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This study introduces a cross-modal generative framework that utilizes dilated convolutions and cross-modal attention to translate fetal-maternal electrocardiograms (fECG) into fetal Doppler waveforms. By analyzing 885 synchronized segments from 39 pregnancies, the model achieves a significant reduction in power spectral density mean squared error (PSD MSE) and heart-rate error compared to baseline methods, demonstrating the effectiveness of incorporating maternal cardiovascular dynamics. The findings enhance our understanding of fetal cardiovascular function by quantifying the contributions of electrical versus mechanical factors, ultimately improving clinical assessments of fetal health.
Cross-modal attention reduces Doppler synthesis error by 39%, revealing the hidden mechanical contributions to fetal cardiovascular dynamics.
Fetal electrocardiogram (fECG) and Doppler ultrasound provide complementary views of fetal cardiovascular function: fECG captures electrical activity while Doppler reflects mechanical hemodynamics shaped by factors such as placental resistance and vascular compliance. Understanding the recoverable and unrecoverable Doppler components through reconstruction from fECG offers insight into the relative contributions of electrical versus mechanical factors in fetal circulation, thereby informing clinical decisions. In addition, clinical evidence of maternal-fetal cardiac coupling suggests that maternal cardiovascular dynamics may also inform fetal hemodynamics. To computationally model these relationships, we propose a cross-modal generative framework combining dilated convolutions with cross-modal attention to selectively incorporate maternal ECG and self-attention to capture long-range temporal dependencies. Trained on 885 synchronized fetal/maternal ECG and Doppler envelope segments from 39 pregnancies, our model synthesizes Doppler envelopes with power spectral density mean squared error (PSD MSE) of 49.9 +/- 15.8 dB^2 (51% lower than two-channel baseline) and heart-rate error of 4.71 +/- 0.77 bpm (1.5% better than baseline; negligible relative to the 110-160 bpm physiological range). Cross-modal attention yields a 39% PSD MSE reduction over naive dual-channel concatenation, quantifying the contribution of maternal-fetal coupling. Our proposed framework advances computational modeling of the maternal-fetal cardiovascular system by enabling the synthesis of Doppler envelopes from dual-lead ECG. By analysis of both recoverable and residual Doppler components, this approach enables quantification of the purely mechanical contributions to Doppler waveforms -- those not recoverable from electrical recordings -- ultimately facilitating a more comprehensive fetal assessment.