The Validity and Reliability of an Open Source Biosensing Board to Quantify Heart Rate Variability

Overview

Journal Heliyon

Specialty Social Sciences

Date 2021 Jun 14

PMID 34124405

Citations 4

Authors

Joel S Burma

Andrew P Lapointe

Ateyeh Soroush

Ibukunoluwa K Oni

Jonathan D Smirl

Jeff F Dunn

Affiliations

Soon will be listed here.

Abstract

Background: Heart rate variability (HRV) is a popular tool to quantify autonomic function. However, this typically requires an expensive 3-12 lead electrocardiogram (ECG) and BioAmp system. This investigation sought to determine the validity and reliability of an OpenBCI cyton biosensing board (open source) for accurately quantifying HRV.

New Method: A cyton board with a 3-lead ECG was employed to acquire heart rate waveform data, which was processed to obtain HRV within both time- and frequency-domains. The concurrent validity was compared to a simultaneous recording from an industry-standard 3-lead ECG (ADInstruments) (n = 15). The reliability of the cyton board was compared between three days within a 7-day timespan (n = 10). Upright quiet-stance short-term HRV metrics were quantified in time- and frequency-domains.

Results: The two devices displayed excellent limits of agreements (all log mean differences ±0.4) and very high between-device variable associations (all > 0.98). Between the three time points in the same subjects, no differences were noted within time- (all > 0.71) or frequency-domains (all > 0.88) across testing points. Finally, all HRV metrics exhibited excellent levels of reliability through high Cronbach's Alpha (all ≥0.916) and intraclass correlation coefficients (all ≥0.930); and small standard error of the measurement (all ≤0.7) and typical error of the measurement (all ≤0.1) metrics.

Comparison With Existing Methods: The cyton board with 3-lead ECG was compared with an industry-standard ADInstruments ECG during HRV assessments. There were no significant differences between devices with respect to time- and frequency-domains. The cyton board displayed high-levels of between-day reliability and provided values harmonious to previous ECG literature highlighting the applicability for longitudinal studies.

Conclusion: With proper background knowledge regarding ECG principles and a small degree of set-up complexity, an open source cyton board can be created and employed to perform multimodal HRV assessments at a fraction of the cost (~4%) of an industry-standard ECG setup.

Citing Articles

Validity and reliability of short-term heart-rate variability from disposable electrocardiography leads.

Okwose N, Russell S, Rahman M, Steward C, Harwood A, McGregor G Health Sci Rep. 2022; 6(1):e984.

PMID: 36514326 PMC: 9731360. DOI: 10.1002/hsr2.984.

Repetitive bout of controlled soccer heading does not alter heart rate variability metrics: A preliminary investigation.

Smirl J, Peacock D, Burma J, Wright A, Bouliane K, Dierijck J Front Neurol. 2022; 13:980938.

PMID: 36504654 PMC: 9732532. DOI: 10.3389/fneur.2022.980938.

Alterations in Baroreflex Sensitivity and Blood Pressure Variability Following Sport-Related Concussion.

Ellingson C, Singh J, Ellingson C, Sirant L, Kratzig G, Dorsch K Life (Basel). 2022; 12(9).

PMID: 36143435 PMC: 9500648. DOI: 10.3390/life12091400.

The influence of external stressors on physiological testing: Implication for return-to-play protocols.

Ellingson C, Singh J, Ellingson C, Dech R, Piskorski J, Neary J Curr Res Physiol. 2022; 5:240-245.

PMID: 35756694 PMC: 9213225. DOI: 10.1016/j.crphys.2022.06.003.

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