Publications
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Author Title Type [ Year
Filters: Author is Dimitrijevic, Milan R [Clear All Filters]
Effect of functional electrical stimulation on the central state of excitability of the spinal cord.
(Long, M., Ed.).World Congress for Medical Physics and Biomedical Engineering. 39, 2240-2243.
Preprint (210.32 KB)
(2012). 
The Human Lumbar Cord Circuitry Disconnected from the Brain Can Generate a Variety of Motor Outputs in Response to Non-Patterned Spinal Cord Stimulation at Different Frequencies.
Cellular and Network functions in the Spinal Cord. 13.
Poster (4.5 MB)
(2012). 
Modification of posterior root-muscle reflexes by volitional motor tasks.
Society for Neuroscience Abstract Viewer and Itinerary Planner. 42, 890.01/LL9.
Poster (2.08 MB)
(2012). 
Non-invasive transcutaneous stimulation of the human lumbar spinal cord facilitates locomotor output in spinal cord injury..
Biomed Tech (Berl).
(2012). Spasticity: Pathophysiology and Neural Control.
(Kusumastuti, P., & Tular A. B. M., Ed.).3rd Asia-Oceanian Conference of Physical and Rehabilitation Medicine in Conjunction with XI Annual Scientific of Indonesian Association of Physical Medicine and Rehabilitation. 9-15.
Preprint (188.18 KB)
(2012). 
Human lumbar cord can process spinal cord stimulation of different frequencies.
Neuroscience 2011. Meeting Planner Program Nr. 182.06,
Poster (3.07 MB)
(2011). 
Transcutaneous Lumbar Posterior Root Stimulation for Motor Control Studies and Modification of Motor Activity after Spinal Cord Injury.
(Dimitrijevic, M. R., Kakulas B. A., McKay B. W., & Vrbova G., Ed.).Restorative Neurology of Spinal Cord Injury. 226-255.
(2011). Neural control of human posture and movement: Modifcations of monosynaptic lumbosacral posterior root-muscle re exes.
(Mandl, T., Martinek J., Bijak M., Lanmueller H., Mayr W., & Pichler M., Ed.).15th Annual Conference of the International Functional Electrical Stimulation Society. 074.
(2010). Stimulation of the human lumbar spinal cord with implanted and surface electrodes: a computer simulation study.
IEEE Trans Neural Syst Rehabil Eng. 18(6), 637-45.
(2010). Transcutaneous stimulation of the human lumbar spinal cord: Facilitating locomotor output in spinal cord injury.
Neuroscience 2010. Abstract Viewer/Itinerary Planner No. 286.19.,
Poster (746.26 KB)
(2010). 
Modification of reflex responses to lumbar posterior root stimulation by motor tasks in healthy subjects.
Artif Organs. 32(8), 644-8.
Post-print (183.97 KB)
(2008). 
Posterior root-muscle reflexes elicited by transcutaneous stimulation of the human lumbosacral cord.
Muscle Nerve. 35(3), 327-36.
(2007). Effect of peripheral afferent and central afferent input to the human lumbar spinal cord isolated from brain control.
Biocybernetics and Biomed. Eng. 25, 11-19.
(2005). Electrophysiological characteristics of H-reflexes elicited by percutaneous stimulation of the cauda equina.
Neuroscience. Program No. 411.17. 2004 Neuroscience Meeting Planner,
Poster (927.38 KB)
(2004). 
Frequency-dependent selection of alternative spinal pathways with common periodic sensory input..
Biol Cybern. 91(6), 359-76.
(2004). Evidence for a Spinal Central Pattern Generator in Humansa.
Annals of the New York Academy of Sciences. 860(1 NEURONAL MECH), 360 - 376.
(1998).