TY - JOUR
T1 - Evaluating Cardiac Impairment From Abnormal Respiratory Patterns
T2 - Insights From a Wireless Radar and Deep Learning Study
AU - Chiu, Chun Chih
AU - Liu, Wen Te
AU - Kang, Jiunn Horng
AU - Chen, Chun Chao
AU - Ho, Yu Hsuan
AU - Huang, Yu Wen
AU - Tsai, Zong Lin
AU - Chien, Rachel
AU - Chen, Ying Ying
AU - Chen, Yen Ling
AU - Chang, Nai Wen
AU - Lu, Hung Wen
AU - Lee, Kang Yun
AU - Majumdar, Arnab
AU - Liao, Shu Han
AU - Liu, Ju Chi
AU - Tsai, Cheng Yu
N1 - Publisher Copyright:
© 2013 IEEE.
PY - 2025
Y1 - 2025
N2 - Objectives: Assessing the bidirectional impacts of heart function impairment and sleep-disordered breathing remains underexplored. Thus, this study analyzed respiratory patterns from a wireless radar framework to explore their associations with echocardiographic (2D-echo) measurements. Methods: Background details, 2D-echo parameters, and biochemical data were collected from patients in a cardiology ward in northern Taiwan. Their radar-based respiratory patterns from the night before and the night of the 2D-echo were obtained, averaged, and used to derive indices such as the respiratory disturbance index (RDI) and periodic breathing (PB) cycle length, representing overall respiratory patterns. Next, retrieved data were grouped based on a 50% left ventricular ejection fraction (LVEF) threshold and analyzed using mean comparisons and regression models to explore relationships. Results: Patients with an LVEF of ≤50 % demonstrated significantly reduced total sleep time, higher RDI, and longer PB cycles compared to those with LVEF >50%. Each 1-event/h increase in the RDI reduced the LVEF by 0.22% (95% confidence interval [CI]: −0.41% to −0.03%, p <0.05), and each 1-s increase in the PB cycle length was associated with a 0.21% LVEF reduction (95% CI: −0.35% to −0.07%). Increases in RDI and PB cycle length were associated with a heightened risk of LVEF declining to ≤50 % from >50%. Subgroup analysis revealed that the PB cycle length was associated with elevated N-terminal-prohormone-brain-natriuretic-peptide (NT-proBNP) levels. Conclusions: This study demonstrates that a wireless radar framework combined with deep learning can effectively monitor respiratory patterns that are associated with cardiac function. Its contactless nature may support continuous cardiac function assessments. Clinical Impact: This study highlights the effectiveness of a wireless radar and deep learning framework for monitoring respiratory patterns that are associated with cardiac function (e.g., LVEF), underscoring its potential for long-term cardiac and sleep-disorder management.
AB - Objectives: Assessing the bidirectional impacts of heart function impairment and sleep-disordered breathing remains underexplored. Thus, this study analyzed respiratory patterns from a wireless radar framework to explore their associations with echocardiographic (2D-echo) measurements. Methods: Background details, 2D-echo parameters, and biochemical data were collected from patients in a cardiology ward in northern Taiwan. Their radar-based respiratory patterns from the night before and the night of the 2D-echo were obtained, averaged, and used to derive indices such as the respiratory disturbance index (RDI) and periodic breathing (PB) cycle length, representing overall respiratory patterns. Next, retrieved data were grouped based on a 50% left ventricular ejection fraction (LVEF) threshold and analyzed using mean comparisons and regression models to explore relationships. Results: Patients with an LVEF of ≤50 % demonstrated significantly reduced total sleep time, higher RDI, and longer PB cycles compared to those with LVEF >50%. Each 1-event/h increase in the RDI reduced the LVEF by 0.22% (95% confidence interval [CI]: −0.41% to −0.03%, p <0.05), and each 1-s increase in the PB cycle length was associated with a 0.21% LVEF reduction (95% CI: −0.35% to −0.07%). Increases in RDI and PB cycle length were associated with a heightened risk of LVEF declining to ≤50 % from >50%. Subgroup analysis revealed that the PB cycle length was associated with elevated N-terminal-prohormone-brain-natriuretic-peptide (NT-proBNP) levels. Conclusions: This study demonstrates that a wireless radar framework combined with deep learning can effectively monitor respiratory patterns that are associated with cardiac function. Its contactless nature may support continuous cardiac function assessments. Clinical Impact: This study highlights the effectiveness of a wireless radar and deep learning framework for monitoring respiratory patterns that are associated with cardiac function (e.g., LVEF), underscoring its potential for long-term cardiac and sleep-disorder management.
KW - echocardiographic (2D-echo) measurements
KW - left ventricular ejection fraction (LVEF)
KW - periodic breathing (PB) cycle length
KW - respiratory disturbance index (RDI)
KW - Sleep-disordered breathing
KW - echocardiographic (2D-echo) measurements
KW - left ventricular ejection fraction (LVEF)
KW - periodic breathing (PB) cycle length
KW - respiratory disturbance index (RDI)
KW - Sleep-disordered breathing
UR - https://www.scopus.com/pages/publications/105011683549
UR - https://www.scopus.com/inward/citedby.url?scp=105011683549&partnerID=8YFLogxK
U2 - 10.1109/JTEHM.2025.3588523
DO - 10.1109/JTEHM.2025.3588523
M3 - Article
C2 - 40740837
AN - SCOPUS:105011683549
SN - 2168-2372
VL - 13
SP - 323
EP - 332
JO - IEEE Journal of Translational Engineering in Health and Medicine
JF - IEEE Journal of Translational Engineering in Health and Medicine
ER -