Non-Invasive Spinal Electrical Stimulation 

NISE-Stim Certification Part1

by Gerti Motavalli, MPT

Target Audience: Physical Therapists (PTs), Physical Therapy Assistants (PTAs), Occupational Therapists (OTs)

Presented by: Gerti Motavalli, MPT
Date: Friday April 17, 2026
Time: 8:00 a.m.-6:00 p.m. (9, hours)

Date: Saturday April 18, 2026
Time: 7:30 a.m. – 3:30 p.m. (7 hours)

Course Location: RISE Pediatric Therapy
4554 E Inverness Ave
C-1
Mesa, AZ 85206

Sponsor: Adaptive Movements Pediatric Therapy

Course Coordinator: Denise Labriola-Berry, PT, DPT, ATACP, CME II

Email: denisegetsampt@gmail.com

Cell: 480-223-7736

Cost:

Early Bird Discount until March 17, 2026     $660
Group Discount (3+)                                 $660
Regular after March 17, 2026                    $690
Registration: Through this Jotform

CEUs: 16 contact hours, 

 

This course is approved for 16 hours by APTA Arkansas, California, Florida (# 50-54090), TPTA Texas

Courses approved by other state boards in the following jurisdictions are likely accepted for licensure credit based on the state regulation:

AL | AK | AR | CO | CT | DE | GA | HI | ID | IN | IA | KS | KY | ME | MA | MI | MO | MT | NE | NH | NC | ND | OR | PA | RI | SC | SD | UT | VT | VA | VI | WA | WI | WY

Courses approved by other APTA chapters in the following jurisdictions are likely accepted for licensure credit based on the state regulation:

AZ | DC | MD | MS | NM

Please reach out to your state licensing board to confirm the currency and accuracy of this information. If you have a specific question about CEU approval for this course in your state, please direct your inquiry to info@ceuapproval.com.

The following states are not pre-approved:  IL, LA, MN, NV, NY, NJ, OH, OK, TN, WV

Participants licensed in states not pre-approved may file for individual approval using the instructions on this document.

                                            

Course Description:

This specialized course is designed for physical therapists and clinicians seeking the most advanced applications of Non-Invasive Spinal Electrical Stimulation (NISE-Stim) to enhance clinical outcomes in children with:

Spina bifida
Hypotonia
Spinal cord injuries
Brachial plexus paralysis
Cerebral palsy (CP)
Other neuromotor impairments

Course Highlights:
✔ Muscle Activation – Learn how NISE-Stim can be used to activate muscles, allow them to fire faster and improve strength.
✔ Functional Electrical Stimulation (FES) – Discover effective treatment strategies for improving trunk, upper, and lower extremity control.
✔ Muscle & Nerve Testing – Gain expertise in assessing muscle-nerve function and optimizing stimulation parameters.
✔ Hands-On Training & Clinical Videos – Participate in practical sessions and review real case studies to enhance your skills.

This course will provide step-by-step guidance on selecting optimal stimulation settings, refining treatment plans, and advancing therapy techniques for better patient outcomes.

NO PREVIOUS KNOWLEDGE OF ELECTRICAL STIMULATION IS NEEDED, BUT CLINICAL KNOWLEDGE IS NECESSARY!

A Chattanooga Continuum or EMPI Continuum e-stim unit will be used for the course. The presenter will bring enough units and electrodes for up to 30 participants. A cheaper unit costing $70, the Twin Stim IV will be introduced as well.

The Turtle Bracing concept will be presented as well. It allows the therapist to fabricate quick, custom molded, inexpensive bracing to UE, LE and trunk which can be remolded and adjusted to growth and fit many times.

Biography:
With 40 years of experience as a pediatric physical therapist, Gerti Motavalli, MPT, has worked in Germany, India, and the USA, specializing in neurological rehabilitation. In collaboration with Dr. Gad Alon, PhD, PT, she developed the first surface spinal electrical stimulation protocol in 2017 for children with Spina Bifida, published 2019 in Child Neurology Open.

Gerti has presented at the Spina Bifida World Conference (2023, Tucson, AZ) and international conferences in the UK and Germany. She trains therapists worldwide in NISE-Stim, expanding its use for children with Spina Bifida, cerebral palsy, SMA, and other motor impairments. Through in-person and online treatment, she continues to make spinal stimulation more accessible globally.

For more information, visit spinalstim.net.

Program Objectives:
1. Explain the required stimulation parameters and appropriate protocols/procedures used in pediatrics.

2. Describe the advantages, limitations, contra-indications, and indications for the use of electrical stimulation in the management of pediatric patients.

3. Discuss the various mechanisms by which functional electrical stimulation and spinal electrical stimulation can affect the peripheral neuromuscular, peripheral vascular, skeletal as well as central nervous systems.

4. Describe the procedures for nerve conduction testing.

5. Explain the application of lower spinal stimulation protocols and procedures.

6. Describe how to implement functional electrical stimulation in gait.

7. Explain electrode placement for plexus paralysis using upper spinal stimulation.

8. Select appropriate patients and implement surface spinal electrical stimulation in children with spina bifida or other neuromotor impairments.

9. Advise caregivers how to properly use the stimulation at home in to achieve more effective and efficient outcome.   

10. Explain the advantages, limitations, contra-indications, and indications for the use of Turtle Bracing for pediatric patients.

11. Fabricate a Turtle Brace and assess the Turtle Brace for good alignment and fit.                                                     

 

Class Schedule (subject to change)

Day 1 (9 hours)

7:30 AM: Registration

8:00–9:00 AM: Electrical stimulation technology (electrical parameters, electrodes). What we must know about the stimulation systems

9:00–10:30 AM: Hands–on laboratory I: Sensory vs. muscle activation, twitch vs. tetanic contraction, symmetrical vs asymmetrical current

10:30–11:00 AM: Research

11:00–11:15 AM: Break

11:15 AM–12:00 PM: Electrical excitability testing for peripheral nerve damage, upper and lower extremity, and trunk

12:00–1:00 PM: Introducing surface non-invasive spinal cord stimulation

1:00–1:30 PM: Lunch

1:30–2:30 PM: Demo patient: nerve conduction testing and spinal stimulation treatment

2:30–3:00 PM: Discussion of the evaluation findings and treatment approach

3:00–3:30 PM: Spinal Stimulation for club foot, nerve pain, CP, scoliosis, plexus paralysis, bowel, and bladder

3:30–3:45 PM: Break

3:45–5:00 PM: Hands–on laboratory II: Various placements and settings for surface non-invasive spinal cord stimulation for lower extremity, spinal stimulation on sensory level

5:00–6:00 PM: Hands-on Laboratory III: Spinal Electrical Stimulation for upper extremity and trunk for various impairments, spinal stimulation on the sensory level

 

Day 2 Schedule (7 hours)

7:30–8:00 AM (30 min): Review of key points

8:00–9:00 AM (60 min): Hands-On Laboratory: NISE-Stim for various impairments

9:00–10:00 AM (60 min): Functional Electrical Stimulation

10:00–10:15 AM (15 min): Break

10:15–11:15 AM (60 min): Hands-On Laboratory: FES for sit-to-stand transitions, bilateral reaching, gait, transitions, crawling, and unilateral reaching

11:15 AM–12:15 PM (60 min): Demonstration patient: assessment and treatment. Discussion of findings and treatment approach

12:15–12:45 PM (30 min): Lunch

12:45–1:45 PM (60 min): Five demonstration patients for class treatment

1:45–2:00 PM (15 min): Feedback on treatment

2:00–2:15 PM (15 min): Break

2:15–3:30 PM (75 min): Turtle Bracing lecture and hands-on fabrication of Turtle Braces 

 

Research:
Motavalli, Gerti, Jan J. McElroy, and Gad Alon. "An exploratory electrical stimulation protocol in the management of an infant with spina bifida: a case report." Child Neurology Open 6 (2019): 2329048X19835656.

Goutam Singh, PT, PhD; Anastasia Keller, PhD; et al.
Safety and Feasibility of Cervical and Thoracic Transcutaneous Spinal Cord Stimulation to Improve Hand Motor Function in Children With Chronic Spinal Cord Injury. Neuromodulation 4/2023, https://doi.org/10.1016/j.neurom.2023.04.475

Kristin Girshin 1,2, Rahul Sachdeva, et al. Spinal Cord Neuromodulation to treat Cerebral Palsy in Pediatrics: POUNCE Multiside Randomized Clinical Trial 6/2023 Frontiers in Neuroscience, 10.3389/fnins.2023.1221809

James J. Laskin, Zeina Waheed,et al. Spinal Cord Stimulation Research in the Restoration of Motor, Sensory, and Autonomic Function for Individuals Living With Spinal Cord Injuries: A Scoping Review, Archives of Physical Medicine and Rehabilitation 2022;103: 1387-97, http://www.archives-pmr.org/

Parag N. Gad, Evgeniy Kreydin, Non-invasive Neuromodulation of Spinal Cord Restores Lower Urinary Tract Function After Paralysis, Frontiers in Neuroscience, doi: 10.3389/fnins.2018.00432

Samejima, S. Caskey, C. D. Inanici, F. Multisite Transcutaneous Spinal Stimulation for Walking and        Autonomic Recovery in Motor-Incomplete Tetraplegia: A Single-Subject Design. Phys Ther 2022;102: DOI10.1093/ptj/pzab228.

Anastasia Keller1,2, Goutam Singh 1,2, et al. Noninvasive spinal stimulation safely enables upright posture in children with spinal cord injury NATURE COMMUNICATIONS https://doi.org/10.1038/s41467-021-26026-z

Solopova IA, Sukhotina IA, Zhvansky DS, et al. Effects of spinal cord stimulation on motor functions in children with cerebral palsy. Neurosci Lett. 2017;639:192-198.

Krucoff MO, Rahimpour S, Slutzky MW, Edgerton VR, Turner DA. Enhancing Nervous System Recovery through Neurobiologics, Neural Interface Training, and Neurorehabilitation. Front Neurosci. 2016;10:584.

Gerasimenko Y, Gad P, Sayenko D, et al. Integration of sensory, spinal, and volitional descending inputs in regulation of human locomotion. J Neurophysiol. 2016;116(1):98-105.

Lee NG, Andrews E, Rosoklija I, et al. The effect of spinal cord level on sexual function in the spina bifida population. J Pediatr Urol. 2015;11(3):142 e141-146.

Sayenko DG, Atkinson DA, Floyd TC, et al. Effects of paired transcutaneous electrical stimulation delivered at single and dual sites over lumbosacral spinal cord. Neurosci Lett.2015;609:229-234.

Shideler, B.L., et al., Toward a hybrid exoskeleton for crouch gait in children with cerebral palsy: neuromuscular electrical stimulation for improved knee extension. J Neuroeng Rehabil, 2020.

 

Please note that in the event of unforeseen circumstances, such as sudden severe illness or canceled flights, that prevent me from attending the course, I will refund the course fee in full. However, I cannot be held responsible for any additional expenses that participants may incur, such as travel or accommodation costs.