genetics, Carcinoma, Squamous Cell drug therapy, Carcinoma, Squamous Cell genetics, Carcinoma, Squamous Cell radiotherapy, Chemoradiotherapy, Female, Humans, Lung Neoplasms genetics, Male, Middle Aged, Pilot Projects, Radiation, Ionizing, Tomography, X-Ray Computed, Carcinoma, Non-Small-Cell Lung therapy, Cell-Free Nucleic Acids blood, Lung Neoplasms therapy

Abstract

Background: The overall aim was to investigate the change over time in circulating cell free DNA (cfDNA) in patients with locally advanced non-small cell lung cancer (NSCLC) undergoing concurrent chemo-radiotherapy. Furthermore, to assess the possibility of detecting circulating cell free tumor DNA (ctDNA) using shallow whole genome sequencing (sWGS) and size selection., Methods: Ten patients were included in a two-phase study. The first four patients had blood samples taken prior to a radiation therapy (RT) dose fraction and at 30 minutes, 1 hour and 2 hours after RT to estimate the short-term dynamics of cfDNA concentration after irradiation. The remaining six patients had one blood sample taken on six treatment days 30 minutes post treatment to measure cfDNA levels. Presence of ctDNA as indicated by chromosomal aberrations was investigated using sWGS. The sensitivity of this method was further enhanced using in silico size selection., Results: cfDNA concentration from baseline to 120 min after therapy was stable within 95% tolerance limits of +/- 2 ng/ml cfDNA. Changes in cfDNA were observed during therapy with an apparent qualitative difference between adenocarcinoma (average increase of 0.69 ng/ml) and squamous cell carcinoma (average increase of 4.0 ng/ml). Tumor shrinkage on daily cone beam computer tomography scans during radiotherapy did not correlate with changes in concentration of cfDNA., Conclusion: Concentrations of cfDNA remain stable during the first 2 hours after an RT fraction. However, based on the sWGS profiles, ctDNA represented only a minor fraction of cfDNA in this group of patients. The detection sensitivity of genomic alterations in ctDNA strongly increases by applying size selection., Competing Interests: The authors have declared that no competing interests exist.

Published

2020