Prediction of Preterm Labor from the Electrohysterogram Signals Based on Different Gestational Weeks
Abstract
:1. Introduction
2. Dataset
3. The Proposed Method
3.1. Preprocessing
3.2. EHG Signal Decomposition
- 1.
- Detecting the local extrema of ;
- 2.
- Synthesizing the upper and lower signal’s envelopes from the detected extrema using cubic spline;
- 3.
- Forming the local mean signal, , by averaging the upper and lower signal’s envelopes;
- 4.
- Subtracting the local mean signal from the original signal to acquire the first possible IMF candidate .
- 1.
- The number of zero-crossings and local extrema must either be equal or differ at most by one.
- 2.
- The average value of the envelopes defined by the local maxima and minima is zero.
3.3. Feature Extraction
3.4. Data Balancing
3.5. Feature Selection
3.6. Data Segmentation
3.7. Classification
4. Results and Discussion
4.1. Selected Features
4.2. Classification Results
4.3. Sensitivity of Classifiers for Preterm Labor Based on Only Real EHG Data
4.4. Comparison against the State-of-the-Art Methods
4.5. Future Work
5. Conclusions
Author Contributions
Funding
Institutional Review Board Statement
Informed Consent Statement
Data Availability Statement
Conflicts of Interest
Abbreviations
EHG | electrohysterogram |
EMD | empirical mode decomposition |
IMF | intrinsic mode functions |
RMS | root mean square |
MTKE | mean Teager–Kaiser energy |
WLE | wavelet log energy |
SE | Shannon entropy |
KFD | Katz fractal dimension |
HE | Hurst exponent |
RF | random forest |
DT | decision tree |
SVM | support vector machine |
Acc | accuracy |
Sen | sensitivity |
Spe | specificity |
AUC | area under the curve |
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Gestational Time of Recording | Delivery Type | |
---|---|---|
Preterm | Term | |
Before 26th week | Preterm Early (PE), n = 19 | Term Early (TE), n = 143 |
After 26th week | Preterm Later (PL), n = 19 | Term Later (TL), n = 119 |
PE-TE Group | |||||||||||
---|---|---|---|---|---|---|---|---|---|---|---|
RMS | RMS | WLE | WLE | RMS | WLE | WLE | RMS | RMS | RMS | RMS | WLE |
MTKE | MTKE | SE | SE | MTKE | SE | KFD | KFD | MTKE | KFD | WLE | SE |
WLE | WLE | HE | KFD | SE | HE | SE | HE | ||||
SE | KFD | HE | |||||||||
PL-TL group | |||||||||||
RMS | RMS | WLE | WLE | RMS | RMS | WLE | RMS | RMS | RMS | RMS | WLE |
MTKE | MTKE | SE | SE | KFD | KFD | HE | SE | WLE | MTKE | HE | KFD |
WLE | WLE | KFD | KFD | SE | HE | HE | KFD | ||||
SE | HE | HE | |||||||||
HE |
Group | PE-TE | PL-TL | ||||||
---|---|---|---|---|---|---|---|---|
Classifier | Sen | Spe | Acc | AUC | Sen | Spe | Acc | AUC |
AdaBoost | 92% | 97% | 95% | 0.99 | 90% | 94% | 93% | 0.98 |
SVM | 66% | 99% | 83% | 0.93 | 64% | 98% | 81% | 0.89 |
DT | 85% | 92% | 88% | 0.90 | 85% | 87% | 86% | 0.86 |
RF | 86% | 96% | 92% | 0.97 | 84% | 96% | 90% | 0.95 |
Study | Group and No. of Data | Classifier | Acc | Sen | Spe | AUC |
---|---|---|---|---|---|---|
Ours | PE (n = 143)-TE (n = 143) | AdaBoost | 95% | 92% | 97% | 0.99 |
PL (n = 119)-TL (n = 119) | 93% | 90% | 93% | 0.98 | ||
[42] | PE (n = 135)-TE (n = 143) | RF | 92% | 88% | 96% | 0.88 |
PL (n = 111)-TL (n = 119) | 93% | 89% | 97% | 0.80 | ||
[43] | PE (n = 93)-TE (n = 93) | QDA | 97% | 100% | 95% | N.A |
PL (n = 57)-TL (n = 57) | 100% | 100% | 100% | N.A | ||
[35] | PE (n = 140)-TE (n = 143) | QDA | 100% | 100% | 100% | 1.0 |
[44] | PE-TE, n is not reported. | SVM | 96.5% | 94% | 99% | 0.99 |
PL-TL, n is not reported. | 92.5% | 88% | 97% | 0.98 |
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Mohammadi Far, S.; Beiramvand, M.; Shahbakhti, M.; Augustyniak, P. Prediction of Preterm Labor from the Electrohysterogram Signals Based on Different Gestational Weeks. Sensors 2023, 23, 5965. https://doi.org/10.3390/s23135965
Mohammadi Far S, Beiramvand M, Shahbakhti M, Augustyniak P. Prediction of Preterm Labor from the Electrohysterogram Signals Based on Different Gestational Weeks. Sensors. 2023; 23(13):5965. https://doi.org/10.3390/s23135965
Chicago/Turabian StyleMohammadi Far, Somayeh, Matin Beiramvand, Mohammad Shahbakhti, and Piotr Augustyniak. 2023. "Prediction of Preterm Labor from the Electrohysterogram Signals Based on Different Gestational Weeks" Sensors 23, no. 13: 5965. https://doi.org/10.3390/s23135965
APA StyleMohammadi Far, S., Beiramvand, M., Shahbakhti, M., & Augustyniak, P. (2023). Prediction of Preterm Labor from the Electrohysterogram Signals Based on Different Gestational Weeks. Sensors, 23(13), 5965. https://doi.org/10.3390/s23135965