Dewald, Julius, PT, PhD

Selected Publications

Selected Publications

The effects of wide pulse neuromuscular electrical stimulation on elbow flexion torque in individuals with chronic hemiparetic stroke.
Clair-Auger JM, Collins DF, Dewald JP
Clinical neurophysiology : official journal of the International Federation of Clinical Neurophysiology 2012 Nov; 123(11):2247-55
PMID: 22627022

Neck rotation modulates flexion synergy torques indicating an ipsilateral reticulospinal source for impairment in stroke.
Ellis MD, Drogos J, Carmona C, Keller T, Dewald JP
Journal of neurophysiology 2012 Sep 5; :
PMID: 22956793

Involuntary paretic wrist/finger flexion forces and EMG increase with shoulder abduction load in individuals with chronic stroke.
Miller LC, Dewald JP
Clinical neurophysiology : official journal of the International Federation of Clinical Neurophysiology 2012 Jun; 123(6):1216-25
PMID: 22364723

Effects of body orientation on maximum voluntary arm torques.
Krainak DM, Ellis MD, Bury K, Churchill S, Pavlovics E, Pearson L, Shah M, Dewald JP
Muscle & nerve 2011 Nov; 44(5):805-13
PMID: 22006695

Quantifying loss of independent joint control in acute stroke with a robotic evaluation of reaching workspace.
Ellis MD, Kottink AI, Prange GB, Rietman JS, Buurke JH, Dewald JP
Conference proceedings : … Annual International Conference of the IEEE Engineering in Medicine and Biology Society. IEEE Engineering in Medicine and Biology Society. Conference 2011 Aug; 2011:8231-4
PMID: 22256253



Dewald, Julius, PT, PhD




Office Phone

312-238-2210 / 312-908-6788

Office Fax



Department Chair, Physical Therapy and Human Movement Sciences, Feinberg School of Medicine


645 N. Michigan Ave., Suite 1100 Chicago


Areas of Research

Motor Control, Movement & Rehabilitation, Neurobiology of Disease

NU Scholar Profile

Recent Publications on PubMed

Current Research

Current Research

Quantification of motor impairments following brain injury due to stroke or cerebral palsy and development of neuroscientific models to understand these impairments as well as to develop science-based physical and pharmacological rehabilitation interventions.

As Professor and Chair of Northwestern University’s Department of Physical Therapy and Human Movement Sciences (PTHMS) and Professor in Biomedical Engineering, I have the opportunity to combine neurophysiology and neuropharmacology, imaging and signal analysis techniques, rehabilitation robotics and clinical insights to advance the scientific understanding of pathophysiological mechanisms underlying movement disorders following central nervous system lesions in individuals with stroke and cerebral palsy. My colleagues and I are funded largely through awards from the NIH, the Department of Education (NIDRR) and the American Heart Association (AHA).

Ongoing Projects in the Neuroimaging and Motor Control Laboratories at PTHMS

Our Neuroimaging and Motor Control Laboratories are dedicated to understanding motor recovery following stroke, in learning the role of brain plasticity in recovery, and in developing novel therapeutic training techniques to improve arm function following cerebrovascular accident. Our research is directed towards adults who have had a stroke as well as children with spastic hemiparetic cerebral palsy. While our research efforts are integrative, it can be sectioned and described in the context of Neuroimaging, Impairment Quantification, Neural Machine Interface, Intervention Studies, Device Development, Clinical Outcome Correlations, and Research Registries. The following descriptions summarize each component at use in the Neuroimaging and Motor Control Laboratories.

Neuroimaging: Cortical reorganization following brain injury is being investigated in our laboratories with three techniques: multi-channel EEG recordings in conjunction with anatomical MRI, Transcranial Magnetic Stimulation (TMS) in conjunction with anatomical MRI, functional MRI, and Diffusion Tensor Imaging. Through these investigations, we seek to illustrate the difference in somatotopic organization between normal and injured brains. Significant differences will support the premise that abnormal movement constraints observed in individuals with hemiparesis post stroke or cerebral palsy are due to reorganization of the brain following brain injury.

Neural Machine Interface: A substantial percentage of individuals after stroke are not able to use their paretic hand 6 months following a stroke. Presently, there are no effective therapeutic methods that can successfully restore hand function in moderately to severely impaired individuals with stroke. This population would greatly benefit from a neuroprosthesis as an artificial means to regain hand function. A Neural-Machine-Interface (NMI) together with Neural Electrical Stimulation (NES) can detect user intent and convert the associated neural activity into control commands. Our goal is to design and translate NMI and NES techniques for regaining basic hand function following Stroke.

Impairment Quantification: The recovery process from stroke is characterized by the emergence of stereotypic multi-joint movement patterns that reflect a loss of independent joint control at both the arm and leg. Recent evidence has also suggested discoordination at the level of the trunk. Utilizing quantitative techniques, we aim to elucidate the role of abnormal neural constraints in upper and lower limb and trunk discoordination following hemiparetic stroke.

Intervention Studies: A translational model is implemented in our laboratories such that new findings from the more basic science investigations have been applied to the development of interventions that target the loss of independent joint control. This work began with isometric strengthening interventions and have progressed into dynamic coordination and strengthening interventions utilizing novel science-based robotic devices.

Device Development: Quantifying movement impairment is critical not only to basic investigation of motor control and stroke/Cerebral Palsy recovery but also to precise clinical evaluation and effective treatment. We are currently working on both passive and actively actuated robotic devices for these purposes. While sophisticated and expensive devices dominate our research laboratory, scaled down less expensive yet robust devices are under development for real clinical practice.

Clinical Outcomes Correlations: We are validating our quantitative measures of impairment with clinical assessments across the spectrum of the International Classification of Disease and Functioning (ICF).

Research Registries: We currently operate a national registry for children with cerebral palsy who are interested in participating in clinical research. The registry not only connects families with current research but also allows for outcomes studies of this cohort.