Your search keyword '"Camps, C"' showing total 2 results

1. The complete costs of genome sequencing: a microcosting study in cancer and rare diseases from a single center in the United Kingdom.

Author

Schwarze K, Buchanan J, Fermont JM, Dreau H, Tilley MW, Taylor JM, Antoniou P, Knight SJL, Camps C, Pentony MM, Kvikstad EM, Harris S, Popitsch N, Pagnamenta AT, Schuh A, Taylor JC, and Wordsworth S

Subjects

High-Throughput Nucleotide Sequencing economics, High-Throughput Nucleotide Sequencing instrumentation, Humans, Neoplasms economics, Rare Diseases economics, State Medicine, Translational Research, Biomedical, United Kingdom, Whole Genome Sequencing instrumentation, Neoplasms genetics, Rare Diseases genetics, Whole Genome Sequencing economics

Abstract

Purpose: The translation of genome sequencing into routine health care has been slow, partly because of concerns about affordability. The aspirational cost of sequencing a genome is $1000, but there is little evidence to support this estimate. We estimate the cost of using genome sequencing in routine clinical care in patients with cancer or rare diseases., Methods: We performed a microcosting study of Illumina-based genome sequencing in a UK National Health Service laboratory processing 399 samples/year. Cost data were collected for all steps in the sequencing pathway, including bioinformatics analysis and reporting of results. Sensitivity analysis identified key cost drivers., Results: Genome sequencing costs £6841 per cancer case (comprising matched tumor and germline samples) and £7050 per rare disease case (three samples). The consumables used during sequencing are the most expensive component of testing (68-72% of the total cost). Equipment costs are higher for rare disease cases, whereas consumable and staff costs are slightly higher for cancer cases., Conclusion: The cost of genome sequencing is underestimated if only sequencing costs are considered, and likely surpasses $1000/genome in a single laboratory. This aspirational sequencing cost will likely only be achieved if consumable costs are considerably reduced and sequencing is performed at scale.

Published

2020

2. Clinical applicability and cost of a 46-gene panel for genomic analysis of solid tumours: Retrospective validation and prospective audit in the UK National Health Service.

Author

Hamblin A, Wordsworth S, Fermont JM, Page S, Kaur K, Camps C, Kaisaki P, Gupta A, Talbot D, Middleton M, Henderson S, Cutts A, Vavoulis DV, Housby N, Tomlinson I, Taylor JC, and Schuh A

Subjects

Adolescent, Adult, Aged, Aged, 80 and over, Carcinoma, Non-Small-Cell Lung economics, Carcinoma, Non-Small-Cell Lung genetics, Carcinoma, Non-Small-Cell Lung therapy, Child, Clinical Decision-Making, Colorectal Neoplasms economics, Colorectal Neoplasms genetics, Colorectal Neoplasms therapy, Female, High-Throughput Nucleotide Sequencing, Humans, Male, Melanoma economics, Melanoma genetics, Melanoma therapy, Middle Aged, National Health Programs, Prospective Studies, Retrospective Studies, United Kingdom, Young Adult, Carcinoma, Non-Small-Cell Lung diagnosis, Colorectal Neoplasms diagnosis, Genomics, Melanoma diagnosis, Pathology methods, Pathology standards

Abstract

Background: Single gene tests to predict whether cancers respond to specific targeted therapies are performed increasingly often. Advances in sequencing technology, collectively referred to as next generation sequencing (NGS), mean the entire cancer genome or parts of it can now be sequenced at speed with increased depth and sensitivity. However, translation of NGS into routine cancer care has been slow. Healthcare stakeholders are unclear about the clinical utility of NGS and are concerned it could be an expensive addition to cancer diagnostics, rather than an affordable alternative to single gene testing., Methods and Findings: We validated a 46-gene hotspot cancer panel assay allowing multiple gene testing from small diagnostic biopsies. From 1 January 2013 to 31 December 2013, solid tumour samples (including non-small-cell lung carcinoma [NSCLC], colorectal carcinoma, and melanoma) were sequenced in the context of the UK National Health Service from 351 consecutively submitted prospective cases for which treating clinicians thought the patient had potential to benefit from more extensive genetic analysis. Following histological assessment, tumour-rich regions of formalin-fixed paraffin-embedded (FFPE) sections underwent macrodissection, DNA extraction, NGS, and analysis using a pipeline centred on Torrent Suite software. With a median turnaround time of seven working days, an integrated clinical report was produced indicating the variants detected, including those with potential diagnostic, prognostic, therapeutic, or clinical trial entry implications. Accompanying phenotypic data were collected, and a detailed cost analysis of the panel compared with single gene testing was undertaken to assess affordability for routine patient care. Panel sequencing was successful for 97% (342/351) of tumour samples in the prospective cohort and showed 100% concordance with known mutations (detected using cobas assays). At least one mutation was identified in 87% (296/342) of tumours. A locally actionable mutation (i.e., available targeted treatment or clinical trial) was identified in 122/351 patients (35%). Forty patients received targeted treatment, in 22/40 (55%) cases solely due to use of the panel. Examination of published data on the potential efficacy of targeted therapies showed theoretically actionable mutations (i.e., mutations for which targeted treatment was potentially appropriate) in 66% (71/107) and 39% (41/105) of melanoma and NSCLC patients, respectively. At a cost of £339 (US$449) per patient, the panel was less expensive locally than performing more than two or three single gene tests. Study limitations include the use of FFPE samples, which do not always provide high-quality DNA, and the use of "real world" data: submission of cases for sequencing did not always follow clinical guidelines, meaning that when mutations were detected, patients were not always eligible for targeted treatments on clinical grounds., Conclusions: This study demonstrates that more extensive tumour sequencing can identify mutations that could improve clinical decision-making in routine cancer care, potentially improving patient outcomes, at an affordable level for healthcare providers., Competing Interests: This was an investigator-planned and driven study. The study was funded by a grant from the Technology Strategy Board (TSB, now Innovate UK), with contributory funding from commercial partners ThermoFisher (lead commercial partner), AstraZeneca and Johnson and Johnson. ThermoFisher's contribution to the Innovate UK funding scheme consisted of in kind support for the Ion Torrent reagents and platform, in accordance with the requirements of the TSB funding scheme. The academic investigators named on this paper as authors carried out the research by selecting the cancer samples, sequencing these, choosing the methods for analysis, analysing the sequencing and clinical data, conducting the cost analysis and writing the manuscript. This work was all undertaken independently of the commercial partners. ThermoFisher, AstraZeneca and Johnson and Johnson were not involved in the study design or analysis for the 46 gene hotspot panel or in the sequencing or analysis of any of the samples. Nor were they involved in the decision to report the results or the writing of the manuscript at any stage.

Published

2017