慢性頸痛患者的睡眠電生理訊號分析

Jiunn-Horng Kang; 康峻宏

請用此 Handle URI 來引用此文件： http://tdr.lib.ntu.edu.tw/jspui/handle/123456789/23840

完整後設資料紀錄

DC 欄位	值	語言
dc.contributor.advisor	趙福杉
dc.contributor.author	Jiunn-Horng Kang	en
dc.contributor.author	康峻宏	zh_TW
dc.date.accessioned	2021-06-08T05:10:53Z	-
dc.date.copyright	2011-07-25
dc.date.issued	2011
dc.date.submitted	2011-07-07
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dc.identifier.uri	http://tdr.lib.ntu.edu.tw/jspui/handle/123456789/23840	-
dc.description.abstract	Chronic neck pain is defined as the duration of neck symptoms last for more than 6 months. It is estimated about 7.6% of general population having chronic neck pain. In addition to increased medical burden, neck pain is also one of the most frequent causes for lost workdays and pension claims. Although the specific pathomechanism of chronic neck pain is still unclear, identified risk factors include jobs pattern with high repetitive and monotonic movements, prior neck/shoulder injury, perceptive stress, low-pressure pain threshold to tenderness, and psychosocial factors. Some longitudinal study reported these patients may have poor prognosis and a significant ratio of patients had persist symptoms. The strong association between pain and sleep has been recognized. Most of patients who have underlying pain disorders suffer from sleep disturbance. Patients with pain conditions usually complain the difficulty to fall asleep, awake after sleep, reduced total sleep time and non-refreshing sleep. Sleep disturbance is associated with poor outcome of patients with chronic pain. Sleep can also directly modulate pain. Previous study showed the pain perception threshold can be altered after sleep deprivation in both normal subjects and patients with pain conditions. From previous polysomnography study, the patients with chronic pain had increased sleep fragmentation, decreased slow wave sleep, and alpha intrusion were reported. Some evidence supports the involvement of a dysautonomia is also involved in the pathogenesis of chronic pain. Worth noting, in patients with underlying pain, changes in autonomic balance could have primary origins, from an inherent dysfunctional central autonomic network, or secondary origins, as a response to pain or emotion associated with pain. Decreased vagal and increased sympathetic regulation may impart resistance to pain behavior. As a complex system, the biological system is usually inherently a non-linear and non-stationary system. Therefore, applying linear analysis to approach biological time series may be inadequate and miss some important information. In this thesis, we aim to investigate the presentations in sleep and autonomic system in the patients with chronic neck pain in a series of study. In addition, we used several non-linear methods to approach this topic. First, we found the heart rate variability (HRV) at resting status was significantly correlated with the level of disability in the patients with chronic neck pain. We suggest that HRV analysis may provide an objective tool to evaluate the severity of chronic neck pain. Furthermore, we conducted a standard PSG and concurrent linear and nonlinear analysis of HRV in the patients with chronic neck pain. We found the patients with chronic neck pain had lower approximate entropy and sample entropy of heart rate series during sleep compared to control group. However, the difference of HRV parameters in time and frequency domains between patients and controls was not significant. Hence, we suggest nonlinear analysis of HRV may be a more sensitive tool to detect the autonomic dysfunction in the patients with chronic neck pain. Our results also support that heart rate complexity is altered in the patients with chronic pain which implied these patients have altered baseline autonomic status even during sleep. We found that the patients with chronic neck pain had significantly lower entropy of electroencephalography (EEG) during sleep compared to controls, particularly in the awake, light sleep and overall sleep. In addition, a specific pattern of multiscale entropy can be found in the patients with chronic neck pain. The pathomechanism of our observation is still unknown. Previous studies demonstrated the EEG entropy is altered in several mental or neurological diseases. Decreased EEG entropy is associated with the disruption of neural network. Therefore, we hypothesize that underlying neural network could be altered during sleep in the patients with chronic pain. Non-linear analysis provides a powerful approach to investigate the biomedical signals. Nevertheless, further studies to evaluate the physiological basis and potential applications are still needed.	en
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dc.description.tableofcontents	List 致謝 IV Abbreviation V 中文摘要 VI Abstract IX Chapter 1. Introduction 12 1.1. Epidemiology and clinical characteristics of chronic neck pain 12 1.2. The association between sleep and pain 13 1.3. The association between autonomic system and pain 17 1.4. Heart rate variability analysis (HRV) in pain studies 19 1.5.Non-linear analysis for biological time series 23 1.5.1 Information theory based approaches 24 1.5.2. Chaos dynamics based approaches 25 Chapter 2. Clustering and HRV analysis with the disability in the patients with chronic neck pain 29 2.1. Hypothesis and goal of study 29 2.2. Material and methods 30 2.2.1. Subjects 30 2.2.2. 5-minute resting state heart rate variability measurement 30 2.2.3. Questionnaires 32 2.2.3.1. Pittsburgh Sleep Quality Index (PSQI) 32 2.2.3.2. Chinese health questionnaire-12 (CHQ-12) 32 2.2.3.3. Neck disability index (NDI) 32 2.2.4. Pressure pain threshold (PPT) measurement 33 2.2.5. Clustering and statistical analysis 34 2.3. Results 35 2.3.1. Basic variables 35 2.3.2. Results from 5-minute HRV analysis in time and frequency domain 37 2.3.3. Results from clustering analysis 39 2.3.4. Correlation between disability and other variables 42 2.4. Discussions 44 Chapter 3. Linear and non-linear heart rate variability analysis during sleep in the patients with chronic neck pain 48 3.1. Hypothesis and goal of study 48 3.2. Material and methods 48 3.2.1. Subjects 49 3.2.2 Polysomnography (PSG) 49 3.3. Data extraction and Heart rate variability (HRV) analysis 51 3.3.1. Poincare plot analysis 53 3.3.2. Detrended fluctuation analysis (DFA) 54 3.3.3. Approximate entropy (ApEn) and sample entropy (SpEn) 57 3.3.4. Correlation dimension (D2) 58 3.2.4. Statistical Analysis 59 3.3 Results 60 3.3.1. Basic variables 60 3.3.2 PSG parameters 61 3.3.3 Linear and nonlinear HRV analysis 63 3.4 Discussions 66 Chapter 4. Entropy analysis of EEG signals during sleep in the patients with chronic neck pain 70 4.1. Hypothesis and goal of study 70 4.2. Material and methods 70 4.2.1. Subjects 70 4.2.2. Polysomnograpy (PSG) and EEG data extraction 71 4.2.3. Renyi entropy analysis of EEG 71 4.2.4. Multiscale entropy (MSE) analysis 72 4.3.5. Statistical Analysis 73 4.3. Results 74 4.3.1 Basic variables 74 4.3.2 PSG parameters 75 4.3.3 Renyi entropy(RE) analysis 77 4.3.4. Multiscale entropy 80 4.4. Discussions 82 Chapter 5. Limitations 86 Chapter 6. Conclusions 87 6.1. Clustering and HRV analysis with the disability in the patients with chronic neck pain 87 6.2. Heart rate variability during sleep in patients with chronic neck pain 87 6.3 EEG entropy during sleep in patients with chronic neck pain 88 Chapter 7. Future work 89 7.1. Longitudinal study of HRV and EEG entropy analysis in patients with chronic neck pain 89 7.2. Investigation of the multi-channel interactions with non-linear analysis 89 7.3. Correlation study with other research modality 90 7.4 Verifications in animal model 90 Reference 91 Acknowledgement 105 Honors and Publication list 106 List of Tables Table 2.1. Basic variables of patients with chronic neck pain 36 Table 2.2. 5-minute HRV analysis during resting state in time and frequency domain in the patients with chronic neck pain 38 Table 3.1. The basic profile of subjects and pain characteristic for patient group 61 Table 3.2. Comparison of sleep parameters between two groups 62 Table 3.3. Six-hour HRV during sleep in time domain and frequency domain of controls and subjects with chronic neck pain 64 Table 4.1. Basic subject profile 74 Table 4.2. Comparison of polysomnographic findings between the controls and patients with chronic neck pain 76 Table 4.3. Renyi entropy of EEG during sleep between the controls and patients with chronic neck pain 77 List of Figures Figure 1.1. N2 sleep in a normal subject. 16 Figure 1.2. REM sleep in a normal subject. 16 Figure 1.3. Power density spectrum of HRV of a normal subject. 21 Figure 1.4. Lorenz attractor. 26 Figure 2.1. Pressure Algometry 33 Figure 2.2. The sites for measurement of pressure pain threshold. 34 Figure 2.3. The subgroups based on two-step clustering analysis 39 Figure 2.4 The distribution of variables of symptoms among three subgroups with chronic neck pain 41 Figure 3.3. RR Tachogram from a subject with chronic neck pain 52 Figure 3.4. Poincare plot analysis of HRV. 54 Figure 3.5. Detrended fluctuation analysis of HRV 56 Figure 3.6. Non-linear analysis of HRV between the controls and patients with chronic neck pain 65 Figure 4.1. 10-20 system of EEG 71 Figure 4.1. Renyi entropy of EEG during sleep in control subjects and patients with chronic neck pain 79 Figure 4.2. Multiscale entropy analysis of EEG during sleep in the patient with chronic neck pain. 81
dc.language.iso	en
dc.title	慢性頸痛患者的睡眠電生理訊號分析	zh_TW
dc.title	Analysis of electrophysiological signals of the patients with chronic neck pain during sleep	en
dc.type	Thesis
dc.date.schoolyear	99-2
dc.description.degree	博士
dc.contributor.oralexamcommittee	郭德盛,黃基礎,王亭貴,陳適卿
dc.subject.keyword	慢性頸痛,睡眠,睡眠多頻道生理紀錄,心率變異性,自主神經,腦波,熵,非線性分析方法,複雜度,	zh_TW
dc.subject.keyword	chronic neck pain,sleep,polysomnography,autonomic status,heart rate variability,electroencephalography,non-linear analysis,entropy,complexity,	en
dc.relation.page	111
dc.rights.note	未授權
dc.date.accepted	2011-07-07
dc.contributor.author-college	工學院	zh_TW
dc.contributor.author-dept	醫學工程學研究所	zh_TW
顯示於系所單位：	醫學工程學研究所

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