Alma Merians, Ph.D., PT
Professor
Department of Rehabilitation and Movement Sciences
Program: Physical Therapy (DPT)
Administrative Title: Associate Dean
Phone: (973) 972-7820
Email: merians@rutgers.edu
Office location:
65 Bergen Street
Stanley S Bergen, Room 718A
Newark, NJ 07107
About
Alma Merians received her degree in Physical Therapy from Columbia University and did graduate studies at New York University, receiving a Ph.D. in Pathokinesiology. She is Professor and Chairperson of the Department of Rehabilitation and Movement Sciences.
Her areas of teaching include motor control, motor learning and scientific inquiry. Her research focus developed as a result of her clinical physical therapy practice with pediatric and adult clients with neurological deficits. She studies basic mechanisms underlying neuromuscular control of human movement and sensorimotor learning and utilizes technology-assisted rehabilitation to re-train people with neurological diseases like stroke or cerebral palsy.
She and her collaborators at NJIT have developed robotics and virtual reality gaming simulations to be used in the rehabilitation of hand and arm function after stroke. They completed a 4 year RO1 grant from NIH to test this type of intervention in patients in the chronic phase post-stroke and have recently been funded to run a clinical study to further test the system in the acute phase post-stroke.
Education
B.S., Columbia University
Ph.D., PT, New York University
Professional Achievements
Best Paper at ICDVRAT Conference in Vina del Mar, Chile 2010
Best Paper at IEEE/ICME Proceedings International Conference on Complex Medical Engineering, Beijing, China 2007
Outstanding Service Award -New Jersey American Physical Therapy Association, 1995
Foundation of UMDNJ Excellence in Teaching Award, 1987
Research
The main focus of my work is to study basic mechanisms underlying neuromuscular control of human movement and sensorimotor learning and to utilize technology-assisted rehabilitation to re-train people with neurological diseases like stroke or cerebral palsy.
We were one of the pioneering groups to use interactive, adaptive robotics and virtual reality simulations for hand training in people with hemiplegia post-stroke. We have developed a library of 16 simulations that integrate adaptive, haptic robotics with complex, immersive three-dimensional externally paced gaming activities that use adaptive algorithms, activity scaling, haptic and visual effects to accommodat¬¬e to the wide range of impairments seen post-stroke and target specific skill re-acquisition.
Description of Current Projects
We are currently recruiting subjects for two projects. 1. Hand and upper arm rehabilitation in the acute phase post-stroke using interactive virtual environments 2. Home-based therapy for the upper extremity post-stroke using interactive virtual reality simulations.
Current Projects: We are currently recruiting subjects for two projects. 1. Hand and upper arm rehabilitation in the acute phase post-stroke using interactive virtual environments 2. Home-based therapy for the upper extremity post-stroke using interactive virtual reality simulations.
Title |
Sponsor |
Effective Dates |
Role |
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Optimizing Hand Rehabilitation Post-Stroke Using Interactive Virtual Environments |
Rutgers University, NJIT, Kessler Rehabilitation, Northeastern University |
09/01/2017-5/31/2022 |
PI | |||
Optimizing Hand Rehabilitation Post-Stroke Using Interactive Virtual Environments |
NIH |
03/05/2013 – 02/28/2014 |
Co-Investigator | |||
Virtual reality rehabilitation of hand use after stroke. The major goal of this project was to investigate how post- stroke patients reach to and grasp real-world objects with their hemiplegic hand before and after virtual reality rehabilitation training. |
NIH |
3/2009 – 2/2013 |
Co-Investigator | |||
The Role of Feedback for Enhancing Motor Skill Learning in Geriatric Neurologically Impaired Populations |
University of Medicine and Dentistry Foundation |
1992 |
PI | |||
DDSA-N.J. Division of Mental Retardation and Developmental Disabilities |
Special Child Health Services Grant, N.J. Dept. of Health |
1980 – 1981 & 1981 – 1982 |
PI |
Publications
| Title | Authors | Where and When | ||
Participant Adherence to a Video Game-Based Tele-rehabilitation Program: A Mixed-Methods Case Series |
Fluet GG, Qiu Q, Cronce A, Sia E, Blessing K, Patel J, Merians A, Wohn DY, Adamovich S |
Virtual Reality in Health and Rehabilitation. 1st edition.; 2021. Chapter 13; p.169-181. |
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Virtual Rehabilitation of the Paretic Hand and Arm in Persons With Stroke: Translation From Laboratory to Rehabilitation Centers and the Patient’s Home |
Fluet G, Qiu Q, Patel J, Mont A, Cronce A, Yarossi M, Merians A, Adamovich S |
Front Neurol. 2021;12:623261. eCollection |
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Virtual Rehabilitation of the Paretic Hand and Arm in Persons With Stroke: Translation From Laboratory to Rehabilitation Centers and the Patient’s Home. |
Fluet G, Qiu Q, Patel J, Mont A, Cronce A, Yarossi M, Merians A, Adamovich S. |
Front Neurol. 2021;12:62326 |
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Development of the Home based Virtual Rehabilitation System (HoVRS) to remotely deliver an intense and customized upper extremity training. |
Qiu Q, Cronce A, Patel J, Fluet GG, Mont AJ, Merians AS, Adamovich SV |
Neuroeng Rehabil. 2020 Nov 23;17(1):155 |
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Hand Focused Upper Extremity Rehabilitation in the Subacute Phase Post-stroke Using Interactive Virtual Environments |
Merians AS, Fluet GG, Qiu Q, Yarossi M, Patel J, Mont AJ, Saleh S, Nolan KJ, Barrett AM, Tunik E, Adamovich SV |
Front Neurol. 2020;11:573642 |
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Autonomous use of the Home Virtual Rehabilitation System (HoVRS): a feasibility and pilot study |
Fluet GG, Qiu Q, Cronce, A, Patel J, Adamovich S, Merians A. |
Games Health J. 2019 Dec;8(6):432-438 |
||
Intensive virtual reality and robotic based upper limb training compared to usual care, and associated cortical reorganization, in the acute and early sub-acute periods post-stroke: a feasibility study |
Patel J, Fluet G, Qiu Q, Yarossi M, Merians A, Tunik E, Adamovich S |
. J Neuroeng Rehabil. 2019 Jul 17;16(1):92 |
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The Association Between Reorganization of Bilateral M1 Topography and Function in Response to Early and Intensive Hand Focused Upper Limb Rehabilitation on Ipsilesional Corticospinal Tract Integrity |
Yarossi, M and Patel, J, Qiu, Q, Massood, S, Fluet, G, Merians, A, Adamovich, S and Tunik, E. |
Front Neurol, 10:258, Mar 2019 |
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Neural Patterns of Reorganization after Intensive Robot-Assisted Virtual Reality Therapy and Repetitive Task Practice in Patients with Chronic Stroke. |
Saleh S, Fluet GG, Qiu Q, Merians A, Adamovich SV, Tunik E. |
Front.Neuro, 04 2017 |
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Motor skill changes and neurophysiologic adaptation to recovery-oriented virtual rehabilitation of hand function in a person with subacute stroke: a case study |
Fluet G, Patel J, Merians A, Qiu Q, Yarossi M, Adamovich S, Tunik E, Massood S. |
Disability and Rehabilitation. 2017; 39 (15):1524-1531 |
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Virtual reality-augmented rehabilitation in the acute phase post-stroke for individuals with flaccid upper extremities: A feasibility study |
Patel J, , Merians A, Qiu Q, Yarossi M, Adamovich S, Tunik E, Massood S, Fluet G. |
Disability and Rehabilitation. 2017; 39(15):1515-1523 |
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Does training with traditionally presented and virtually simulated tasks elicit differing changes in object interaction kinematics in persons with upper extremity hemiparesis? |
Fluet G, Merians A, Qiu Q; Rohafaza M, VanWingerden A, Adamovich S |
Topics in Stroke Rehabilitation; 2015, 22(3);176-84 |
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Comparing integrated training of the hand and arm with isolated training of the same effectors in persons with stroke using haptically rendered virtual environments, a randomized clinical trial |
Fluet G, Merians AS, Qiu, Q, Davidow A, Adamovich SV |
J Neuroeng Rehab, 2014, 11(1):126 |
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Virtual reality-augmented rehabilitation for patient in sub-acute phase post-stroke: a feasibility study |
G G Fluet, A Merians, J Patel, A Van Wingerden, Q Qiu, M Yarossi, E Tunik, S Adamovich, S Massood |
In Sharkey, P., Pareto, L., Broeren, J. and Rydmark, M., eds. (2014) Proceedings 10th International Conference on Disability, Virtual Reality and Associated Technologies (ICDVRAT) 2014. University of Reading, Reading, UK, pp480. ISBN 0704915467 |
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Customized motor training for a person with upper extremity hemiparesis, using robots integrated with virtual reality simulations; a case report |
Fluet G.G., Qiu, Q., Merians A.S., Saleh S., Lafond I., Ruano V, Delmonico A.R., Adamovich S.V. |
JNPT 2012;36:79-86 |
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Customized motor training for a person with upper extremity hemiparesis, using robots integrated with virtual reality simulations; a case report |
Fluet G.G., Qiu, Q., Merians A.S., Saleh S., Lafond I., Ruano V, Delmonico A.R., Adamovich S.V. |
Journal of Neurologic Physical Therapy 13:335-345, 2012 |
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Rehabilitation Applications using Virtual Reality for Persons with Residual Impairments following Stroke. In Virtual Reality Technologies for Health and Clinical Applications |
Merians AS & Fluet G |
(Series editor: P. Sharkey): Vol. 1: Applying Virtual Reality Technologies to Motor Rehabilitation, P.L. Weiss, E.A. Keshner, M.F. Levin (Eds), Springer, 2013 |
||
Customized motor training for a person with upper extremity hemiparesis, using robots integrated with virtual reality simulations; a case report |
Fluet G.G., Qiu, Q., Merians A.S., Saleh S., Lafond I., Ruano V, Delmonico A.R., Adamovich S.V. |
Journal of Neurologic Physical Therapy 13:335-345, 2012 |
||
Robotically Facilitated Virtual Rehabilitation of Arm Transport Integrated With Finger Movement in Persons with Hemiparesis |
Merians AS, Fluet GG, Qiu Q, Saleh S, Lafond I, Davidowm A, Adamovich SV |
Journal of NeuroEngineering and Rehabilitation 2011, 8:27 (16 May 2011) |
| Title | Authors | Where and When | ||
Learning in a virtual Eevironment using haptic systems for movement re-education: can this medium be used for remodeling other behaviors and actions |
Merians AS, Fluet GG, Qui Q, Saleh S, LaFond I. Davidow A, Adamovich SV |
J Diabetes and Science Technology, 2011, 5(2) |
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Robotically facilitated virtual rehabilitation of arm transport integrated with finger movement in persons with hemiplegia |
Merians AS, Fluet GG, Qui Q, Saleh S, LaFond I. Davidow A, Adamovich SV |
Journal of NeuroEngineering and Rehabilitation 2011, 8:27 (16 May 2011) |
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A Virtual Reality-Based System Integrated with fMRI to Study Neural Mechanisms Underlying Rehabilitation: A Proof of Concept Study |
Adamovich S, August K, Merians A and Tunik E |
Restorative Neurology and Neuroscience 2009;27(3):209-23 |
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Sensorimotor training in virtual reality: a review |
Adamovich SV, Fluet GG, Tunik E, Merians AS |
NeuroRehabilitation. 2009;25(1):29-44.PMCID:PMC2819065 |
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Virtual Reality to maximize function for hand and arm rehabilitation: Exploration of neural mechanisms |
Merians A, Tunik E, Sergei V. Adamovich |
Studies in Health Technology and Informatics 145, 2009 |
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Innovative Approaches to Rehabilitation of Upper Extremity Hemiparesis Using Virtual Environments |
Merians AS, Tunik E, Fluet G, Qui Q, Adamovich S |
Eur J Phys Rehabil Med. 2009;45;123-33 |
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Semsorimotor Training in a Virtual Reality Environment: Does it Improve Functional Recovery Post-Stroke? |
Merians AS, Poizner HP, Boian R, Burdea G, Adamovich SV. |
Neural Rehabilitation Neural Repair. Vol. 20 (2): (2006 ) |
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Incorporating Haptic Effects Into Three-Dimensional Virtual Environments To Train The Hemiparetic Upper Extremity |
Adamovich, S, Fluet G, Merians AS, Mathai A, Qinyin Q |
IEEE Trans Neural Syst Rehabil Eng. 2009 Oct;17(5):512-20. Epub 2009 Aug 7. PMC |
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Coordination changes demonstrated by subjects with hemiparesis performing hand-arm training using the NJIT-RAVR robotically assisted virtual rehabilitation system |
Qiu Q, Fluet GG, Lafond I, Merians AS, Adamovich SV |
Conf Proc IEEE Eng Med Biol Soc. 2009;1:11436. PMCID:PMC2819135 |
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“Recovery of Hand Function in Virtual Reality: Training Hemiparetic Hand and Arm Together or Separately,” |
S. Adamovich, G. G. Fluet, A. S. Merians, A. Mathai, and Q. Qiu |
in Proc. 28th EMBC Annu. Int. Conf. Eng. Medicine Biol. Soc., Vancouver, Canada, August 2008, 3475-3478 |
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Strategies for Incorporating Bilateral Training into a Virtual Environment |
Merians AS, Lewis J, Qinyin Q, Fluet, G, Talati B and Adamovich S |
IEEE/ICME Proceedings International Conference on Complex Medical Engineering, May, 2007, Beijing, China |
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Design of a Virtual Reality-Based System For Hand and Arm Rehabilitation |
Adamovich S., Qinyin Q, Talati B. Fluet G and Merians AS |
Proceedings IEEE International Conference on Rehabilitation Robotics, Netherlands 2007 |
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fMRI Analysis of Neural Mechanisms Underlying Rehabilitation in Virtual Reality: Activating Secondary Motor Areas |
August K, Lewis JA, Chandar G, Merians A, Biswal B, Adamovich S. |
Proceedings, IEEE EMBS, August 2006, p. 285. |
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Design of an fMRI Compatible System to Explore Neural Mechanisms Subserving VR Therapies |
Jeffrey A. Lewis, K. August, Alma Merians, Bharat Biswal, Sergei Adamovich |
Proceedings of IWVR 2006, August 2006 |
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A virtual reality (VR)-based exercise system for hand rehabilitation after stroke Presence |
Adamovich S. V., Merians AS., Boian R., Tremaine M., Burdea G. C., Recce M. and Poizner H |
2005;14;161-174 |
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An Innovative Approach to the Rehabilitation of Hand Function Post-Stroke |
Adamovich S.V., Merians A.S., Boian R, Burdea G.S., Poizner H |
Proceedings of the 17th Annual International Conference on Technological Innovations in Disability, Garches Institute, B. Bussel, editor, Paris, France, 2004, pp. 252-262 |
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(2004) Development and Application of Virtual Reality Technology to Improve Hand Use and Gait of Individuals Post-Stroke |
Deutsch, JE. Merians, AS. Adamovich, H. Poizner, and G. Burdea |
Restorative Neurology and Neuroscience, Special issue on motor system plasticity, recovery and rehabilitation, Vol. 22(3-5), pp. 341-386 |
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A Virtual Reality (VR)-based exercise system for hand rehabilitation after stroke |
Adamovich S. V., Merians AS., Boian R., Tremaine M., Burdea G. C., Recce M. and Poizner H |
Proc. 2nd Int. Workshop on Virtual Rehabilitation, Piscataway, NJ, 2003 |
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Virtual Reality-Augmented Rehabilitation for Patients Post Stroke: Three Case Studies |
Merians AS, Jack D., Boian R., Tremaine M., Burdea G.C Adamovich S., Recce M., and Poizner, H |
Physical Therapy 2002, 82:898-915 |
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2002 Haptics and Virtual Reality Used to Increase Strength and Improve Function in Chronic Patients Post-stroke: Two Case Reports |
Deutsch JE, Merians AS, Burdea G, Boian R, Adamovich S. Poinzer H |
Neurology Report 2002;26:2:78-85 |
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2002 Haptics and Virtual Reality Used to Increase Strength and Improve Function in Chronic Patients Post-stroke: Two Case Reports |
Deutsch JE, Merians AS, Burdea G, Boian R, Adamovich S. Poinzer H |
Neurology Report 2002;26:2:78-85 |
||
2002 Haptics and Virtual Reality Used to Increase Strength and Improve Function in Chronic Patients Post-stroke: Two Case Reports |
Deutsch JE, Merians AS, Burdea G, Boian R, Adamovich S. Poinzer H |
Neurology Report 2002;26:2:78-85 |
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Virtual Reality-Based Post Stroke Rehabilitation |
Boian R., Sharma A., Han C., Merians A., Burdea G., Adamovich S., Recce M., Tremaine M., and Poizner H. |
Proceedings of Medicine Meets Virtual Reality Conference 2002 Conference, Newport Beach, CA. January 23-26 2002 IOS Press, 64-70 |
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Virtual Reality-Based Stroke Rehabilitation |
Jack D., Boian R., Merians A., Tremaine M., Burdea G.C., Senior Member,IEEE, Adamovich S., Recce M. and Poizner H |
IEEE Transactions on Neural Systems and Rehabilitation Engineering, 9, (308-318) 2001 |
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A Virtual Reality-Based Exercise Program For Stroke Rehabilitation |
Jack D., Boian R., Merians A., Adamovich S.,Tremaine M., Recce M., Burdea G.C. and Poizner H |
ASSETS 2000: Fourth ACM SIGCAPH Conference on Assistive Technologies, Arlington Virginia, November, 2000 |
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Motor Learning after Unilateral Brain Damage |
Winstein C J, Merians A S, Sullivan K J |
Neuropsychologia (1999) 37, 975-987 |
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Virtual reality to maximize function for hand and arm rehabilitation: exploration of neural mechanisms |
Merians A., Tunik E and. Adamovich S |
Innovations in Rehabilitation Technology; Israel |
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Technological Applications to the Study of Limb Apraxia in Apraxia |
Poizner H, Merians A, Clark M A, Rothi L, Heilman K |
Rothi L & Heilman K eds. Lawrence Erlbaum Associates. (1997) |
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Rutgers, The State University of New Jersey, an equal opportunity, affirmative action institution. All rights reserved.
Rutgers is an equal access/equal opportunity institution. Individuals with disabilities are encouraged to direct suggestions, comments, or complaints concerning any accessibility issues with Rutgers web sites to: accessibility@rutgers.edu or complete the Report Accessibility Barrier or Provide Feedback Form.