What does this research mean for the field?

ECG leads are suitable for monitoring respiratory activity and can enhance respiratory sEMG performance when combined with sEMG electrodes. Novelty: ClaimNovelty.NOVEL_FINDING. Consensus alignment: ConsensusAlignment.NEUTRAL.

What question did this study set out to answer?

The aim is to evaluate the effectiveness of ECG leads for monitoring respiratory effort compared to standard methods.

March 16, 2026Open Access

Measuring respiratory surface EMG with ECG electrode leads

Q: What is the clinical evidence from this study?

Study design: Other. Population: Respiratory muscle activity measurement (n=20). Intervention: ECG leads for measuring respiratory sEMG vs. Standard electrode leads. Primary outcome: Signal-to-noise ratio (SNR) for inspiratory activity and baseline noise (null, 95% CI null, p=<0.05).

Key Result

ECG leads achieved an SNRbase of 6.00 ±3.04 dB during quiet breathing, demonstrating their potential for monitoring respiratory muscle activity without compromising cardiac signals.

Key Points

The aim is to evaluate the effectiveness of ECG leads for monitoring respiratory effort compared to standard methods.
Investigated the use of ECG leads in respiratory monitoring among 20 subjects.
Subjects performed both quiet and resistance breathing exercises.
Quantified performance using signal-to-noise ratios between inspiratory activity and noise as well as expiratory activity.
ECG leads proved suitable for monitoring respiration.
Performance improved when ECG leads were combined with sEMG electrodes.
Significant enhancement in detecting inspiratory activity over baseline noise.

Structured PICO

Do standard ECG leads provide adequate signal-to-noise ratios for monitoring respiratory surface EMG compared to dedicated chest electrodes in healthy subjects?

Population

20 healthy subjects, mean age 26.7±3.33 years, BMI 24.00±2.91 kg/m2

Intervention

Standard 12-lead ECG leads (Einthoven and Wilson) and differential leads combining one ECG electrode with one chest electrode

Comparator

Reference differential lead between LMCL3 and RMCL3

Outcome

Signal-to-noise ratios (SNRbase and SNRexp) between inspiratory activity and baseline noise or expiratory activitysurrogate

Standard ECG leads can be repurposed to monitor respiratory muscle activity, with performance enhanced by adding a single respiratory sEMG electrode, facilitating integrated cardiopulmonary monitoring.

Main Result

Effect estimate: null (95% CI null)

p-value: p=<0.05

Limitations

Small sample size of healthy subjects
Need for validation in intensive care patient cohorts

Abstract

Surface electromyography (sEMG) offers potential for analyzing patient-ventilator interactions and respiratory effort. Despite promising in monitoring respiration, it is not clinically established, unlike electrocardiography (ECG), which shares the same physiological principle for cardiac monitoring. This study investigates ECG leads for respiratory monitoring in 20 subjects performing quiet and resistance breathing. Performance was quantified by signal-to-noise ratios between inspiratory activity and (1) baseline noise and (2) expiratory activity. ECG leads were suitable for monitoring respiration, with performance enhanced by combining ECG electrodes with sEMG electrodes. The findings support integrating respiratory sEMG into clinical practice using ECG electrodes without compromising cardiac monitoring.

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Cite This Study

Oltmann et al. (Tue,) conducted a other in Respiratory muscle activity measurement (n=20). ECG leads for measuring respiratory sEMG vs. Standard electrode leads was evaluated on Signal-to-noise ratio (SNR) for inspiratory activity and baseline noise (null, 95% CI null, p=<0.05). ECG leads achieved an SNRbase of 6.00 ±3.04 dB during quiet breathing, demonstrating their potential for monitoring respiratory muscle activity without compromising cardiac signals.

synapsesocial.com/papers/69b79e6e8166e15b153abbfa https://doi.org/https://doi.org/10.18416/automed.2026.2500

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