Chapter 1: Wearable and wireless systems for movement disorder evaluation and deep brain stimulation systems

1.1 Introduction

1.2.1 Perspective of Chapter 2:

     Movement disorders: Parkinson’s disease and Essential tremor, a general perspective

1.2.2 Perspective of Chapter 3:

     Traditional ordinal strategies for establishing the severity and status of movement disorders, such as Parkinson's disease and Essential tremor

     Deep brain stimulation for the treatment of movement disorder regarding Parkinson's disease and Essential tremor with device characterization

     Surgical procedure for deep brain stimulation implantation and operative phase with post-operative risks

1.2.5 Perspective of Chapter 6:

1.2.6 Perspective of Chapter 7:

1.2.7 Perspective of Chapter 8:

1.2.8 Perspective of Chapter 9:

     Assessment of machine learning classification strategies for the differentiation of deep brain stimulation ‘On’ and ‘Off’ status for Parkinson’s disease

1.2.9 Perspective of Chapter 10:

     New perspectives for Network Centric Therapy for the treatment of Parkinson's disease and Essential tremor

References

Chapter 2: Movement disorders: Parkinson’s disease and Essential tremor, a general perspective

2.1 Introduction

2.2 Parkinson's disease

2.3 Essential tremor

2.4 Traditional strategies for assessing progression and treatment of Parkinson's disease and Essential tremor

2.5 Advanced strategies for assessing progression and treatment of Parkinson's disease and Essential tremor

2.6 Extrapolation to Network Centric Therapy

2.7 Conclusion

References

3.1 Introduction

3.2 Clinical assessment of Parkinson's disease

3.3 Clinical assessment of Essential tremor

3.4 Wearable and wireless systems for the quantification of movement disorder tremor

3.5 Extrapolation to Network Centric Therapy

3.6 Conclusion

References

Chapter 4: Deep brain stimulation for the treatment of movement disorder regarding Parkinson's disease and Essential tremor with device characterization

4.2 The foundations of deep brain stimulation

4.4 Benefit and risk consideration of deep brain stimulation

4.5 Target selection for deep brain stimulation

4.5.1 Essential tremor

4.5.2 Parkinson's disease

4.6 Deep brain stimulation system device description

4.6.1 Electrode leads and the implantable pulse generator

4.6.2 Battery

4.6.3 Electrical signal

4.7 Deep brain stimulation system programmer

4.8 Attaining the optimal parameter configuration for deep brain stimulation an issue with tuning

4.9 Future perspectives for deep brain stimulation

4.10 Conclusion

References

Chapter 5: Surgical procedure for deep brain stimulation implantation and operative phase with post-operative risks

5.2 General surgical perspective and considerations for the application of deep brain stimulation

5.3 Deep brain stimulation operative risks and complications

5.4 Post-operative risk regarding energy interaction

5.5 Adverse neurological and neuropsychological effects for deep brain stimulation

5.6 Operative technique advocated by Allegheny General Hospital

5.7 Applied deep brain stimulation programming from by Allegheny General Hospital

5.8 Conclusion

References

6.1 Introduction

6.3 Wireless accelerometer feedback for optimal tuning of deep brain stimulation parameter settings, a conceptual perspective

6.5 Evolution of wearable and wireless systems, from local wireless connectivity to Internet connectivity

References

Chapter 7: Wearable and wireless systems with Internet connectivity for quantification of Parkinson's disease and Essential tremor characteristics

7.1 Introduction

7.2 Smartphone for quantifying Parkinson's disease hand tremor

7.3 Smartphone for quantification of Essential tremor regarding deep brain stimulation in ‘On’ and ‘Off’ mode

7.4 Smartwatches, Bluetooth wireless connectivity, and other wearable and wireless systems for the quantification of movement disorder status

7.5 Network Centric Therapy

7.6 Conclusion

References

Chapter 8: Role of machine learning for classification of movement disorder and deep brain stimulation status

8.1 Introduction

8.2 Waikato Environment for Knowledge Analysis (WEKA) for machine learning classification of movement disorder ameliorated through deep brain stimulation using wearable and wireless systems for quantified feedback

8.2.1 J48 decision tree

8.2.2 K-nearest neighbors

8.2.3 Logistic regression

8.2.4 Support vector machine

8.2.5 Multilayer perceptron neural network

8.2.6 Random forest

8.2.7 Attribute-Relation File Format (ARFF)

8.3 The role of machine learning for Network Centric Therapy

8.4 Conclusion

References

9.1 Introduction

9.2 Background

9.3 Method and materials

9.4 Results and discussion

9.5 Network Centric Therapy integrating wearable and wireless systems as quantified feedback for deep brain stimulation using machine learning classification

References

Dr. Robert LeMoyne is currently serving as an Adjunct Professor for Northern Arizona University for the Department of Biological Sciences and Center for Bioengineering Innovation. At Northern Arizona University he is researching advanced technology concepts for wearable and wireless systems for biomedical applications. He earned his PhD in Biomedical Engineering from University of California Los Angeles (UCLA) during 2010. From 2010 to 2012 he served Sandia National Laboratories, and since 2013 he has been serving Northern Arizona University. Dr. LeMoyne has first authored over 100 technical proceedings that have been cited over 1000 times. From a biomedical engineering perspective his research interests emphasize deep brain stimulation systems, prosthetic technologies, machine learning applications, and wearable and wireless systems for biomedical applications, such as through smartphones and portable media devices, for accessing health status, such as Parkinson’s disease and Essential tremor.

Timothy Mastroianni is a Cognitive Scientist, Researcher, Entrepreneur. First to develop and use computer vision and pattern recognition in a non-invasive manner to discover the internal states of the random number generator in machines (HiLoClient). Later presented these algorithms and methods to Carnegie Mellon University to map the human brain using machine learning and fMRI to discover brain states during specific tasks.

Nestor D. Tomycz MD was born and raised in Flint, MI.  He graduated from Harvard College summa cum laude in chemistry in 2001 and earned his MD from Harvard Medical School in 2005.  His general surgery internship and neurosurgery residency were completed at the University of Pittsburgh Medical Center and he completed a fellowship in functional and stereotactic neurosurgery at Allegheny General Hospital under Dr. Donald Whiting.  He is currently director of stereotactic/functional neurosurgery and director of neurosurgical pain division at Allegheny General Hospital.  His research interests include deep brain stimulation, spinal cord stimulation, chronic pain, and neurodegenerative disorders. 

In 1992, Donald Whiting joined a practice in Washington, PA that would later merge with the health system now known as Allegheny Health Network. He became the System Chair for their Neuroscience Institute and a Professor of Neurosurgery for Drexel University in 2014. Three years later, he also accepted the role of President of Allegheny Clinic. Amongst his peers, Donald Whiting is a respected physician-leader that is passionate about changing the way health care is delivered.

Donald has authored over 60 scientific articles and chapters in medical textbooks and various publications such as The Journal of Neurosurgery & Current Concepts in Movement Disorder Management. He is an active member in many of his field’s leading professional and scientific organizations, including the Congress of Neurological Surgeons, the American Association of Neurological Surgeons, and the American Society of Stereotactic and Functional Neurosurgery.

It’s no wonder Donald Whiting has been the annual recipient of “Top Doctor/Surgeon” awards on both local & national levels. He is regarded as one of the nation’s foremost experts in the use of deep-brain stimulation to control the debilitating motor symptoms of patients with Parkinson’s disease and other movement disorders, helping establish Allegheny General Hospital in Pittsburgh, Pennsylvania as one of the top centers in the world for DBS treatment. His sub-specialties include complex spine surgery, disc replacement/motion preservation spine surgery, the surgical treatment of movement disorders & Neurosurgical management of pain.

This book provides a far-sighted perspective on the role of wearable and wireless systems for movement disorder evaluation, such as Parkinson’s disease and Essential tremor. These observations are brought together in the application of quantified feedback for deep brain stimulation systems using the wireless accelerometer and gyroscope of a smartphone to determine tuning efficacy. The perspective of the book ranges from the pioneering application of these devices, such as the smartphone, for quantifying Parkinson’s disease and Essential tremor characteristics, to the current state of the art. Dr. LeMoyne has published multiple first-of-their-kind applications using smartphones to quantify movement disorder, with associated extrapolation to portable media devices.