Your search keyword '"Chai, Xiaoke"' showing total 23 results

1. Detections of Steady-State Visual Evoked Potential and Simultaneous Jaw Clench Action from Identical Occipital Electrodes: A Hybrid Brain-Computer Interface Study

Author

Zhang, Zhimin, Chai, Xiaoke, Guan, Kai, Liu, Tao, Xu, Jinxiu, Fan, Yubo, and Niu, Haijun

Published

2021

2. Clinical neuromodulatory effects of deep brain stimulation in disorder of consciousness: A literature review.

Author

Cao, Tianqing, He, Shenghong, Wang, Luchen, Chai, Xiaoke, He, Qiheng, Liu, Dongsheng, Wang, Dong, Wang, Nan, He, Jianghong, Wang, Shouyang, Yang, Yi, Zhao, Jizong, and Tan, Huiling

Subjects

DEEP brain stimulation, CONSCIOUSNESS disorders, MOVEMENT disorders, LITERATURE reviews, SUBTHALAMIC nucleus, PATIENT selection, BRAIN injuries

Abstract

Background: The management of patients with disorders of consciousness (DOC) presents substantial challenges in clinical practice. Deep brain stimulation (DBS) has emerged as a potential therapeutic approach, but the lack of standardized regulatory parameters for DBS in DOC hinders definitive conclusions. Objective: This comprehensive review aims to provide a detailed summary of the current issues concerning patient selection, target setting, and modulation parameters in clinical studies investigating the application of DBS for DOC patients. Methods: A meticulous systematic analysis of the literatures was conducted, encompassing articles published from 1968 to April 2023, retrieved from reputable databases (PubMed, Embase, Medline, and Web of Science). Results: The systematic analysis of 21 eligible articles, involving 146 patients with DOC resulting from acquired brain injury or other disorders, revealed significant insights. The most frequently targeted regions were the Centromedian‐parafascicular complex (CM‐pf) nuclei and central thalamus (CT), both recognized for their role in regulating consciousness. However, other targets have also been explored in different studies. The stimulation frequency was predominantly set at 25 or 100 Hz, with pulse width of 120 μs, and voltages ranged from 0 to 4 V. These parameters were customized based on individual patient responses and evaluations. The overall clinical efficacy rate in all included studies was 39.7%, indicating a positive effect of DBS in a subset of DOC patients. Nonetheless, the assessment methods, follow‐up durations, and outcome measures varied across studies, potentially contributing to the variability in reported efficacy rates. Conclusion: Despite the challenges arising from the lack of standardized parameters, DBS shows promising potential as a therapeutic option for patients with DOC. However, there still remains the need for standardized protocols and assessment methods, which are crucial to deepen the understanding and optimizing the therapeutic potential of DBS in this specific patient population. [ABSTRACT FROM AUTHOR]

Published

2024

3. Effects of fatigue on steady state motion visual evoked potentials: Optimised stimulus parameters for a zoom motion-based brain-computer interface

Author

Chai, Xiaoke, Zhang, Zhimin, Guan, Kai, Zhang, Tengyu, Xu, Jinxiu, and Niu, Haijun

Published

2020

4. A hybrid BCI-controlled smart home system combining SSVEP and EMG for individuals with paralysis

Author

Chai, Xiaoke, Zhang, Zhimin, Guan, Kai, Lu, Yangting, Liu, Guitong, Zhang, Tengyu, and Niu, Haijun

Published

2020

5. Brain–computer interface digital prescription for neurological disorders.

Author

Chai, Xiaoke, Cao, Tianqing, He, Qiheng, Wang, Nan, Zhang, Xuemin, Shan, Xinying, Lv, Zeping, Tu, Wenjun, Yang, Yi, and Zhao, Jizong

Subjects

*BRAIN-computer interfaces, *NEUROLOGICAL disorders, *MEDICAL prescriptions, *DIAGNOSIS, *ASSISTIVE technology

Abstract

Neurological and psychiatric diseases can lead to motor, language, emotional disorder, and cognitive, hearing or visual impairment By decoding the intention of the brain in real time, the Brain–computer interface (BCI) can first assist in the diagnosis of diseases, and can also compensate for its damaged function by directly interacting with the environment; In addition, provide output signals in various forms, such as actual motion, tactile or visual feedback, to assist in rehabilitation training; Further intervention in brain disorders is achieved by close‐looped neural modulation. In this article, we envision the future BCI digital prescription system for patients with different functional disorders and discuss the key contents in the prescription the brain signals, coding and decoding protocols and interaction paradigms, and assistive technology. Then, we discuss the details that need to be specially included in the digital prescription for different intervention technologies. The third part summarizes previous examples of intervention, focusing on how to select appropriate interaction paradigms for patients with different functional impairments. For the last part, we discussed the indicators and influencing factors in evaluating the therapeutic effect of BCI as intervention. [ABSTRACT FROM AUTHOR]

Published

2024

6. Effects of slow and regular breathing exercise on cardiopulmonary coupling and blood pressure

Author

Zhang, Zhengbo, Wang, Buqing, Wu, Hao, Chai, Xiaoke, Wang, Weidong, and Peng, Chung-Kang

Published

2017

7. Integral representations for hyperbolic harmonic function in the clifford algebra Cln+1,0.

Author

Bian, Xiaoli, Chai, Xiaoke, Wang, Haiyan, and Liu, Hua

Subjects

*FUNCTION algebras, *HYPERBOLIC functions, *INTEGRAL representations, *CLIFFORD algebras, *DIRAC operators

Abstract

The main goal of this paper is to give the basic principles of hyperbolic function theory. First, we discuss the Green identity for H k ¯ H k . Second, we also deal with the integral representations for hyperbolic harmonic function in the Clifford algebra C l n + 1 , 0. [ABSTRACT FROM AUTHOR]

Published

2023

8. Integral representations for hyperbolic harmonic function in the clifford algebra Cln+1,0.

Author

Bian, Xiaoli, Chai, Xiaoke, Wang, Haiyan, and Liu, Hua

Subjects

FUNCTION algebras, HYPERBOLIC functions, INTEGRAL representations, CLIFFORD algebras, DIRAC operators

Abstract

The main goal of this paper is to give the basic principles of hyperbolic function theory. First, we discuss the Green identity for H k ¯ H k . Second, we also deal with the integral representations for hyperbolic harmonic function in the Clifford algebra C l n + 1 , 0. [ABSTRACT FROM AUTHOR]

Published

2023

9. Neurophysiological evidence for goal-oriented modulation of speech perception.

Author

Chai, Xiaoke, Liu, Min, Huang, Ting, Wu, Meiyun, Li, Jinhong, Zhao, Xue, Yan, Tingting, Song, Yan, and Zhang, Yu-Xuan

Published

2023

10. Disulfiram Chelated With Copper Inhibits the Growth of Gastric Cancer Cells by Modulating Stress Response and Wnt/β-catenin Signaling.

Author

Wang, Ling, Chai, Xiaoke, Wan, Run, Zhang, Hong, Zhou, Cong, Xiang, Lin, Paul, Maswikiti Ewetse, and Li, Yumin

Subjects

CANCER cell growth, REACTIVE oxygen species, DISULFIRAM, OXYGEN consumption, CHELATES

Abstract

Disulfiram (DSF) is a well-known drug for alcohol abuse. In recent decades, DSF has been demonstrated to exhibit anti-tumor activity; DSF chelated with copper shows enhanced anti-tumor effect. Our goal was to explore the effect of DSF/Cu complex on the growth and metastasis of gastric cancer (GC) in vitro and in vivo. DSF/Cu complex suppressed the proliferation, migration of MKN-45 and BGC-823 GC cells. Furthermore, DSF/Cu treatment reduced the tumor volume in GC mouse models with a tumor suppression rate of 48.24%. Additionally, DSF/Cu induced apoptosis in vitro in MKN-45 and BGC-823 GC cells in a dose- and time-dependent manner as well as in vivo in the xenograft tumor mouse model. Furthermore, DSF/Cu induced autophagy and autophagic flux in MKN-45 and BGC-823 cells, increased the expression of autophagy-related Beclin-1 and LC3 proteins in vivo. Additionally, DSF/Cu suppressed aerobic glycolysis and oxidative phosphorylation by reducing oxygen consumption rate and extracellular acidification rate, respectively, in MKN-45 and BGC-823 cells. Treatment with DSF/Cu induced oxidative stress and DNA damage response by elevating the reactive oxygen species levels; increasing the expression of P53, P21, and γ-H2AX proteins; and inhibiting Wnt/β-catenin signaling in vitro and in vivo. Thus, DSF/Cu suppressed the growth and metastasis of GC cells via modulating the stress response and Wnt/β-catenin signaling. Hence, DSF may be used as a potential therapeutic agent for the treatment of GC. [ABSTRACT FROM AUTHOR]

Published

2020

11. A Radial Zoom Motion-Based Paradigm for Steady State Motion Visual Evoked Potentials.

Author

Chai, Xiaoke, Zhang, Zhimin, Guan, Kai, Liu, Guitong, and Niu, Haijun

Subjects

VISUAL evoked potentials, FATIGUE (Physiology), ELECTROENCEPHALOGRAPHY, BRAIN-computer interfaces, CANONICAL correlation (Statistics)

Abstract

Background: In steady state visual evoked potential (SSVEP)-based brain-computer interfaces, prolonged repeated flicker stimulation would reduce the system performance. To reduce the visual discomfort and fatigue, while ensuring recognition accuracy, and information transmission rate (ITR), a novel motion paradigm based on the steady-state motion visual evoked potentials (SSMVEPs) is proposed. Methods: The novel SSMVEP paradigm of the radial zoom motion was realized using the sinusoidal form to modulate the size of the stimuli. The radial zoom motion-based SSMVEP paradigm was compared with the flicker-based SSVEP paradigm and the SSMVEP paradigm based on Newton's ring motion. The canonical correlation analysis was used to identify the frequency of the eight targets, the recognition accuracy of different paradigms with different stimulation frequencies, and the ITR under different stimulation durations were calculated. The subjective comfort scores and fatigue scores, and decrease in the accuracy due to fatigue was evaluated. Results: The average recognition accuracy of the novel radial zoom motion-based SSMVEP paradigm was 93.4%, and its ITR reached 42.5 bit/min, which was greater than the average recognition accuracy of the SSMVEP paradigm based on Newton's ring motion. The comfort score of the novel paradigm was greater than both the flicker-based SSVEP paradigm and SSMVEP paradigm based on Newton's ring motion. The decrease in the recognition accuracy due to fatigue was less than that of the SSSMVEP paradigm based on Newton's ring motion. Conclusion: The SSMVEP paradigm based on radial zoom motion has high recognition accuracy and ITR with low visual discomfort and fatigue scores. The method has potential advantages in overcoming the performance decline caused by fatigue. [ABSTRACT FROM AUTHOR]

Published

2019

12. Anti‐phasic oscillatory development for speech and noise processing in cochlear implanted toddlers.

Author

Wu, Meiyun, Wang, Yuyang, Zhao, Xue, Xin, Tianyu, Wu, Kun, Liu, Haotian, Wu, Shinan, Liu, Min, Chai, Xiaoke, Li, Jinhong, Wei, Chaogang, Zhu, Chaozhe, Liu, Yuhe, and Zhang, Yu‐Xuan

Abstract

Human brain demonstrates amazing readiness for speech and language learning at birth, but the auditory development preceding such readiness remains unknown. Cochlear implanted (CI) children (n = 67; mean age 2.77 year ± 1.31 SD; 28 females) with prelingual deafness provide a unique opportunity to study this stage. Using functional near‐infrared spectroscopy, it was revealed that the brain of CI children was irresponsive to sounds at CI hearing onset. With increasing CI experiences up to 32 months, the brain demonstrated function, region and hemisphere specific development. Most strikingly, the left anterior temporal lobe showed an oscillatory trajectory, changing in opposite phases for speech and noise. The study provides the first longitudinal brain imaging evidence for early auditory development preceding speech acquisition. [ABSTRACT FROM AUTHOR]

Published

2024

13. Anatomical-related factors and outcome of percutaneous short-term spinal cord stimulation electrode shift in patients with disorders of consciousness: a retrospective study.

Author

He Q, Yang C, Xu Y, Niu H, Wu H, Huang H, Chai X, Cao T, Wang N, Wong P, He J, Yang Y, and Zhao J

Abstract

Background: Disorders of consciousness (DoC) represent a spectrum of neurological conditions that pose significant treatment challenges. Percutaneous short-term spinal cord stimulation (SCS) has emerged as a promising experimental diagnostic treatment to assess and potentially improve consciousness levels. However, the effectiveness of this intervention is frequently compromised by the shift of electrodes, particularly in the cervical region, which can negatively affect therapeutic outcomes., Methods: This retrospective study aimed to study if electrodes shift in percutaneous short-term SCS in patients with DoC would affect the outcome. We analyzed the relationship between electrode shift length and patient outcome, as well as the correlation with various anatomical parameters, including the actual length of the cervical spine, linear length, spinal canal transverse diameter, spinal canal diameter, and C2 cone height, in a cohort of patients undergoing the procedure., Results: Our findings revealed that in patients with better outcome, there are significant less patient with electrode shift ( p  = 0.019). Further, a linear correlation was found between the length of electrode shift and patients' outcome (Rho = 0.583, p  = 0.002), with longer shift lengths associated with poorer outcomes. Contrary to our expectations, there was no significant association between the measured anatomical parameters and the extent of electrode shift. However, a trend was found between the actual length of the cervical spine and the shift of the electrode ( p  = 0.098). Notably, the shorter spinal canal transverse diameter was found to be significantly associated with better outcome in patients with DoC receiving percutaneous short-term SCS ( p  = 0.033)., Conclusion: These results highlight the clinical importance of electrode stability in the cervical region during SCS treatment for patients with DoC. Ensuring secure placement of electrodes may play a crucial role in enhancing patients' outcome and minimize postoperative complications. Given the lack of association with expected anatomical parameters, future research should investigate other factors that could impact electrode stability to optimize this therapeutic intervention., Competing Interests: The authors declare that the research was conducted in the absence of any commercial or financial relationships that could be construed as a potential conflict of interest., (Copyright © 2024 He, Yang, Xu, Niu, Wu, Huang, Chai, Cao, Wang, Wong, He, Yang and Zhao.)

Published

2024

14. The brain nebula: minimally invasive brain-computer interface by endovascular neural recording and stimulation.

Author

He Q, Yang Y, Ge P, Li S, Chai X, Luo Z, and Zhao J

Abstract

A brain-computer interface (BCI) serves as a direct communication channel between brain activity and external devices, typically a computer or robotic limb. Advances in technology have led to the increasing use of intracranial electrical recording or stimulation in the treatment of conditions such as epilepsy, depression, and movement disorders. This indicates that BCIs can offer clinical neurological rehabilitation for patients with disabilities and functional impairments. They also provide a means to restore consciousness and functionality for patients with sequelae from major brain diseases. Whether invasive or non-invasive, the collected cortical or deep signals can be decoded and translated for communication. This review aims to provide an overview of the advantages of endovascular BCIs compared with conventional BCIs, along with insights into the specific anatomical regions under study. Given the rapid progress, we also provide updates on ongoing clinical trials and the prospects for current research involving endovascular electrodes., Competing Interests: Competing interests: None declared., (© Author(s) (or their employer(s)) 2024. Re-use permitted under CC BY-NC. No commercial re-use. See rights and permissions. Published by BMJ.)

Published

2024

15. EEG Based Dynamic Functional Connectivity Analysis in Mental Workload Tasks With Different Types of Information.

Author

Guan K, Zhang Z, Chai X, Tian Z, Liu T, and Niu H

Subjects

Brain physiology, Humans, Man-Machine Systems, Parietal Lobe, Electroencephalography methods, Workload psychology

Abstract

The accurate evaluation of operators' mental workload in human-machine systems plays an important role in ensuring the correct execution of tasks and the safety of operators. However, the performance of cross-task mental workload evaluation based on physiological metrics remains unsatisfactory. To explore the changes in dynamic functional connectivity properties with varying mental workload in different tasks, four mental workload tasks with different types of information were designed and a newly proposed dynamic brain network analysis method based on EEG microstate was applied in this paper. Six microstate topographies labeled as Microstate A-F were obtained to describe the task-state EEG dynamics, which was highly consistent with previous studies. Dynamic brain network analysis revealed that 15 nodes and 68 pairs of connectivity from the Frontal-Parietal region were sensitive to mental workload in all four tasks, indicating that these nodal metrics had potential to effectively evaluate mental workload in the cross-task scenario. The characteristic path length of Microstate D brain network in both Theta and Alpha bands decreased whereas the global efficiency increased significantly when the mental workload became higher, suggesting that the cognitive control network of brain tended to have higher function integration property under high mental workload state. Furthermore, by using a SVM classifier, an averaged classification accuracy of 95.8% for within-task and 80.3% for cross-task mental workload discrimination were achieved. Results implies that it is feasible to evaluate the cross-task mental workload using the dynamic functional connectivity metrics under specific microstate, which provided a new insight for understanding the neural mechanism of mental workload with different types of information.

Published

2022

16. Evaluation of Mental Workload in Working Memory Tasks with Different Information Types Based on EEG.

Author

Guan K, Chai X, Zhang Z, Li Q, and Niu H

Subjects

Parietal Lobe, Reaction Time, Workload, Electroencephalography, Memory, Short-Term

Abstract

To explore the effectiveness of using Electro- encephalogram (EEG) spectral power and multiscale sample entropy for accessing mental workload in different tasks, working memory tasks with different information types (verbal, object and spatial) and various mental loads were designed based on the N-Back paradigm. Subjective scores, accuracy and response time were used to verify the rationality of the tasks. EEGs from 18 normal adults were acquired when tasks were being performed, an independent component analysis (ICA) based artifact removal method were applied to get clean data. Linear (relative power in Theta and Alpha band, etc.) and nonlinear (multiscale sample entropy) features of EEGs were then extracted. Indices that can effectively reflect mental workload levels were selected by using multivariate analysis of variance statistical approach. Results showed that with the increment of task load, power of frontal Theta, Theta/Alpha ratio and sample entropies at scale more than 10 in parietal regions increased significantly first and decreased slightly then, while the power of central-parietal Alpha decreased significantly first and increased slightly then. Considering the difference between task types, no difference in power of frontal Theta, central-parietal Alpha and sample entropies at scales more than 10 of parietal regions were found between verbal and object tasks, as well as between two spatial tasks. No difference of frontal Theta/Alpha ratio was found in all the four tasks. The results can provide evidence for the mental workload evaluation in tasks with different information types.

Published

2021

17. Effects of Jaw Clench Actions on Steady-State Visual Evoked Potential Detection at Some Typical Frequencies.

Author

Zhang Z, Guan K, Wang L, Chai X, Ma Y, Gao X, Liu T, and Niu H

Subjects

Canonical Correlation Analysis, Electroencephalography, Humans, Photic Stimulation, Brain-Computer Interfaces, Evoked Potentials, Visual

Abstract

More and more hybrid brain-computer interfaces (BCI) supplement traditional single-modality BCI in practical applications. Combinations based on steady-state visual evoked potential (SSVEP) and electromyography (EMG) are the widely used hybrid BCIs. The EMG of jaw clench is commonly used together with SSVEP. This article explored the interference with SSVEP from occipital electrodes by the jaw clench-related EMG so that SSVEP with specific frequency can be identified even during occlusal movements. The experiment was divided into three sets base on the jaw clench patterns (no clenches, chew, and long clench). In each set, the subjects used the same visual stimuli, which were realized by the three flashing targets at different frequencies (6.2Hz, 9.8Hz, and 14.6Hz). After collecting the SSVEP at 4 sites in the occipital region, the SSVEP response spectrum of each stimulus was observed under the three jaw clench patterns. Then, the SSVEP signal was identified by the canonical correlation analysis method for accuracy statistics. Spectrum responses showed that the interference of the jaw clench EMG on SSVEP could be avoided when the stimulation frequency is lower than 20Hz. SSVEP could be identified based on the frequency domain characteristics of these signals. During steady-state visual stimulation with jaw clenches, the recognition rate of SSVEP was still high (no clenches: 100.0%, chew: 94.7%, and long clench: 100.0%). Through reasonable frequency selecting and signal processing, the influence of the jaw clench movement on the SSVEP could be reduced and a high recognition accuracy could be achieved, even the jaw clench actions and the SSVEP stimulation occur simultaneously.

Published

2021

18. [Study of Steady State Motion Visual Evoked Potential-based Visual Stimulation of BCI System].

Author

Liu G, Zhang Z, Chai X, Lu Y, Fan Y, and Niu H

Subjects

Electroencephalography instrumentation, Motion, Brain-Computer Interfaces, Evoked Potentials, Visual, Photic Stimulation

Abstract

Objective: To propose a square's ring motion stimulation based on steady-state motion visual evoked potential, and compare it with the commonly used visual stimulation modes (Newton's ring motion, square flicker and circular flicker)., Methods: EEG signals were collected while 9 experimental subjects gazing at four stimulation and pattern analyzed by Canonical Correlation Analysis (CCA). Stimulation were evaluated by recognition accuracy and subjective scores., Results: The classification accuracies of SSVEP elicited by the square's ring motion(82.8%±14.1%) and Newton's ring(83.3%±11.5%) have no significant difference between them, which are lower than that of the square flicker(98.3%±4.1%) and the circular flicker(99.2%±1.8%). The shape of the figure has no significant influence on the classification accuracy either in motion mode or flicker mode. The comfort of the square's ring motion is higher than the other three stimulation according to subjective scores., Conclusions: The square's ring motion can elicit EEG and reduce the discomfort caused by flicker modes. The square's ring motion can be used as a visual stimulation in SSMVEP-based BCI system.

Published

2018

19. [Variation of SpO2 during a Step-wise Paced Breathing Procedure].

Author

Hang N, Wang M, Wang J, Zhang Z, Wang B, and Chai X

Subjects

Altitude, Humans, Hypoxia, Oximetry, Oxygen, Heart Rate, Respiration

Abstract

Rhythmic respiratory movement in a deep and slow pattern can be beneficial to cardiovascular system, this paper investigates the effect of step-wise paced breathing procedure on blood oxygen saturation (SpO2). Experiment objects were divided into two groups, the normobaric hypoxia (simulated altitude of 4 500 meters hypoxia environment, 8 persons), normoxia and normobaric group (laboratory environment, 49 persons). The respiratory movements were performed by a high-to-low progressive change in two groups respectively. During the experiment, each object's blood oxygen saturation and heart rate were recorded. Results showed that progressive guided breathing could significantly increase the subjects' blood oxygen saturation level from 90% to 95% under the hypoxic condition. Even under the normobaric and normoxic condition, progressive guided breathing with stable blood oxygen saturation level can also enhance the blood oxygen saturation level. In both groups, mean heart rate declined in the progressive guided breathing. The research showed that the step-wise paced breathing technique could regulate the blood oxygen saturation and effectively improve the level of blood oxygen saturation by adjusting the respiratory motion in the low oxygen environment.

Published

2017

20. [Study on the Optimum Order of Autoregressive Models for Heart Rate Variability Analysis].

Author

Chai X, Wang B, Zhang Z, and Wang W

Subjects

Adult, Autonomic Nervous System, Humans, Reproducibility of Results, Software, Electrocardiography, Heart Rate, Models, Cardiovascular

Abstract

Heart rate variability (HRV) analysis technology based on an autoregressive (AR) model is widely used in the assessment of autonomic nervous system function. The order of AR models has important influence on the accuracy of HRV analysis. This article presents a method to determine the optimum order of AR models. After acquiring the ECG signal of 46 healthy adults in their natural breathing state and extracting the beat-to-beat intervals (RRI) in the ECG, we used two criteria, i. e. final prediction error (FPE) criterion to estimate the optimum model order for AR models, and prediction error whiteness test to decide the reliability of the model. We compared the frequency domain parameters including total power, power in high frequency (HF), power in low frequency (LF), LF power in normalized units and ratio of LF/HF of our HRV analysis to the results of Kubios-HRV. The results showed that the correlation coefficients of the five parameters between our methods and Kubios-HRV were greater than 0.95, and the Bland-Altman plot of the parameters was in the consistent band. The results indicate that the optimization algorithm of HRV analysis based on AR models proposed in this paper can obtain accurate results, and the results of this algorithm has good coherence with those of the Kubios-HRV software in HRV analysis.

Published

2015

21. [The Study of the Measurement of Heart Rate Variability Using ECG and Photoplethysmographic Signal].

Author

Wang B, Chai X, Zhang Zhengbo, and Wang W

Subjects

Adult, Algorithms, Humans, Reproducibility of Results, Electrocardiography, Heart Rate, Photoplethysmography

Abstract

In comparison with the measurement of heart rate variability from ECG and from photoplethysmographic signal from 46 healthy adults in their spontaneous breathing state. The beat-to-beat intervals in ECG and pulse-to-pulse intervals in photoplethysmographic signal are extracted, and then the parameters of heart rate variability are calculated. Three kinds of algorithms are chosen to get the pulse-to-pulse intervals, which are the intervals of maximum of second derivative, the maximum of PPG signal and the tangent intersection. The results show that the correlation coefficients of the HRV parameters in the two calculation methods are highly correlated. The Bland-Altman scattered plots show the relative bias results from the algorithm of the maximum of PPG signal are smallest and singular points that deviate from the consistent limits are the least compared with the other two algorithms.

Published

2015

22. [Change of pulse transit time during stepwise paced breathing].

Author

Chai X, Wang B, Zhang Z, Wang G, and Wang W

Subjects

Adult, Blood Pressure, Blood Pressure Determination, Essential Hypertension, Humans, Hypertension, Electrocardiography, Pulse Wave Analysis, Respiration, Respiratory Rate

Abstract

To investigate the effect of stepwise paced breathing (PB) on pulse transit time (PTT), we collected physiological signals of electrocardiogram (ECG), respiration and arterial pulse wave during a procedure of stepwise PB, which consists of 6 different breathing rates changing in a protocol of 14.0-12.5-11.0-9.5-8.0-7.0 breath per minute (BPM), with each breathing rate lasting 3 minutes. Twenty two healthy adults involved in this experiment and the change of PTT was analyzed during the stepwise PB procedure. In our study, the PTT was measured by calculating the time interval from the R-spike of the ECG to the peaks of the second derivative of the arterial pulse wave. Ensemble empirical mode decomposition (EEMD) was applied to PTT to decompose the signal into different intrinsic mode function, and respiratory oscillation and trend component (baseline) in PTT were further extracted. It was found that the respiratory oscillations in the PTT increased with decreasing of the PB rate, and many of the subjects (14 out of 22) showed the phenomena of PTT baseline increasing during the stepwise PB procedure. The results indicated that the stepwise PB procedure induced a high level of cardiovascular oscillation and produced an accumulative effect of PTT baseline increase. As PTT is capable of predicting changes in BP over a short period of time, increase of PTT baseline indicates the decrease of blood pressure. The experiments showed that the stepwise PB procedure could reduce blood pressure for most subjects. For future work, it is necessary to develop certain indices differentiating the effectiveness of the stepwise PB procedure on the PTT baseline change, and to test the effectiveness of this stepwise PB procedure on blood pressure reduction for patients with essential hypertension.

Published

2014

23. [Clinical data mining by exploring public MIMIC-II intensive care database].

Author

Wang J, Zhang Z, Wang W, Pan L, and Chai X

Subjects

Blood Pressure, Circadian Rhythm, Heart Rate, Humans, Critical Care, Data Mining, Databases, Factual, Medical Informatics

Abstract

This paper introduces a free and publicly open ICU database: multi-parameter intelligent monitoring in intensive care II: MIMIC-II, which has been built up and maintained by the laboratory of computational physiology at the Massachusetts Institute Technology, Beth Israel Deaconess Medical Center and Philips Healthcare over the past decade. This paper briefly introduces its infrastructure, implementation and applications in clinical studies. Clinical study pertaining to circadian variation in heart rate and blood pressure during sepsis is shown as a typical example of research performed with MIMIC-II. In this study, it was found there was significant difference in circadian variation in both heart rate and blood pressure between survival and non-survival groups in septic patients. This study tackled several important techniques necessary for the investigation of the circadian rhythm.

Published

2014