Dr. Avraham CohenChief Clinical Officer MediTouch Ltd.

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FEEDBACK IN PHYSICAL REHABILITATION

N e w G e n e r a t i o n i n R e h a b i l i t a t i o n

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1 INTRODUCTION

MOTOR LEARNING2

BIOFEEDBACK3

4 CLINICAL APPLICATIONS

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OPTIMAL REHABILITATION

Introduction

FUNCTIONALABILITIES

SENSORIMOTORIMPROVEMENT

REHAB. AIMREHAB. METHOD

?

MOTORLEARNING

Motor learning

INREHABLITATION

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DISABILITY

DISABILITIES

NEUROMUSCULAR / MUSCULOSKELETAL INJURIES

SENSORIMOTOR IMPAIRMENTS

Motor learning

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DISABILITY

FUNCTIONAL ACTIVITIES

SOCIAL PARTICIPATION

BODY FUNCTION

Motor learning

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APPROACHES

FUNCTIONALPRACTICE

IMPAIRMENT IMPROVEMENT

Motor learning

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APPROACHES

IMPAIRMENTPRACTICE

FUNCTIONALIMPROVEMENT

Motor learning

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CLINICAL REASONING

DIAGNOSIS

PHASE

MOVEMENTABILITY

Motor learning

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BRAIN PLASTICITY

BRAIN'S ABILITY TO CHANGE PHYSICALLY, CHEMICALLY AND FUNCTIONALLY THROUGHOUT LIFE.

Motor learning

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MOVEMENT INSTRUCTIONS

MOTOR CORTEX RECEIVES INSTRUCTION AND FEEDBACK INPUT FROM VISUAL AND AUDITORY CORTEX

Motor learning

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MOTOR CORTEX

RESPONSIBLE TO PLAN, CONTROL AND EXECUTE VOLUNTARY MOVEMENTS

Motor learning

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MOVEMENT INSTRUCTIONS

Motor learning

VISUAL INPUT IS RESPONSIBLE FOR SELF OBJECTIVE UNDERSTANDING OF MOVEMENT

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MOVEMENT INSTRUCTIONS

Motor learning

AUDITORY INPUT IS RESPONSIBLE FOR SELF SUBJECTIVE UNDERSTANDING OF MOVEMENT

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MOVEMENT INSTRUCTIONS

OPTIMAL VOLUNTARY MOVEMENTS ARE EXECUTED BY OBJECTIVE AND SUBJECTIVE INPUTS

AUDITORY

VISUAL

Motor learning

SPATIAL ORIENTATION

VISUAL SYSTEM

PERIPHERAL MECHANOCEPTORS

VESTIBULAR SYSTEM

Motor learning

PERIPHERAL SENSATION

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PERIPHERAL MECHANOCEPTORS

Motor learning

MUSCLE SPINDLE

SKIN RECEPTORS

TENDON GOLGI

LIGAMENT ARTICULAR RECEPTORS

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PERIPHERAL SENSATION

PROPERIOCEPTION - JOINT POSITION INFORMATION

KINESTHESIA - JOINT MOVEMENT INFORMATION

JOINT RESISTANCE - FORCE GENERATED WITHIN A JOINT

DEEP SENSATION

TEMPERATURE

PAIN

PRESSURE

CUTANEOUS SENSATION

Motor learning

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SPATIAL ORIENTATION

SPATIAL ORIENTATION HELPS TO MAXIMIZE BODY FUNCTION

Motor learning

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PERIPHERAL SENSATION

PROPRIOCEPTION JOINT POSITION INFORMATION

KINESTHESIA JOINT MOVEMENT

INFORMATION

Motor learning

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PERIPHERAL SENSATION

PERIPHERAL SENSATION HELPS TO MINIMIZE BODY DAMAGE

Motor learning

OPTIMAL BRAIN ORGANIZATION MOVEMENT USING AMPLIFICATION OF WEAK AND REDUCTION OF DOMINANT INPUT

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POSITIVE BRAIN REORGANIZATION

Motor learning

VISUAL CORTEX

AUDITORY CORTEX

PERIPHERAL SENSATION

MOTOR CORTEX

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REHABILITATION METHODS

Motor learning

IOT – Impairment Oriented Training

HIGH RESOLUTION

OPEN KINETIC CHAIN

IOT

OBJECTIVE EVALUATION

CLOSED KINETIC CHAIN

HIGH COORDINATION

TOT

SUBJECTIVE EVALUATION

TOT – Task Oriented Training

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PRACTICE TYPE

BLOCKED A SERIES OF IDENTICAL PRACTICE

RANDOM A SERIES OF DIFFERENT PRACTICE

DISTRIBUTED MORE REST TIME THAN PRACTICE TIME

Motor learning

MASSEDMORE PRACTICE TIME THAN REST TIME

OPEN KINETIC CHAIN

PRACTICE METHOD

KINESTHESIA

PROPRIOCEPTION

JOINT RESISTANCE

LOCAL DEEP SENSATION

LIMITED MUSCLE RECRUITMENT

LOW BALANCE ABILITY

LOW MUSCLE STRENGTH

Motor learning

NO GROUND REACTION FORCE25

PRACTICE METHOD

KINESTHESIA

PROPRIOCEPTION

JOINT RESISTANCE

MULTI DEEP SENSATION

MULTI MUSCLE RECRUITMENT

HIGH BALANCE ABILITY

HIGH MUSCLE STRENGTH

Motor learning

WITH GROUND REACTION FORCE

CLOSED KINETIC CHAIN

GRF

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PRACTICE METHOD

FOR MOBILITY OPEN CHAIN SHOULD BE USED

FOR STABILITY STATIC CLOSED CHAIN SHOULD BE USED

FOR CONTROLLED MOBILITY DYNAMIC CLOSED CHAIN SHOULD BE USED

Motor learning

IMPAIRMENT FOCUS

SELECTIVE PRACTICE LEADS TO PREVENT COMPENSATORY MOVEMENT DEVELOPMENT

Motor learning

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DIFFICULTY LEVEL CUSTOMIZATION

TASK DIFFICULTY LEVEL CUSTOMIZED TO PATIENT PHYSICAL ABILITY

Motor learning

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INTENSIVE PRACTICE

Motor learning

INTENSIVE REPETITION OF CUSTOMIZED TASK ARE REQUIRED FOR MOTOR LEANING AND PHYSICAL REHABILITATION

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REACTION TIME

TIME PREDICTION AND TASK INSTRUCTION AFFECT ON REACTION TIME

Motor learning

Biofeedback

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KNOWLEDGE OF RESULT (KR)

KR IS THE INFORMATION ABOUT THE PERFORMANCE OUTCOME

DEFINITION

FEEDBACK WITH LESS SENSORIMOTOR INVOLVEMENTIN THE CORRECT MOVEMENT PERFORMANCE

DESCRIPTION

Biofeedback

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KNOWLEDGE OF RESULT (KR)

Biofeedback

KR CAN CAUSE COMPENSATORY MOVEMENT DEVELOPMENT

DISADVANTAGES

ADVANTAGES KR USED BY PATIENTS WITH BROAD SPECTRUM OF MOVEMENT ABILITIES

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KNOWLEDGE OF PERFORMANCE (KP)

KP IS THE INFORMATION ABOUT THE QUALITY OF PERFORMANCE

DEFINITION

Biofeedback

DESCRIPTIONFEEDBACK WITH MORE SENSORIMOTOR INVOLVEMENTIN THE CORRECT MOVEMENT PERFORMANCE

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KNOWLEDGE OF PERFORMANCE (KP)

USED IN BROAD SPECTRUM OF MOVEMENT ABILITIES

ADVANTAGES

Biofeedback

PROVIDES CONTINUING AND TERMINAL FEEDBACK

PROVIDES PROFESSIONAL TRAINING

PREVENTS COMPENSATORY MOVEMENT DEVELOPMENT

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FEEDBACK TYPES

INTERNAL

PERIPHERAL

SENSATION

VISION

AUDITION

EXTERNAL

REAL

AUGMENTED

Biofeedback

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FEEDBACK ACCURACY

PRECISE FEEDBACK COMPARED TO GENERAL ENCOURAGEMENT

Biofeedback

PA

TIE

NT

AB

ILIT

Y

REHABILITATION PERIOD

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FEEDBACK DOSAGE

FEEDBACK INTENSITY NEEDS TO INCREASE AS IMPAIRMENT SEVERITY INCREASES

Biofeedback

FE

ED

BA

CK

INT

EN

SIT

Y

IMPAIRMENT SEVERITY

TASK INTRINSIC FEEDBACK

PROVIDES VISION, AUDITION AND SENSATION INFORMATION

Biofeedback

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FADED FEEDBACK

FEEDBACK SHOULD BE PROVIDED IN DEVIATION LIMIT

Biofeedback

DEVIATION AREA

CORRECT AREA

FEEDBACK AREA

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REAL TIME FEEDBACK

PROVIDES IMMEDIATE INFORMATION, SHORT TERM MEMORY NOT REQUIRED

Biofeedback

TERMINAL FEEDBACK

KR AND KP INFORMATION THAT IS PROVIDED AFTER MOVEMENT PERFORMANCE

DEFINITION

Biofeedback

TERMINAL KRINFORMATION PROVIDED AFTER PERFORMANCE ON HOW TO IMPROVE MOVEMENT

TERMINAL KPA COMBINATION OF INFORMATION AND INSTRUCTION PROVIDED AFTER PERFORMANCE ON HOW TO IMPROVE MOVEMENT

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EXTERNAL FEEDBACK

EXTERNAL DEVICES PROVIDE INFORMATION DURING TASK PERFORMANCE

Biofeedback

NON MEASURABLE DEVICES

AUGMENTED FEEDBACK

MEASURABLE DEVICES

REAL FEEDBACK

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CHALLENGE EFFECT

Biofeedback

CHALLENGING TASK

INCREASE MOTIVATION

REPETITIVE PERFORMANCE

BETTER OUTCOME

BEFORE CHALLENGE

AFTER CHALLENGE

PERFORMANCE CORRECTION

LEADS TO SELF OBJECTIVE UNDERSTANDING OF PERFORMANCE

Biofeedback

POSITIVE FEEDBACK

NEGATIVE FEEDBACK

MOTION FEEDBACK

PERFORMANCE CONTINUATION

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1.2.3.

Clinical applications

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INSTRUCTION

DETAILED JOINT/S MOVEMENT INSTRUCTIONS CAN BE CUSTOMIZED

EXT. EXT. HOLD FLX. FLX. HOLD

Clinical applications

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TIME LINE FEEDBACK

CONCOMITANT FEEDBACK IS PROVIDED ON PAST AND PRESENT PERFORMANCE

PAST FUTUREPRESENT

Clinical applications

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DEVIATION LIMIT CAN BE CUSTOMIZED

FADED FEEDBACK

Clinical applications

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NO EXTRA AUDITORY / VISUAL FEEDBACK IS PROVIDED WHEN IN DEVIATION LIMIT

POSITIVE FEEDBACK

Clinical applications

EXTRA AUDITORY / VISUAL FEEDBACK IS PROVIDED WHEN OUT OF DEVIATION LIMIT

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NEGATIVE FEEDBACK

Clinical applications

QUANTITATIVE INFORMATION IS PROVIDED DURING AND AT THE END OF THE TASK

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QUANTITATIVE FEEDBACK

Clinical applications

QUALITATIVE INFORMATION IS PROVIDED DURING PERFORMANCE

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QUALITATIVE FEEDBACK

Clinical applications

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THE TASK CAN BE REPEATED FOR INTENSIVE PRACTICE

INTENSIVE TASK

CYCLE 1 CYCLE 2

Clinical applications

Repetitive practice

Motor learning

Real feedback

Difficulty levels

SUMMERY

MotivationIntensive practice

Functional practice

SUCCESSFUL

FUNCTIONAL RECOVERY56

Clinical applications

meditouch.co.il

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