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Rehabilitation Robots: Market Shares, Strategies, and Forecasts, Worldwide, 2015 to 2021

March 2015 | 659 pages | ID: R8BC56CC9E4EN
WinterGreen Research

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LEXINGTON, Massachusetts (March 23, 2015) – WinterGreen Research announces that it has published a new study Rehabilitation Robots: Market Shares, Strategy, and Forecasts, Worldwide, 2015 to 2021. The 2015 study has 659 pages, 266 tables and figures. Worldwide markets are poised to achieve significant growth as the rehabilitation robots, active prostheses, and exoskeletons are used inside rehabilitation treatment centers and sports facilities providing rehabilitation for all patients with injuries or physical dysfunction.

Relearning of lost functions in a patient depends on stimulation of desire to conquer the disability. The rehabilitation robots can show patients progress and keep the progress occurring, encouraging patients to work on getting healthier. Independent functioning of patients depends on intensity of treatment, task-specific exercises, active initiation of movements and motivation and feedback. Rehabilitation robots can assist with these tasks in multiple ways. Creating a gaming aspect to the rehabilitation process has brought a significant improvement in systems.

As patients get stronger and more coordinated, a therapist can program the robot to let them bear more weight and move more freely in different directions, walking, kicking a ball, or even lunging to the side to catch one. The robot can follow the patient’s lead as effortlessly as a ballroom dancer, its presence nearly undetectable until it senses the patient starting to drop and quickly stops a fall. In the later stages of physical therapy, the robot can nudge patients off balance to help them learn to recover.

According to Susan Eustis, principal author of the team that developed the market research study, “Robotic therapy stimulus of upper limbs provides an example of the excellent motor recovery after stroke that can be achieved using rehabilitation robots.” Lower limb systems and exoskeleton systems provide wheelchair bound patients the ability to get out of a wheelchair.

No company dominates the entire rehabilitation robot market sector. The products that work are still emerging as commercial devices. All the products that are now commercially viable are positioned to achieve significant staying power in the market long term, providing those companies that offer them with a possibility for long term leadership position in the market.

The companies you would expect to see as participating in these markets, the leaders in the wheelchair markets re not there with any significant presence. The exoskeletons will challenge the wheel chairs, providing a supplement to the wheelchair, permitting disabled people to have some more mobility than they have now.

Robotic rehabilitation equipment is mostly used in rehabilitation clinical facilities. There is a huge opportunity for launching a homecare equipment market if it is done through sports clubs rather than through clinical facilities. People expect insurance to pay for medical equipment but are willing to spend bundles on sports trainer equipment for the home. Rehabilitation robots can help stroke patients years after an event, so it makes a difference if someone keeps working to improve their functioning.

Vendors will very likely have to develop a strong rehabilitation robotic market presence as these devices evolve a homecare aspect. The expense of nursing home rehabilitation has been very high, limiting the use of rehabilitation to a few weeks or months at the most.

Rehabilitation robots realistically extend the use of automated process for rehabilitation in the home. The availability of affordable devices that improve mobility is not likely to go unnoticed by the sports clubs and the baby boomer generation, now entering the over 65 age group and seeking to maintain lifestyle.

As clinicians realize that more gains can be made by using rehabilitation robots in the home, the pace of acquisitions will likely pick up.

Rehabilitation robot market size at $203.3 million in 2014 is expected grow dramatically to reach $1.1 billion by 2021. Exoskeleton markets will be separate and additive to this market. A separate exoskeleton market will create more growth. Market growth is a result of the effectiveness of robotic treatment of muscle difficulty. The usefulness of the rehabilitation robots is increasing. Doing more sophisticated combinations of exercise have become more feasible as the technology evolves. Patients generally practice 1,000 varied movements per session. With the robots, more sessions are possible.

WinterGreen Research is an independent research organization funded by the sale of market research studies all over the world and by the implementation of ROI models that are used to calculate the total cost of ownership of equipment, services, and software. The company has 35 distributors worldwide, including Global Information Info Shop, Market Research.com, Research and Markets, Electronics.CA, Bloomberg, and Thompson Financial.

WinterGreen Research is positioned to help customers face challenges that define the modern enterprises. The increasingly global nature of science, technology and engineering is a reflection of the implementation of the globally integrated enterprise. Customers trust WinterGreen Research to work alongside them to ensure the success of the participation in a particular market segment. WinterGreen Research supports various market segment programs; provides trusted technical services to the marketing departments. It carries out accurate market share and forecast analysis services for a range of commercial and government customers globally. These are all vital market research support solutions requiring trust and integrity.
REHABILITATION ROBOT EXECUTIVE SUMMARY

Rehabilitation Robot Market Driving Forces
  Rehabilitation Robots Assistive Devices
  Rehabilitation Robots Decrease the Cost of Recovery
  Rehabilitation Robot Medical Conditions Treated
  Robotic Modules for Disability Therapy
  Wearable Robotics for Disability Therapy
  Rehabilitation Robots Leverage Principles Of Neuroplasticity
Rehabilitation Robot Market Shares
Rehabilitation Robot Market Forecasts

1. REHABILITATION ROBOT MARKET DESCRIPTION AND MARKET DYNAMICS

1.1 Stroke Rehabilitation
  1.1.1 Stroke Protocols
  1.1.2 Rehabilitation Medicine: New Therapies in Stroke Rehabilitation
  1.1.3 Botulinum Toxin Injections
  1.1.4 Constraint Induced Movement Therapy (CIMT)
  1.1.5 Dynamic Splinting
  1.1.6 Electrical Stimulation
  1.1.7 Robotic Therapy Devices
  1.1.8 Partial Body Weight-Supported Treadmill
  1.1.9 Virtual Reality (including Wii-hab)
  1.1.10 Brain Stimulation
  1.1.11 Acupuncture
  1.1.12 Mental Practice
  1.1.13 Mirror Therapy
  1.1.14 Hyperbaric Oxygen Therapy
  1.1.15 Evidence-Based Treatment Protocols
1.2 Restoring Physical Function Through Neuro-Rehabilitation After Stroke
  1.2.1 Traumatic Brain Injury Program
  1.2.2 Concussion Program
  1.2.3 Hospital Stroke Programs Rapid Response to Create Better Outcomes
  1.2.4 Stroke Response Process Leverage Protocols that Implement Streamlined Timely Treatment
1.3 Rehabilitation Physical Therapy Trends
  1.3.1 Running with Robots
  1.3.2 Use Of Video Game Technology In PT
  1.3.3 Telemedicine Growing Trend In The Physical Therapy Space
1.4 Rehabilitation Robot Market Definition
  1.4.1 Automated Process for Rehabilitation Robots
  1.4.2 Why Rehabilitation is Essential
  1.4.3 Rehabilitation Involves Relearning of Lost Functions
1.5 Continuous Passive Motion CPM Definition
1.6 Robotic Exoskeletons Empower Patient Rehabilitation Achievements
  1.6.1 Rehabilitation Options
  1.6.2 Rehabilitation Robots Economies Of Scale
1.7 Seizing the Robotics Opportunity
  1.7.1 Modular Self-Reconfiguring Robotic Systems
1.8 Public Aware That Robotics Have “Arrived”
  1.8.1 Rehabilitation Robotics Centers Of Excellence
1.9 Home Medical Rehabilitation Robots
  1.9.1 Telemedicine and Domestic Robots
  1.9.2 Rehabilitation Robots Provide Intensive Training For Patients And Physical Relief For Therapists

2. REHABILITATION ROBOT MARKET SHARES AND MARKET FORECASTS

2.1 Rehabilitation Robot Market Driving Forces
  2.1.1 Rehabilitation Robots Assistive Devices
  2.1.2 Rehabilitation Robots Decrease the Cost of Recovery
  2.1.3 Rehabilitation Robot Medical Conditions Treated
  2.1.4 Robotic Modules for Disability Therapy
  2.1.5 Wearable Robotics for Disability Therapy
  2.1.6 Rehabilitation Robots Leverage Principles Of Neuroplasticity
2.2 Rehabilitation Robot Market Shares
  2.2.1 AlterG Bionic Leg Customer Base
  2.2.2 Myomo
  2.2.3 Interactive Motion Technologies (IMT) InMotion Robots
  2.2.4 Hocoma Robotic Rehabilitation
  2.2.5 Homoca Helping Patients To Grasp The Initiative And Reach Towards Recovery
  2.2.6 Ekso Bionics Robotic Suit Helps Paralyzed Man Walk Again
  2.2.7 Rehabilitation Robot Market Share Unit Analysis
  2.2.8 Motorized CPM Stroke Rehabilitation Equipment Market Shares
2.3 Rehabilitation Robot Market Forecasts
  2.3.1 Rehabilitation Robot Unit Shipments
  2.3.2 Rehabilitation Robots Market Segments: Lower Extremities, Upper Extremities, Neurological Training, Exoskeleton, Stroke CPM
  2.3.3 Rehabilitation Robots: Dollars and Units, High End, Mid Range, and Low End, Shipments
  2.3.4 Rehabilitation Robot Market Penetration Forecasts Worldwide, 2014-2020
2.4 Types of Conditions and Rehabilitation Treatment by Condition
  2.4.1 Stroke
  2.4.2 Early Rehab After Stroke
  2.4.3 Multiple sclerosis
  2.4.4 Knee-Replacement Surgery
  2.4.5 Hip
  2.4.6 Gait Training
  2.4.7 Sports Training
  2.4.8 Severe Injury or Amputation
  2.4.9 Neurological Disorders
  2.4.10 Recovery After Surgery
2.5 Types of Rehabilitation Robots and Conditions Treated
  2.5.1 Gait Training Devices / Unweighting Systems
  2.5.2 Neuro-Rehabilitation
  2.5.3 Prostheses
  2.5.4 Motorized Physiotherapy CPM (Continuous Passive Motion), CAM Therapy (Controlled Active Motion) and the Onboard Protocols
  2.5.5 Gait Training Devices / Unweighting Systems / Automated Treadmills
  2.5.6 Rehabilitation Therapy Robotics Market
  2.5.7 Upper Limb Robotic Rehabilitation
  2.5.8 Shoulder Biomechanics
  2.5.9 Exoskeletons
  2.5.10 End-effectors
  2.5.11 Exoskeleton-Based Rehabilitation
  2.5.12 Mobility Training Level Of Distribution
  2.5.13 Rehabilitation Robots Cost-Benefit-Considerations
  2.5.14 Rehabilitation Systems
  2.5.15 Spinal Cord Injuries
2.6 Rehabilitation Robot And Motorized CPM Equipment
2.7 Disease Incidence and Prevalence Analysis
  2.7.1 Robotic Therapeutic Stroke Rehabilitation
  2.7.2 Aging Of The Population
  2.7.3 Disease Rehabilitation
  2.7.1 Rehabilitation of Hip Injuries
2.8 Service Robots
  2.8.1 iRobot / InTouch Health
  2.8.2 Next Generation Personal And Service Robotics
2.9 Rehabilitation Robotics Prices
  2.9.1 Danniflex 480 Lower Limb CPM Unit
  2.9.2 Shop for Patterson Kinetec CPM
  2.9.3 Chattanooga Atromot
  2.9.4 Ekso Bionics
  2.9.5 Interaxon Muse
2.10 Rehabilitation Robotics Regional Analysis
  2.10.1 Ekso Bionics Regional Presence

3. REHABILITATION ROBOTS, ACTIVE PROSTHESES, AND EXOSKELETON PRODUCTS

3.1 Lower limb Stroke Rehabilitation Devices
3.2 Hocoma Products
  3.2.1 Hocoma Supports Clinicians And Patients In Neurorehabilitation
  3.2.2 Hocoma's Lokomat Gait Orthosis Automates Locomotion Therapy On A Treadmill
  3.2.3 Hocoma Lokomat Intensive Locomotion Therapy
  3.2.4 Hocoma Lokomat Training
  3.2.5 Hocoma Lokomat Robotic Gait-Training Device Aims To Change The Part Of The Brain That Controls Motor Function
  3.2.6 Hocoma Lokomat Functional Electrical Stimulation
  3.2.7 Hocoma Lokomat Advanced Motion Analysis
  3.2.8 Hocoma Rehabilitation Robotics
  3.2.9 Hocoma ArmeoSpring for Stroke Victims
  3.2.10 Hocoma ArmeoSpring Based On An Ergonomic Arm Exoskeleton
  3.2.11 Hocoma ArmeoSpring Clinical Success
  3.2.12 Hocoma Armeo Functional Therapy Of The Upper Extremities
  3.2.13 Hocoma ArmeoSpring - Functional Arm and Hand Therapy
  3.2.14 Hocoma Valedo Functional Movement Therapy For Low Back Pain Treatment
  3.2.15 Hocoma Sensor-Based Back Training For ValedoMotion
  3.2.16 Hocoma Erigo Early Rehabilitation And Patient Mobilization
  3.2.17 Hocoma Early Rehabilitation with Robotic Mobilization and Functional Electrical Stimulation
3.3 Hobart Group / MedInvest Group / Motorika
  3.3.1 Motorika ReoAmbulator Innovative Robotic Gait Training System
  3.3.2 Motorika
3.4 Interactive Motor Technologies Anklebot
  3.4.1 IMT Anklebot Evidence-Based Neurorehabilitation Technology
  3.4.2 Interactive Motion Technologies (IMT) InMotion Robots Stroke Recovery
  3.4.3 Biomarkers Of Motor Recovery
  3.4.4 Robotic Tools For Neuro-Rehabilitation
  3.4.5 Interactive Motion Technologies (IMT) Stroke — Upper Extremity Rehabilitation
  3.4.6 Interactive Motion Technologies (IMT) Robot Provides Long Lasting Rehabilitation Improvements
  3.4.7 InMotion Robot Medical Conditions Treated
  3.4.8 InMotion HAND Robot
  3.4.9 InMotion ARM: Clinical Version Of The MIT-Manus
  3.4.10 Interactive Motion Technologies (IMT) InMotion ARM Software
  3.4.11 Interactive Motion Technologies (IMT) InMotion EVAL
  3.4.12 Interactive Motion Technologies (IMT) Maximum Shoulder Force
  3.4.13 Interactive Motion Technologies (IMT) Long Lasting Improvements
  3.4.14 MIT-MANUS
3.5 AlterG: PK100 PowerKnee
  3.5.1 AlterG Bionic Leg
  3.5.2 Alterg / Tibion Bionic Leg
  3.5.3 AlterG Bionic Leg Customer Base
  3.5.4 AlterG M300
  3.5.5 AlterG M300 Robotic Rehabilitation Treadmill
3.6 Biodex Unweighting Systems
  3.6.1 Pneumex Unweighting Systems from Biodex
3.7 Honda Gait Training
  3.7.1 Honda Motor ASIMO Humanoid Robot
3.8 Mobility Research LiteGait
3.9 Upper Limb Stroke Rehabilitation Devices
3.10 Tyromotion AMADEO -For Individual Fingers or the Entire Hand Neurological Rehabilitation
  3.10.1 Amado Finger-Hand Rehabilitation
  3.10.2 Tyromotion Amadeo System Premier Mechatronic Finger Rehabilitation Device
3.11 Myomo Neuro-Robotic Myoelectric Arm Orthosis System
  3.11.1 Myomo Brace For Medical Professionals Permits A Paralyzed Individual To Perform Activities Of Daily Living
  3.11.2 Myomo EMG
  3.11.3 Myomo mPower 1000 Indications For Use
  3.11.4 Myomo mPower 1000 Warnings
3.12 Focal Meditech BV Mealtime Support and Stress Reduction: Hand Function
  3.12.1 Focal Meditech BV Personal Robot Jaco
  3.12.2 Focal Meditech BV Dynamic Rehabilitation Robotic Arm Supports
  3.12.3 Focal Meditech BV Innovative Assistive Technology
3.13 Catholic University of America Arm Therapy Robot ARMin III
  3.13.1 Catholic University of America Armin Iii Project Description:
  3.13.2 Catholic University of America HandSOME Hand Spring Operated Movement Enhancer
3.14 Kinova Robotarm Jaco
  3.14.1 Invacare / Kinova
3.15 Neurological Training
  3.15.1 Neuro-Rehabilitation
3.16 Interaxon
  3.16.1 Interaxon Muse: Brainwave Category Biometrics
  3.16.2 InteraXon Motivates Change Of Brain
  3.16.3 Interaxon Muse Improves Response To Stress, Lowers Blood Pressure
  3.16.4 Interaxon Muse Gives Self-Control
  3.16.5 Interaxon Muse Can Improve Emotional State
  3.16.6 Interaxon Muse Extended Use Lasting Results
  3.16.7 Interaxon Muse Types of Feedback
3.17 Active Prostheses
  3.17.1 Neuronal-Device Interfaces
3.18 Orthocare Innovations Prosthesis
  3.18.1 Orthocare Innovations Edison Adaptive Vacuum Suspension System
  3.18.2 Orthocare Innovations Edison Adaptive Prosthesis
  3.18.3 Orthocare Innovations Intelligent Adaptive Prosthesis
  3.18.4 Orthocare Innovations Edison Leg and Ankle
  3.18.5 Orthocare Innovations Europa
  3.18.6 Orthocare Innovations Galileo Connector Technology
3.19 RSL Steeper Hand Prostheses
  3.19.1 RSL Steeper Electronic Assistive Technology Devices for the Home
3.20 Pererro - Switch | Access | Control
  3.20.1 Pererro+
  3.20.2 RSL Steeper V3 Myoelectric Hand
3.21 Touch Bionics’ i-limb
  3.21.1 Touch Bionics i-limb Muscle Triggers
  3.21.2 Touch Bionics I-Limb Methods For Switching Modes
  3.21.3 Touch Bionics Prostheses
  3.21.4 Touch Bionics Active Prostheses
3.22 RU Robots
  3.22.1 RU Robots Sunflower Robot
  3.22.2 RU Robots Sophisticated Interactions
  3.22.3 RU Robots Care-o-bot
3.23 Instead Technologies
  3.23.1 Instead Technologies RoboTherapist3D and 2D
  3.23.2 Instead Technologies RoboTherapist3D
  3.23.3 Instead Technologies Ultrasound Breast Volumes BreastExplorer
  3.23.4 Instead Technologies Technology-Based Company
  3.23.5 Instead Technologies Services:
3.24 Exoskeletons
  3.24.1 Muscle Memory
3.25 Ekso Bionics
  3.25.1 Ekso Gait Training Exoskeleton Uses
  3.25.2 Ekso Bionics Rehabilitation
  3.25.3 Ekso Bionics Robotic Suit Helps Paralyzed Man Walk Again
3.26 Berkley Robotics Laboratory Exoskeletons
  3.26.1 Berkley Robotics and Human Engineering Laboratory ExoHiker
  3.26.2 Berkley Robotics and Human Engineering Laboratory ExoClimber
  3.26.3 Berkeley Lower Extremity Exoskeleton (BLEEX)
  3.26.4 Berkley Robotics and Human Engineering Laboratory Exoskeleton
3.27 Reha-Stim Gait Trainer GT I
  3.27.1 Reha-Stim Gait Trainer Target Market
  3.27.2 Reha-Stim Bi-Manu-Track
  3.27.3 Reha-Stim Bi-Manu-Track Hand and Wrist
3.28 Motorized Physiotherapy CPM (Continuous Passive Motion), CAM Therapy (Controlled Active Motion) and the Onboard Protocols
  3.28.1 Movement Of Synovial Fluid To Allow For Better Diffusion Of Nutrients Into Damaged Cartilage
3.29 Chattanooga Active-K CPM (Continuous Passive Motion)
  3.29.1 Chattanooga OptiFlex 3 Knee Continuous Passive Motion (CPM)
  3.29.2 Continuous Passive Motion Machines (CPM)
  3.29.3 Chattanooga OptiFlex Ankle Continuous Passive Motion (CPM)
  3.29.4 Chattanooga OptiFlex S Shoulder Continuous Passive Motion (CPM)
  3.29.5 Chattanooga OptiFlex Elbow Continuous Passive Motion (CPM)
  3.29.6 Chattanooga OptiFlex S Shoulder Continuous Passive Motion (CPM)
3.30 Paterson Kinetec CPM
  3.30.1 Paterson / Kinetec Spectra Knee CPM
3.31 Global Medical
3.32 Furniss Corporation
  3.32.1 Furniss Corporation Continuous Passive Motion DC2480 Knee CPM
3.33 Danniflex
  3.33.1 Danniflex 480 Lower Limb CPM Unit
3.34 Rehab-Robotics Company
  3.34.1 Rehab-Robotics Hand of Hope
  3.34.2 Rehab-Robotics Hand & Arm Training
3.35 Bioxtreme
3.36 Corbys
  3.36.1 Corbys System Overview
3.37 Swtotek Motion Maker

4. REHABILITATION ROBOTS TECHNOLOGY

4.1 Robotic Actuator Energy
  4.1.1 Elastic Actuators
  4.1.2 InMotion Robots Technology
4.2 Rehabilitation Robotic Risk Mitigation
4.3 Rehabilitation Robot Multi-Factor Solutions
  4.3.1 Biometallic Materials Titanium (Ti) and its Alloys
4.4 Berkley Robotics and Human Engineering Laboratory
4.5 Rehabilitation Robot Automated Technique
  4.5.1 InMotion Robots Technology
4.6 HEXORR: Hand EXOskeleton Rehabilitation Robot
4.7 ARMin: Upper Extremity Robotic Therapy
4.8 HandSOME: Hand Spring Operated Movement Enhancer
4.9 Cognitive Science
4.10 Lopes Gait Rehabilitation Device
4.11 Artificial Muscle
4.12 ReWalk Exoskeleton Suit

5. REHABILITATION ROBOT COMPANY PROFILES

5.1 AlterG
  5.1.1 AlterG M300 Customers
  5.1.2 AlterG M300
  5.1.3 AlterG Acquires Tibion Bionic Leg
5.2 Berkley Robotics and Human Engineering Laboratory
5.3 Biodex
  5.3.1 Biodex Clinical AdvantageTM
5.4 Bioness
5.5 Bioxtreme
5.6 Breg
5.7 Catholic University of America HandSOME Hand Spring Operated Movement Enhancer498
5.8 Claflin Rehabilitation Distribution
5.9 DJO Global
  5.9.1 DJO Global Trademarks, Service Marks And Brand Names
  5.9.2 DJO Global Business Activities
  5.9.3 DJO / Chattanooga
  5.9.4 Chattanooga OptiFlex Knee Continuous Passive Motion (CPM)
5.10 Ekso Bionics
  5.10.1 Ekso Fourth Quarter And Full Year 2014 Financial Results
  5.10.2 Ekso Bionics Seeks To Lead The Technological Revolutions
  5.10.3 Ekso Bionics HULC Technology Licensed to the Lockheed Martin Corporation
  5.10.4 Ekso Bionics Regional Presence
  5.10.5 Ekso Bionics Customers
5.11 Fanuc
  5.11.1 Fanuc Revenue
  5.11.2 FANUC America - Industrial Robot Automation Systems and ROBODRILL Machine Centers
5.12 Focal Meditech
  5.12.1 FOCAL Meditech BV Collaborating Partners:
5.13 Hobart Group / Motorika
  5.13.1 Motorika
5.14 Hocoma
  5.14.1 Hocoma Revenue
5.15 Honda Motor
  5.15.1 Honda Motor Revenue
  5.15.2 Honda Automobile Business
  5.15.3 Honda Walk Assist
5.16 Instead Technologies
  5.16.1 Instead Technologies Services:
5.17 Interactive Motion Technologies (IMT)
  5.17.1 Interactive Motion Technologies (IMT) InMotion Robots
5.18 Interaxon
5.19 iRobot
  5.19.1 iRobot Home Robots
  5.19.2 iRobot Defense and Security: Protecting Those In Harm’s Way
  5.19.3 iRobot Remote Presence: Brings Meaningful Communication
  5.19.4 iRobot STEM
  5.19.5 iRobot Acquires Evolution Robotics, Inc.
  5.19.6 iRobot / Evolution Robotics
  5.19.7 iRobot / InTouch Health
5.20 KDM
5.21 Kinova
  5.21.1 Kinova JACO
5.22 KLC Services
5.23 Medi
5.24 Mobility Research
5.25 MRISAR
5.26 Myomo
  5.26.1 Myomo mPower 1000
5.27 Orthocare Innovations
  5.27.1 Orthocare Innovations Adaptive Systems For Advanced O&P Solutions.
  5.27.2 Orthocare Innovations Company Highlights
5.28 Patterson
  5.28.1 Patterson Medical Strategy
  5.28.2 Patterson Medical Brands
  5.28.3 PMI Acquires Mobilis Healthcare
  5.28.4 Patterson Medical Business Segments
  5.28.5 Patterson Medical Products and Services
  5.28.6 Patterson Medical Consumables
  5.28.7 Patterson Medical Equipment and Software
5.29 ProMed Products Xpress
5.30 Rehab-Robotics Company
5.31 Reha-Stim
  5.31.1 Reha-Stim Support Patients In Restoring And Improving Gait Function
  5.31.2 Reha-Stim Support Patients In Restoring Arm And Hand Function
5.32 ReWalk Robotics
5.33 Robotdalen
5.34 RSL Steeper
5.35 RU Robots
5.36 Secom
  5.36.1 Secom Co.Ltd MySpoon
  5.36.2 Secom Co.Ltd MySpoon Manual Mode
  5.36.3 Secom Co.Ltd MySpoon Semi-automatic Mode
  5.36.4 Secom Co. Ltd MySpoon Automatic Mode
5.37 Sunrise Medical
  5.37.1 Sunrise Medical Quality Policy
  5.37.2 Sunrise Medical Whitmyer Biomechanics
5.38 Touch Bionics
5.39 Tyromotion GmbH
  5.39.1 Tyromotion GmbH Network
5.40 Other Rehabilitation Robot Companies
  5.40.1 Additional Rehabilitation Robots
  5.40.2 Selected Rehabilitation Equipment Companies
  5.40.3 Spinal Cord Treatment Centers in the US

ABOUT THE COMPANY

Research Methodology

LIST OF TABLES AND FIGURES

Table ES-1 Rehabilitation Robot Market Driving Forces
Table ES-2 Rehabilitation Robot Medical Conditions Treated
Table ES-3 Stroke Rehabilitation Guidelines For Interactive Robotic Therapy
Table ES-4 Extremity Rehabilitation Robot Technology
Table ES-5 Health Care Conditions Treated With Rehabilitation Wearable Robotics
Table ES-6 Robotic Technologies Leverage Principles Of Neuroplasticity
Figure ES-7 Rehabilitation Robot Market Shares, Dollars, Worldwide, 2014
Figure ES-8 Rehabilitation Robot Market Forecasts Dollars, Worldwide, 2015-2021
Table 1-1 Stroke Rehabilitation Technology Modalities
Table 1-2 Neuro-Rehabilitation patient Conditions Addressed
Table 1-3 Neuro-rehabilitation Services
Table 1-4 Stroke Response Process Leverage Protocols Interdisciplinary Teams
Table 1-5 Stroke Treatment State-Of-The-Art, Full-Service Stroke Treatment Facilities
Table 1-6 Robotic Rehabilitation Devices Automated Process Benefits
Table 1-7 Robotic Rehabilitation Devices Emerging Technologies
Table 1-8 Robotic Rehabilitation Wearable Devices Benefits
Table 1-9 Rehabilitation Involves Relearning Lost Function
Table 1-10 Rehabilitation Lost Function Relearning Initiatives
Table 1-11 CPM Functions:
Table 1-12 CPM Use Indications:
Table 2-1 Rehabilitation Robot Market Driving Forces
Table 2-2 Rehabilitation Robot Medical Conditions Treated
Table 2-3 Stroke Rehabilitation Guidelines For Interactive Robotic Therapy
Table 2-4 Extremity Rehabilitation Robot Technology
Table 2-5 Health Care Conditions Treated With Rehabilitation Wearable Robotics
Table 2-6 Robotic Technologies Leverage Principles Of Neuroplasticity
Figure 2-7 Rehabilitation Robot Market Shares, Dollars, Worldwide, 2014
Table 2-8 Rehabilitation Robot Market Shares, Dollars, Worldwide, 2014
Table 2-9 Hocoma Robotic Rehabilitation Used In Rehabilitation Medicine:
Figure 2-10 Homoca Continuum of Rehabilitation
Figure 2-11 Comparison of the Hocoma Armeo Products
Table 2-12 Rehabilitation Therapy Robots Market Shares, Units, Worldwide, 2014
Table 2-13 Motorized CPM Stroke Rehabilitation Equipment Market Shares, Unit and Dollars, Worldwide, 2014
Figure 2-14 Rehabilitation Robot Market Forecasts Dollars, Worldwide, 2015-2021
Table 2-15 Rehabilitation Robots Market Forecasts, Dollars, Shipments, Worldwide, 2015-2021
Figure 2-16 Rehabilitation Robots: Units Shipments, Worldwide, 2015-2021
Table 2-17 Rehabilitation Robots: Units Shipments, Worldwide, 2015-2021
Table 2-18 Rehabilitation Robot Market Segments, Lower Extremities, Upper Extremities, Neurological Training, Exoskeleton, Stroke CPM, Dollars, Worldwide, 2015-2021
Table 2-19 Rehabilitation Robot Market Segments, Lower Extremities, Upper Extremities, Neurological Training, Exoskeleton, Stroke CPM, Percent, Worldwide, 2015-2021
Table 2-20 Rehabilitation Robots Market Segments
Figure 2-21 Rehabilitation Robots Market Forecasts, Units, Worldwide, 2015-2021
Table 2-22 Rehabilitation Robots: Units Shipments, Worldwide, 2015-2021
Table 2-23 Rehabilitation Robots: Dollars and Units, High End, Mid Range, and Low End, Shipments, Worldwide, 2015-2021
Figure 2-24 Rehabilitation Robots: Facility Market Penetration Forecasts, Units, Worldwide, 2014-2020
Table 2-25 Rehabilitation Facility Robot Market Penetration Forecasts Worldwide, 2014-2020
Table 2-26 Rehabilitation Robot Market Penetration Forecasts Worldwide, High End Facilities, Small and Mid Size Rehabilitation Facilities, 2014-2020
Table 2-27 Rehabilitation Robot Market Segments, Lower Extremities, Upper Extremities, Anti-Gravity High End, Anti-Gravity Low End, and Tools Worldwide, 2014-2020
Table 2-28 Rehabilitation Small and Mid-Size Facility Robot Market Penetration Forecasts Worldwide, 2014-2020
Table 2-29 Rehabilitation High End Facility Robot Market Penetration Forecasts, Worldwide, 2014-2020
Figure 2-30 Chattanooga OptiFlex 3 Knee Continuous Passive Motion (CPM) Device
Table 2-31 Rehabilitation Robot Categories
Table 2-32 Spinal Cord Injury Causes Worldwide, 2014
Table 2-33 Motorized CPM Stroke Rehabilitation Equipment Market Shares, Unit and Dollars, Worldwide, 2014
Table 2-34 Rehabilitation Robot CPM Market Segments, Worldwide, 2015-2021
Table 2-35 US Stroke Incidence Numbers
Table 2-36 Physical Therapy Enhances Recovery After Hip Injury
Figure 2-37 iRobot / InTouch Health RP-VITA
Figure 2-38 Chattanooga Continuous Passive Motion
Figure 2-39 Rehabilitation Robot Regional Market Segments, Dollars, 2014
Table 2-40 Rehabilitation Robot Regional Market Segments, 2014
Figure 2-41 Ekso Bionics Regional Presence Source: Ekso Bionics.
Table 3-1 Lower Limb Stroke Rehabilitation Devices
Figure 3-2 Hocoma Lokomat Pro
Table 3-3 Hocoma Patient Rehabilitation Conditions Addressed
Table 3-4 Hocoma Robotic Improvements to Rehabilitation
Table 3-5 Hocoma Products
Table 3-6 Hocoma Rehabilitation Functional Therapy
Table 3-7 Robotic Legs Working For Improving Cerebral Palsy
Figure 3-8 Hocoma Automates Locomotion Therapy On A Treadmill
Figure 3-9 Hocoma Lokomat Lower Extremity Robot
Table 3-10 Hocoma Rehabilitation Robot Systems
Figure 3-11 Hocoma Armeo Arm Robot Systems
Figure 3-12 Hocoma Lokomats Robot
Figure 3-13 Hocoma ArmeoSpring for Stroke Victims
Figure 3-14 Hocoma ArmeoSpring for Children
Figure 3-15 Hocoma Armeo Power Robotic Arm Exoskeleton
Figure 3-16 Clinical Example of Patients Using the Hocoma ArmeoSpring
Table 3-17 Hocoma Valedo Functional Lower Back Movement Therapy
Table 3-18 Hocoma ValedoMotion Low Back Pain Therapy Advantages
Figure 3-19 Hocoma Erigo
Table 3-20 Hocoma Erigo Advantages of Early Rehabilitation
Figure 3-21 Motorika ReoAmbulator
Figure 3-22 Motorika ReoAmbulator and Gait Training Devices
Figure 3-23 Interactive Motor Technologies Anklebot exoskeletal robotic system Design Principals
Figure 3-24 Interactive Motor Technologies Anklebot Walking Improvement
Figure 3-25 Interactive Motion Technologies (IMT) InMotion Biomarkers Aid Stroke Recovery
Table 3-26 Interactive Motion Technologies (IMT) InMotion Robot Medical Conditions Treated
Table 3-27 Interactive Motion Technologies (IMT) InMotion Robot Medical Technology
Table 3-28 Interactive Motion Technologies (IMT) Clinical Studies Performed With The InMotion ARM224
Table 3-29 InMotion Robots Research Positioning
Figure 3-30 InMotion HAND
Figure 3-31 InMotion HAND Robot
Table 3-32 Interactive Motion Technologies (IMT) InMotion HAND Robot Functions
Table 3-33 Interactive Motion Technologies (IMT) InMotion HAND Robot
Table 34 Interactive Motion Technologies (IMT) InMotion ARM Software Functions
Figure 3-35 Interactive Motion Technologies (IMT) 2D Gravity Compensated Therapy Is More Effective Than 3D Spatial Therapy
Figure 3-36 Measurements Show Interactive Motion Technologies (IMT) 2D Gravity Compensated Therapy Is More Effective Than 3D Spatial Therapy
Table 3-37 Interactive Motion Technologies (IMT) InMotion EVAL Aims
Table 3-38 Interactive Motion Technologies (IMT) InMotion EVAL Quantifiable Measures:
Figure 3-39 6 Degree-Of-Freedom Force-Torque Sensor Monolithic Aluminum Device Visualization
Figure 3-40 Interactive Motion Technologies (IMT) Performance Feedback Metrics
Table 3-41 Interactive Motion Technologies (IMT) InMotion ARM Specifications Dimensions
Figure 3-42 Interactive Motion Technologies (IMT) Sample Circle Plots For A Stroke Patient At Admission
Figure 3-43 Interactive Motion Technologies (IMT) Sample Circle Plots For A Stroke Patient At Discharge
Figure 3-44 AlterG: PK100 PowerKnee
Figure 3-45 AlterG Bionic Neurologic And Orthopedic Therapy Leg
Figure 3-46 Tibion Bionic Leg
Figure 3-47 AlterG M300 Robotic Rehabilitation Treadmill
Figure 3-48 AlterG M300 Robotic Leg, Knee and Thigh Rehabilitation Treadmill
Table 3-49 AlterG Anti-Gravity Treadmill Precise Unweighting Technology Patient Rehabilitation Functions254
Figure 3-50 AlterG Anti-Gravity Treadmill Heals patient Faster
Figure 3-51 Biodex Balance System SD
Figure 3-52 Biodex Balance System SD Features
Figure 3-53 Biodex Pneumex Unweighting Systems
Figure 3-54 Honda Walk assist
Figure 3-55 Honda Stride Management
Figure 3-56 Honda Walk Assist Device Specifications
Figure 3-57 Honda ASIMO
Figure 3-58 Honda ASIMO Front Position
Figure 3-59 Honda ASIMO Dimensions and Weight
Figure 3-60 Honda ASIMO Intelligence Features
Figure 3-61 Mobility Research LiteGait Solution for Gait Therapy
Table 3-62 Mobility Research LiteGait Advanced Solutions For Gait Therapy
Table 3-63 Upper Limb Stroke Rehabilitation Devices
Figure 3-64 Tyromotion Amadeo System For Neurological Rehabilitation
Table 3-65 Amado Individual Fingers Or The Entire Hand Rehabilitation Advantages
Figure 3-66 Tyromotion AMADEO -For Neurological Rehabilitation
Table 3-67 Tyromotion AMADEO -For Neurological Rehabilitation
Table 3-68 Tyromotion AmadeoBenefits
Table 3-69 Myomo mPower 1000 Indications
Table 3-70 Myomo mPower 1000 Contraindications
Table 3-71 Focals Meditech BV Models:
Table 3-72 Focal Meditech BV Assistive Technology Types
Table 3-73 Focal Meditech BV High End Assistive Technology
Table 3-74 Focal Meditech Products for Robotic Rehabilitation
Figure 3-75 ARMin III Robot For Movement Therapy Following Stroke
Figure 3-76 Kinova Robotarm Jaco
Figure 3-77 Kinova Jaco Rehabilitation Hand
Figure 3-78 Invacare Partnered with Kinova to Facilitate Use of the Jaco
Figure 3-79 Invacare Kinova Robotarm Broad Product Line
Figure 3-80 InteraXon Muse Headband
Figure 3-81 Interaxon Finely Calibrated Brain Wave Sensors
Figure 3-82 InteraXon Measuring Brainwaves
Figure 3-83 Lower Limb Prosthetic Designed By The Center For Intelligent Mechatronics
Figure 3-84 Orthocare Innovations Prosthesis
Figure 3-85 Orthocare Innovations Edison Prosthesis Ankle and Foot
Figure 3-86 Orthocare Innovations Edison Leg and Ankle
Figure 3-87 Orthocare Innovations Prosthetic Foot That Adjusts Automatically
Figure 3-88 Orthocare Innovations Proshthetic Foot That Fits
Figure 3-89 Orthocare Innovations Proshthetic Foot That Can Be Used for Hiking
Figure 3-90 Orthocare Innovations
Figure 3-91 RSLSteeper Pererro+
Table 3-92 RSLSteeper Pererro+ Key Features:
Figure 3-93 RSL Steeper Bebionic’s Standard Glove
Figure 3-94 RSL Steeper Prosthesis Hand
Figure 3-95 Touch Bionics’ i-limb Functions
Table 3-96 Touch Bionics i-limb Muscle Triggers
Figure 3-97 Touch Bionics Quick Grips
Figure 3-98 Touch Bionics Prostheses
Figure 3-99 Touch Bionics Active Prostheses
Figure 3-100 Touch Bionics Active prostheses
Table 3-101 Touch Bionics Products
Table 3-102 RU Robots Core Technologies And Competencies
Figure 3-103 RU Robots Advanced Robotics
Figure 3-104 RU Robots Sophisticated Interactions
Figure 3-105 RU Robots Care-o-bot Large Service Robot
Table 3-106 Instead Technologies Advantages of RoboTherapist3D Therapy:
Figure 3-107 Instead Technologies Robotherapist 3D RT3D Arm
Figure 3-108 Instead Technologies Robotherapist 3D RT3D Cup
Figure 3-109 Instead Technologies RT3D Hand
Figure 3-110 Instead Technologies Robotherapist 3D RT3D Ring Structure
Figure 3-111 Instead Technologies Ultrasound Breast Volumes. BreastExplorer
Figure 3-112 Instead Technologies Ultrasound Breast Volumes BreastExplorer Handheld Device
Figure 3-113 Instead Technologies Ultrasound Breast Volumes BreastExplorer Screen Display
Table 3-114 Instead Technologies Research:
Table 3-115 Instead Technologies Consultancy Services:
Figure 3-116 Esko Technology
Figure 3-117 Ekso Bionics Gait Training
Figure 3-118 Ekso Bionics Gait Training Functions
Table 3-119 Ekso Gait Training Exoskeleton Functions
Table 3-120 Ekso Gait Training Exoskeleton Functions
Figure 3-121 Ekso Bionics Step Support System
Table 3-122 Ekso Bionics Operation Modes
Figure 3-123 3.25.2 Ekso Bionics
Figure 3-124 Ekso Bionics Bionic Suit
Figure 3-125 Berkley Robotics and Human Engineering Laboratory ExoHiker
Figure 3-126 Berkley Robotics and Human Engineering Laboratory ExoClimber
Table 3-127 Berkley Robotics and Human Engineering Laboratory Exoskeleton
Figure 3-128 Reha-Stim Gait Trainer GT I
Figure 3-129 Reha-Stim Gait Trainer Improves The Patient Ability To Walk Through Continuous Practice
Figure 3-130 Reha-Stim Bi-Manu-Track Hand and Wrist Rehabilitation Device
Figure 3-131 Reha-Stim Gait Trainer GT I Harness
Figure 3-132 Motorized Physiotherapy Controlled Mobilization Goals of phase 1 rehabilitation
Table 3-133 Continuous Passive Motion (CPM) Device Benefits Following Knee Arthroplasty
Figure 3-134 Chattanooga CPM
Table 3-135 Chattanooga Active-K Functions
Figure 3-136 DJO Chattanooga Active-K
Figure 3-137 Chattanooga Active-K Motorized Physiotherapy Unit Integration Benefits
Figure 3-138 Chattanooga Active-K Motorized Physiotherapy Controlled Mobilization
Figure 3-139 Chattanooga Active-K Motorized Physiotherapy CPM (Continuous Passive Motion
Figure 3-140 Chattanooga Active-K Motorized Physiotherapy Controller
Figure 3-141 DJO Chattanooga Active-K Features:
Table 3-142 Chattanooga Active-K Motorized Physiotherapy Therapeutic Modes
Figure 3-143 Chattanooga Active-K Motorized Physiotherapy Therapeutic Benefits
Figure 3-144 Chattanooga OptiFlex 3 Knee Continuous Passive Motion (CPM) Device
Table 3-145 Chattanooga Optiflex Knee CPM Unique Features:
Table 3-146 Chattanooga Optiflex CPM Use While Resting
Table 3-147 Chattanooga Optiflex Knee CPM Standard Functions:
Table 3-148 Chattanooga OptiFlex 3 Knee Continuous Passive Motion (CPM) Specifications:
Figure 3-149 Chattanooga OptiFlex 3 Ankle Continuous Passive Motion (CPM)
Table 3-150 Chattanooga Optiflex Ankle CPM Features:
Table 3-151 Chattanooga Optiflex Ankle CPM Specifications:
Table 3-152 Chattanooga Optiflex Shoulder CPM Features:
Figure 3-153 Chattanooga OptiFlex 3 Elbow Continuous Passive Motion (CPM)
Table 3-154 Chattanooga OptiFlex Elbow CPM Features:
Figure 3-155 Chattanooga OptiFlex 3 Elbow Continuous Passive Motion (CPM)
Table 3-156 Chattanooga OptiFlex 3 Elbow Continuous Passive Motion (CPM) Specifications:
Figure 3-157 Chattanooga OptiFlex 3 Elbow Continuous Passive Motion (CPM) Flexion
Figure 3-158 Chattanooga OptiFlex S Shoulder Continuous Passive Motion (CPM)
Table 3-159 Chattanooga OptiFlex Shoulder CPM Features:
Figure 3-160 Paterson Kinetec Knee CPM
Table 3-161 Paterson Kinetec Spectra Knee CPM Features:
Table 3-162 Paterson Kinetec Spectra Knee CPM Treatment Modes
Figure 3-163 Global Medical CPM device
Table 3-164 Global Medical CPM device Features
Figure 3-165 Global Medical Handheld Controller
Figure 3-166 Furniss Corporation Model 1800 Knee CPM
Table 3-167 Furniss Corporation CPM 1800 Features
Figure 3-168 Furniss Corporation CP
Figure 3-169 Furniss Corporation Phoenix Model 1850 Knee CPM
Figure 3-170 Furniss Corporation Continuous Passive Motion DC2480 Knee CPM
Figure 3-171 Danniflex 480 Lower Limb CPM Unit
Table 3-172 Danniflex Lower Limb CPM Features
Figure 3-173 Rehab-Robotics Company Hand of Hope Therapeutic Device
Figure 3-174 Rehab-Robotics Repetitive Training System
Table 3-175 Rehab-Robotics Hand of Hope Movement Control
Figure 3-176 Rehab-Robotics Modes Provide Different Levels Of Assistance In Movement Of Patient’s Hand
Figure 3-177 Rehab-Robotics Different Modes
Figure 3-178 Rehab-Robotics Arm Training
Table 3-179 Rehab-Robotics Hand of Hope Modes
Figure 3-180 Bioxtreme Robotic Rehabilitation System
Figure 3-181 Corbys Rehabilitation Robot
Figure 3-182 Corbys Rehabilitation System
Figure 3-183 Corbys Rehabilitation Orthosis Actuation Test Stand
Figure 3-184 Corbys Mobile Robotic Gait Rehabilitation System
Figure 3-185 Swtotek Leg Orthosis of Motion Maker
Table 4-1 Rehabilitation Robot System Concerns Addressed During System Design
Table 4-5 Rehabilitation Robots Software Functions
Table 4-6 InMotion Robots Immediate Interactive Response Sets
Table 4-7 HEXORR: Hand EXOskeleton Rehabilitation Robot Technology Benefits
Table 4-8 HEXORR: Hand EXOskeleton Rehabilitation Robot Technology Monitoring
Table 4-9 HEXORR: Hand EXOskeleton Rehabilitation Robot Treatment Benefits
Table 4-10 HEXORR: Hand EXOskeleton Rehabilitation Robot Technology Force and Motion Sensor Benefits
Figure 4-11 Hand Spring Operated Movement Enhancer
Figure 4-12 Hand Spring Robot Operated Movement Enhancer
Table 5-1 AlterG Anti-Gravity Treadmillsr Features Built on differential air pressure technology
Table 5-2 AlterG Anti-Gravity Treadmillsr Target Markets
Table 5-3 AlterG Product Positioning
Figure 5-4 Selected US Regional AlterG M300 Customer CLusters
Figure 5-5 AlterG / Tibion Bionic Leg
Table 5-6 Berkley Robotics and Human Engineering Laboratory Research Work
Table 5-7 Berkley Robotics and Human Engineering Laboratory Research Work
Figure 5-9 Breg Home Therapy CPM Continuous Passive Motion Practice Kits
Table 5-10 DJO Rehabilitation Product Target Markets
Table 5-11 DJO Rehabilitation Product Targets Care Givers
Figure 5-12 Ekso Bionics Regional Presence
Table 5-13 FOCAL Meditech BV Products:
Table 5-14 FOCAL Meditech BV High- End Rehabilitation Medical Devices
Table 5-15 FOCAL Meditech BV Collaborating Partners:
Table 5-16 Hocoma Robotic Rehabilitation Used In Rehabilitation Medicine:
Table 5-17 Hocoma Therapy Solutions Treatments
Table 5-18 Honda’s Principal Automobile Products
Figure 5-19 Honda Walk assist
Table 5-20 Instead Technologies Research:
Table 5-21 Instead Technologies Consultancy Services:
Table 5-22 iRobot / InTouch Health RP-VITA
Figure 3-23 iRobot / InTouch Health RP-VITA
Figure 5-24 Mobility Research LiteGait Device
Table 5-25 RUR Key Market Areas For Robotic Technologies
Figure 5-26 Secom Co.Ltd MySpoon Manual Mode
Table 5-27 Secom Co.Ltd MySpoon Features in Manual Mode
Figure 5-28 Secom Co.Ltd MySpoon Semi-automatic Mode
Table 5-29 Secom Co.Ltd MySpoon Semi-automatic Mode
Figure 5-30 Secom Co.Ltd MySpoon Automatic Mode
Table 5-31 Secom Co.Ltd MySpoon Automatic Mode
Table 5-32 Sunrise Medical Products
Figure 5-33 Sunrise Medical Whitmyer Biomechanics Head Support
Table 5-34 Sunrise Medical Whitmyer Biomechanics Headrest Features
Figure 5-35 Touch Bionics Prosthetic Technologies
Figure 5-36 Tyromotion GmbH Employee Group
Table 5-37 Tyromotion GmbH PabloPlus System Strengthens The Upper Extremity Hand, Arm And Wrist Functions
Table 5-38 Tyromotion Network


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