Your search keyword '"Lee, Boreom"' showing total 5 results

1. Development of 3D-printed myoelectric hand orthosis for patients with spinal cord injury

Author

Yoo, Hyun-Joon, Lee, Sangbaek, Kim, Jongheon, Park, Chanki, and Lee, Boreom

Published

2019

2. Robust detection of heartbeats using association models from blood pressure and EEG signals.

Author

Taegyun Jeon, Jongmin Yu, Witold Pedrycz, Moongu Jeon, Boreom Lee, Byeongcheol Lee, Jeon, Taegyun, Yu, Jongmin, Pedrycz, Witold, Jeon, Moongu, Lee, Boreom, and Lee, Byeongcheol

Subjects

HEART beat measurement, ELECTROCARDIOGRAPHY, BLOOD pressure, ELECTROENCEPHALOGRAPHY, PATIENT monitoring, CRITICAL care medicine, HEART physiology, ALGORITHMS, SIGNAL processing, TIME, STATISTICAL models

Abstract

Backgrounds: The heartbeat is fundamental cardiac activity which is straightforwardly detected with a variety of measurement techniques for analyzing physiological signals. Unfortunately, unexpected noise or contaminated signals can distort or cut out electrocardiogram (ECG) signals in practice, misleading the heartbeat detectors to report a false heart rate or suspend itself for a considerable length of time in the worst case. To deal with the problem of unreliable heartbeat detection, PhysioNet/CinC suggests a challenge in 2014 for developing robust heart beat detectors using multimodal signals.Methods: This article proposes a multimodal data association method that supplements ECG as a primary input signal with blood pressure (BP) and electroencephalogram (EEG) as complementary input signals when input signals are unreliable. If the current signal quality index (SQI) qualifies ECG as a reliable input signal, our method applies QRS detection to ECG and reports heartbeats. Otherwise, the current SQI selects the best supplementary input signal between BP and EEG after evaluating the current SQI of BP. When BP is chosen as a supplementary input signal, our association model between ECG and BP enables us to compute their regular intervals, detect characteristics BP signals, and estimate the locations of the heartbeat. When both ECG and BP are not qualified, our fusion method resorts to the association model between ECG and EEG that allows us to apply an adaptive filter to ECG and EEG, extract the QRS candidates, and report heartbeats.Results: The proposed method achieved an overall score of 86.26 % for the test data when the input signals are unreliable. Our method outperformed the traditional method, which achieved 79.28 % using QRS detector and BP detector from PhysioNet. Our multimodal signal processing method outperforms the conventional unimodal method of taking ECG signals alone for both training and test data sets.Conclusions: To detect the heartbeat robustly, we have proposed a novel multimodal data association method of supplementing ECG with a variety of physiological signals and accounting for the patient-specific lag between different pulsatile signals and ECG. Multimodal signal detectors and data-fusion approaches such as those proposed in this article can reduce false alarms and improve patient monitoring. [ABSTRACT FROM AUTHOR]

Published

2016

3. Real-time estimation of respiratory rate from a photoplethysmogram using an adaptive lattice notch filter.

Author

Park, Chanki and Lee, Boreom

Published

2014

4. Robust detection of heartbeats using association models from blood pressure and EEG signals.

Author

Jeon T, Yu J, Pedrycz W, Jeon M, Lee B, and Lee B

Subjects

Adult, Algorithms, Humans, Time Factors, Blood Pressure, Electroencephalography, Heart physiology, Models, Statistical, Signal Processing, Computer-Assisted

Abstract

Backgrounds: The heartbeat is fundamental cardiac activity which is straightforwardly detected with a variety of measurement techniques for analyzing physiological signals. Unfortunately, unexpected noise or contaminated signals can distort or cut out electrocardiogram (ECG) signals in practice, misleading the heartbeat detectors to report a false heart rate or suspend itself for a considerable length of time in the worst case. To deal with the problem of unreliable heartbeat detection, PhysioNet/CinC suggests a challenge in 2014 for developing robust heart beat detectors using multimodal signals., Methods: This article proposes a multimodal data association method that supplements ECG as a primary input signal with blood pressure (BP) and electroencephalogram (EEG) as complementary input signals when input signals are unreliable. If the current signal quality index (SQI) qualifies ECG as a reliable input signal, our method applies QRS detection to ECG and reports heartbeats. Otherwise, the current SQI selects the best supplementary input signal between BP and EEG after evaluating the current SQI of BP. When BP is chosen as a supplementary input signal, our association model between ECG and BP enables us to compute their regular intervals, detect characteristics BP signals, and estimate the locations of the heartbeat. When both ECG and BP are not qualified, our fusion method resorts to the association model between ECG and EEG that allows us to apply an adaptive filter to ECG and EEG, extract the QRS candidates, and report heartbeats., Results: The proposed method achieved an overall score of 86.26 % for the test data when the input signals are unreliable. Our method outperformed the traditional method, which achieved 79.28 % using QRS detector and BP detector from PhysioNet. Our multimodal signal processing method outperforms the conventional unimodal method of taking ECG signals alone for both training and test data sets., Conclusions: To detect the heartbeat robustly, we have proposed a novel multimodal data association method of supplementing ECG with a variety of physiological signals and accounting for the patient-specific lag between different pulsatile signals and ECG. Multimodal signal detectors and data-fusion approaches such as those proposed in this article can reduce false alarms and improve patient monitoring.

Published

2016

5. Non-invasive detection of intracranial hypertension using a simplified intracranial hemo- and hydro-dynamics model.

Author

Lee KJ, Park C, Oh J, and Lee B

Subjects

Blood Pressure Determination instrumentation, Body Water, Computer Systems, Humans, Intracranial Hypertension physiopathology, Monitoring, Physiologic methods, Pulsatile Flow, Rest, Algorithms, Blood Pressure Determination methods, Computer Simulation, Hemodynamics, Hydrodynamics, Intracranial Hypertension diagnosis, Intracranial Pressure physiology, Models, Biological, Ultrasonography, Doppler, Transcranial methods, Valsalva Maneuver physiology

Abstract

Background: Monitoring of intracranial pressure (ICP) is highly important for detecting abnormal brain conditions such as intracranial hemorrhage, cerebral edema, or brain tumor. Until now, the monitoring of ICP requires an invasive method which has many disadvantages including the risk of infections, hemorrhage, or brain herniation. Therefore, many non-invasive methods have been proposed for estimating ICP. However, these methods are still insufficient to estimate sudden increases in ICP., Methods: We proposed a simplified intracranial hemo- and hydro-dynamics model that consisted of two simple resistance circuits. From this proposed model, we designed an ICP estimation algorithm to trace ICP changes. First, we performed a simulation based on the original Ursino model with the real arterial blood pressure to investigate our proposed approach. We subsequently applied it to experimental data that were measured during the Valsalva maneuver (VM) and resting state, respectively., Results: Simulation result revealed a small root mean square error (RMSE) between the estimated ICP by our approach and the reference ICP derived from the original Ursino model. Compared to the pulsatility index (PI) based approach and Kashif's model, our proposed method showed more statistically significant difference between VM and resting state., Conclusion: Our proposed method successfully tracked sudden ICP increases. Therefore, our method may serve as a suitable tool for non-invasive ICP monitoring.

Published

2015