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Abstract

Introduction

Genome-wide sequencing (exome or whole genome) is transforming the care and management of paediatric patients with a rare disease because of its diagnostic capabilities. Genome-wide sequencing is most effective when both parents and the child are sequenced as a trio. Genetic counselling is recommended for all families considering genome-wide sequencing. Although telehealth is well established in genetic counselling for hereditary cancer and prenatal genetics, its use with genome-wide sequencing has not been well studied. The CAUSES Clinic at BC Children’s and Women’s Hospitals was a translational paediatric trio-based genome-wide sequencing initiative. Pre-test genetic counselling via telehealth (at a clinical site near the family’s residence) was offered to families who had been previously evaluated by a clinical geneticist. We report on the first 300 families seen in the CAUSES clinic and compare health services implementation issues of families seen via telehealth versus on-site.

Methods

Demographics, cost to families (travel and time), time to first appointment, complete trio sample accrual and diagnostic rates were studied.

Results

Of the 300 patients, 58 (19%) were seen via telehealth and 242 (81%) were seen on-site for pre-test counselling. The mean time to completion of accrual of trio samples in the telehealth group was 56.3 (standard deviation ±87.3) days versus 18.9 (standard deviation ±62.4) days in the onsite group (p < 2.2 × 10⁻¹⁶). The mean per-family estimated actual or potential travel/time cost savings were greater in the telehealth group (Can$987; standard deviation = Can$1151) than for those seen on-site (Can$305; standard deviation = Can$589) (p = 0.0004).

Conclusions

Telehealth allowed for access to genome-wide sequencing for families in remote communities and for them to avoid significant travel and time costs; however, there was a significant delay to accrual of the complete trio samples in the telehealth group, impacting on time of result reporting and delaying diagnoses for families for whom genome-wide sequencing was diagnostic.

Keywords

Telehealth telemedicine virtual health genome-wide sequencing genetic counselling economics

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References

Jennett

Affleck Hall

Hailey

, et al. The socio-economic impact of telehealth: A systematic review. J Telemed Telecare 2003; 9: 311–320.

Bradbury

Patrick-Miller

Harris

, et al. Utilizing remote real-time videoconferencing to expand access to cancer genetic services in community practices: A multicenter feasibility study. J Med Internet Res 2016 ; 18: e23.

Buchanan

Datta

Skinner

, et al. Randomized trial of telegenetics vs. in-person cancer genetic counseling: Cost, patient satisfaction and attendance. J Genet Couns 2015; 24: 961–970.

Cohen

Bradbury

Henderson

, et al. Genetic counseling and testing in a community setting: Quality, access, and efficiency. Am Soc Clin Oncol Educ B 2019; 39: e34–e44.

d’Agincourt-Canning

McGillivray

Panabaker

, et al. Evaluation of genetic counseling for hereditary cancer by videoconference in British Columbia. B C Med J 2008; 50: 554–559.

Elwyn

Gray

Clarke

Shared decision making and non-directiveness in genetic counselling. J Med Genet 2000; 37: 135–138.

Weissman

Zellmer

Gill

, et al. Implementing a virtual health telemedicine program in a community setting. J Genet Couns 2018; 27: 323–325.

Zilliacus

Meiser

Lobb

, et al. Women’s experience of telehealth cancer genetic counseling. J Genet Couns 2010; 19: 463–472.

Walsh

Markus

HS.

Telemedicine for follow-up of rare neurological disease.

Stroke 2019; 50: 750–753.

10.

Hawkins

Creighton

, et al. Providing predictive testing for Huntington disease via telehealth: Results of a pilot study in British Columbia, Canada. Clin Genet 2013; 84: 60–64.

11.

Hawkins

Creighton

Hayden

MR.

When access is an issue: Exploring barriers to predictive testing for Huntington disease in British Columbia, Canada. Eur J Hum Genet 2013; 21: 148–153.

12.

Benoit

Bowes

Bowman

, et al. Telemedicine diagnosis for fetal alcohol syndrome - The Manitoba experience. Paediatr Child Health 2002; 7: 147–151.

13.

Hanlon-Dearman

Edwards

Schwab

, et al. ‘Giving voice’: Evaluation of an integrated telehealth community care model by parents/guardians of children diagnosed with fetal alcohol spectrum disorder in Manitoba. Telemed J E Health 2014; 20: 478–484.

14.

Ens

CDL

Hanlon-Dearman

Millar

, et al. Using telehealth for assessment of fetal alcohol spectrum disorder: The experience of two Canadian rural and remote communities. Telemed J E Health 2010; 16: 872–877.

15.

Elliott

Mhanni

Marles

, et al. Trends in telehealth versus on-site clinical genetics appointments in Manitoba: A comparative study. J Genet Couns 2012; 21: 337–344.

16.

Wright

FitzPatrick

Firth

HV.

Paediatric genomics: Diagnosing rare disease in children.

Nat Rev Genet 2018; 19: 253–268.

17.

Clark

Stark

Farnaes

, et al. Meta-analysis of the diagnostic and clinical utility of genome and exome sequencing and chromosomal microarray in children with suspected genetic diseases. NPJ Genom Med 2018; 3: 16.

18.

Wright

Fitzgerald

Jones

, et al. Genetic diagnosis of developmental disorders in the DDD study: A scalable analysis of genome-wide research data. Lancet 2015; 385: 1305–1314.

19.

Al-Dewik

Mohd

Al-Mureikhi

, et al. Clinical exome sequencing in 509 Middle Eastern families with suspected Mendelian diseases: The Qatari experience. Am J Med Genet A 2019 ; 179: 927–935.

20.

Wright

McRae

Clayton

, et al. Making new genetic diagnoses with old data: Iterative reanalysis and reporting from genome-wide data in 1,133 families with developmental disorders. Genet Med 2018; 20: 1216–1223.

21.

Dragojlovic

Elliott

Adam

, et al. The cost and diagnostic yield of exome sequencing for children with suspected genetic disorders: A benchmarking study. Genet Med 2018; 20: 1013–1021.

22.

Bowdin

Gilbert

Bedoukian

, et al. Recommendations for the integration of genomics into clinical practice. Genet Med 2016; 18: 1075–1084.

23.

Boycott

Hartley

Adam

, et al. The clinical application of genome-wide sequencing for monogenic diseases in Canada: Position statement of the Canadian College of Medical Geneticists. J Med Genet 2015; 52: 431–437.

24.

Elliott

Friedman

JM.

The importance of genetic counselling in genome-wide sequencing. Nat Rev Genet 2018; 19: 735–736.

25.

Green

Berg

Grody

, et al. ACMG recommendations for reporting of incidental findings in clinical exome and genome sequencing. Genet Med 2013; 15: 565–574.

26.

Matthijs

Souche

Alders

, et al. Guidelines for diagnostic next-generation sequencing. Eur J Hum Genet 2016; 24: 2–5.

27.

Hoskovec

Bennett

Carey

, et al. Projecting the supply and demand for certified genetic counselors: A workforce study. J Genet Couns 2018; 27: 16–20.

28.

Stoll

Kubendran

Cohen

SA.

The past, present and future of service delivery in genetic counseling: Keeping up in the era of precision medicine. Am J Med Genet C Semin Med Genet 2018; 178: 24–37.

29.

Dragojlovic

Kim

Elliott

, et al. Evaluating the use of parental reports to estimate health care resource utilization in children with suspected genetic disorders. J Eval Clin Pract 2018; 24: 416–422.

30.

Dragojlovic

van Karnebeek

CDM

Ghani

, et al. The cost trajectory of the diagnostic care pathway for children with suspected genetic disorders. Genet Med 2020; 22: 292–300.

31.

Elliott

du Souich

Adam

, et al. The Genomic Consultation Service: A clinical service designed to improve patient selection for genome-wide sequencing in British Columbia. Mol Genet Genomic Med 2018; 6: 592–600.

32.

Inglese

Elliott

Lehman

, et al. New developmental syndromes: Understanding the family experience. J Genet Couns 2019; 28: 202–212.

33.

Smith

du Souich

Dragojlovic

, et al. Genetic counseling considerations with rapid genome-wide sequencing in a neonatal intensive care unit. J Genet Couns 2019; 28: 263–272.

34.

Boycott

Rath

Chong

, et al. International cooperation to enable the diagnosis of all rare genetic diseases. Am J Hum Genet 2017; 100: 695–705.

35.

Splinter

Adams

Bacino

, et al. Effect of genetic diagnosis on patients with previously undiagnosed disease. N Engl J Med 2018; 379: 2131–2139.

36.

Strande

Berg

JS.

Defining the clinical value of a genomic diagnosis in the era of next-generation sequencing. Annu Rev Genomics Hum Genet 2016; 17: 303–332.

37.

Cohen

Huziak

Gustafson

, et al. Analysis of advantages, limitations, and barriers of genetic counseling service delivery models. J Genet Couns 2016; 25: 1010–1018.

38.

Otten

Birnie

Lucassen

, et al. Telemedicine uptake among genetics professionals in Europe: Room for expansion. Eur J Hum Genet 2016; 24: 157–163.

39.

Otten

Birnie

Ranchor

, et al. Online genetic counseling from the providers’ perspective: Counselors’ evaluations and a time and cost analysis. Eur J Hum Genet 2016; 24: 1255–1261.

40.

Voils

Venne

Weidenbacher

, et al. Comparison of telephone and televideo modes for delivery of genetic counseling: A randomized trial. J Genet Couns 2018; 27: 339–348.

41.

Boothe

Kaplan

Using telemedicine in Mississippi to improve patient access to genetic services. J Genet Couns 2018; 27: 320–322.

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Utilization of telehealth in paediatric genome-wide sequencing: Health services implementation issues in the CAUSES Study

Abstract

Introduction

Methods

Results

Conclusions

Keywords

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References

Supplementary Material