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High resolution ultrasonic monitoring of muscle dynamics and novel approach to modelling

The presented work is concerned with the development and application of an ultrasonic detection scheme suitable for the monitoring of muscle dynamics with high temporal - down to 5 µs - and spatial resolution - down to 0.78 µm. A differential detection scheme has been developed to monitor the variations of the velocity of longitudinal polarized ultrasound waves travelling in contracting and relaxing muscle, compensating for variations of the path length by referencing to a frame. The observed time dependent variations of the time-of-flight of the ultrasonic waves caused by variations in the muscle and in addition by minor deformations of the enclosure are detected each separately and synchronously and are evaluated differentially. Beside of the detected increase of the speed of sound observed for contracted muscle with respect to the relaxed state of about 0.6%, the recovery time from maximum isometric contraction is quantified and relaxation processes are observed for the recovery phase following the isometric contraction. The developed ultrasonic calliper was employed to monitor both, the brain controlled and externally excited muscle dynamics with sampling intervals down to 10 ms synchronously with signals relating to the excitation. Monitored are the activation, hold, and relaxation phase for maximum voluntary isometric contraction of the gastrocnemius muscle. A so far not reported post tetanus overshoot and subsequent exponential recovery are observed. Both are attributed to the muscle as suggested by combined monitoring with EMG and are modelled with a lumped mechanical circuit containing an idealized bidirectional linear motor unit, ratchet, damper, and springs. Both, the rapid contraction and relaxation phases require a high order filter or alternatively a kernel filter, attributed to the nerve system as suggested by external electric stimulation. The respective response function is modelled by an electrical lumped circuit. Together with a reaction time and occasionally observed droops in the hold phase, both adjusted empirically, the monitored response is represented in close approximation by the combined electrical and mechanical lumped circuits. The respectively determined model parameters provide a refined evaluation scheme for the performance of monitored athletes. Valuable parameters relate to the latent period, the muscle response time, the activation and deactivation dynamics, a possible droop and other instabilities of the hold phase, and parameters characterizing the relaxation phase including the observed post tetanus overshoot and subsequent contraction. Monitored and modelled are also the different processes involved in active muscle dynamics including isotonic, isometric, and eccentric contraction or stretching. The developed technology provides time sequential observation of these processes and registration of their path in the extension and force parameter space. Under suitable conditions the closed-loop cycles of mind controlled human muscle movements proceed along characteristic lines coinciding with well identifiable elementary processes. The presentation of the monitored processes in the extension and force parameter space allows the determination of the mechanical energy expenditure for the observed different muscle actions. An elementary macroscopic mechanical model has been developed, suitable to express the basic features of the monitored muscle dynamics.:Table of Contents
Chapter 1
1. Introduction 1
1.1 Monitoring of muscle biomechanics 1
1.2 Detection methods in biomechanics 2
1.3 Ultrasound in biomechanical application 5
1.4 Skeletal muscle 6
1.5 Activation of skeletal muscle 8
1.6 Catatonus effect 10

Chapter 2
2. Concepts and methods in ultrasonic motion monitoring 12
2.1 Ultrasound 12
2.2 Specific concepts of the developed ultrasonic detection scheme 16
2.2.1 Time-of-flight 17
2.2.2 Cross correlation 18
2.2.3 Concepts of cross correlation 19
2.2.4 Chirp technique 19

Chapter 3
3. Ultrasonic monitoring of the muscle extension 21
3.1 Data analysis 21
3.2 Application of the developed monitoring scheme 23
3.2.1 Fast signal and data acquisition mode 23
3.2.2 Monitoring with off-line evaluation 24
3.2.3 Method 26
3.2.4 Data evaluation 27
3.3 Quasi-continuous monitoring scheme 28
3.3.1 Slow with on-line data processing and display 29
3.3.2 Fast with data storage only 30
3.4 Monitoring with on-line evaluation 34
3.4.1 Application involving monitoring of athletic performance 36
3.4.2 Data evaluation 37
3.4.3 Summary 42
3.5 Comparative study of pre and post physical loading session 43
3.5.1 Method 43
3.5.2 Results 44
3.5.3 Summary 45

Chapter 4
4. High resolution monitoring of the velocity of ultrasound in contracting
and relaxing muscle 47
4.1 Methods 49
4.2 Results and evaluation 51
4.2.1 Poission’s ratio for isometrically contracted muscle 52
4.3 Summary 53

Chapter 5
5. Monitoring of muscle dynamics, muscle force, and EMG 56
5.1 Synchronous monitoring of muscle dynamics with muscle force 56
5.1.1 Force-length dynamics under all-out isometric contraction 56
5.1.1.1 Method 56
5.1.1.2 Result and evaluation 58
5.1.2 Force-length dynamics of equal holding monitoring 62
5.1.2.1 Method 62
5.1.2.2 Results and evaluation 63
5.1.3 Summary 67
5.2 Synchronous monitoring of muscle movement with EMG 69
5.2.1 Method 69
5.2.2 Results and evaluation 70
5.3 Synchronous monitoring of muscle movement, EMG and muscle force 73
5.3.1 Method 73
5.3.2 Results and evaluation 74
5.3.3 Summary 77
Chapter 6
6. Monitoring of skeletal muscle dynamics under isometric contraction and
modelling of the non-linear response including post tetanus effects 80
6.1 Method 82
6.2 Data analysis 82
6.3 Results and evaluation 82
6.3.1 Mechanical model 83
6.3.2 Equations relating to modelling 85
6.3.3 Comparison of experimental results and modelling 91
6.3.4 Electrical lumped circuit 93
6.4 Summary 100
Chapter 7
7. Lumped Circuit Model and Energy Transfer for quasi-static approximation 101
7.1 Basic muscle model and biomechanical processes 102
7.1.1 Muscle model 102
7.1.2 Force in the muscular motoric processes 104
7.2 Method 104
7.3 Results of experimental observations of muscle action 106
7.3.1 Muscle force and closed-loop contraction dynamics 106
7.3.2 Muscle work considerations 109
7.4 Summary 110
Chapter 8
8.1 Ultrasonic calliper 112
8.2 Interpretation of sound velocity variation in muscle 114
8.3 Monitored muscle dynamics 118
8.4 Isometric muscle action and tetanus effect 121
8.5 Quasi-static muscle action 125
8.6 Summarizing statement with a moderate outlook 126
References 128
Acknowledgements 140
Selbständigkeitserklärung 141

Identiferoai:union.ndltd.org:DRESDEN/oai:qucosa:de:qucosa:11817
Date23 November 2012
CreatorsMuhammad, Zakir Hossain
ContributorsWolfgang, Grill, Manfred, Radmacher, Josef, Käs, Marius, Grundmann, Jürgen, Haase, Friedrich, Kremer, Maren, Witt, Universität Leipzig
Source SetsHochschulschriftenserver (HSSS) der SLUB Dresden
LanguageEnglish
Detected LanguageEnglish
Typedoc-type:doctoralThesis, info:eu-repo/semantics/doctoralThesis, doc-type:Text
Rightsinfo:eu-repo/semantics/openAccess

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