1. Electrical Agents:�Electrical Stimulation Techniques Body Circuit
As the % of water in tissue increases, its ability to transmit electricity increases
Tissues are either excitable (directly influenced by stimulation) or nonexcitable
3. Electrical Agents:�Characteristics of Electrical Generators The current enters the body through a series circuit since the skin is relatively consistent
Once in the body it may take many different paths
Current prefers the path of least resistance
4. Electrical Agents:�Electrodes Placement of electrodes is important for athlete comfort and efficiency
Electrodes can be of different materials
In most cases a medium is needed to reduce resistance between the skin and the electrode
Wet sponges
Conducting gels
5. Electrical Agents:�Electrodes Size of electrode inversely affects the density of the current
Electrode size ?= current density ?
This affects comfort and effect of the current
Larger electrodes produce greater contractions, but, not as specific
6. Electrical Agents:�Electrodes Motor points, trigger points, acupuncture points
Closer placement of electrodes vs. electrodes placed farther apart
Closer = superficial
Farther = deeper
Direction of fibers is also important
7. Electrical Agents:�Electrodes Bipolar Technique
2 leads, with equal size electrodes
Monopolar Technique
1 or 2 active electrodes and a dispersive electrode
Dispersive pad must be much larger than active electrodes
8. Electrical Agents:�Electrodes Quadripolar Technique
2 sets of electrodes each from there own channels
Current may intersect with each other
9. Electrical Agents:�Movement of Electrical Current Most forms of electrical stimulation are applied transcutaneously
When passed through the skin it has the potential to upset the resting potential of the axons
Under the cathode = depolarization occurs
Under the anode = hyperpolarization occurs
10. Electrical Agents:�Selected Stimulation of Nerves Nerves response is based on 3 factors:
Relative diameter of the nerve
larger stimulated first
Depth of nerve in relation to electrode
sensory are closer to surface than pain/motor
Duration of the pulse
shorter durations require more current to stimulate a nerve type
11. Electrical Agents:�Selected Stimulation of Nerves Sensory nerves are stimulated first, then motor, then pain.
Pain fibers are located in between sensory and motor fibers, but, are smaller in diameter
12. Electrical Agents:�Selected Stimulation of Nerves Subsensory-level
From zero intensity to point athlete first feels the current
Sensory-level
To point of slight muscle contraction
Motor-level
Visable contraction without pain
Noxious-level
Intensity that stimulates pain fibers
13. Electrical Agents:�Accommodation and Habituation Accommodation
Over time it will take more intensity to cause depolarization of the nerve
Habituation
CNS filters out a continuous, non-meaningful stimulus
This can be seen when an athlete gets use to the current
14. Electrical Agents:�Movement of Electrical Current Medical Galvanism
Application of low voltage DC, with a known polarity under each electrode
Certain cellular and biochemical responses occur due to each polarity
Galvanic stimulation is the only form of current that can elicits a muscle contraction from denervated muscle, but the phase duration is so long it also activates the C fibers
15. Electrical Agents:�Movement of Electrical Current Medical Galvanism (Cont.)
Physiological effects are generally opposite under the cathode or anode
Symmetrical or balanced currents can not have any galvanic effects
Unbalanced asymmetrical current can result in residual chemical changes is current is high enough
16. Electrical Agents:�Electrical Stimulation Goals and Techniques Muscular Contractions
Virtually any electric modality can achieve a contraction at a high enough intensity
Contractions used to:
Retard effects of atrophy
Reeducate muscle
Reduce edema
Electrodes should be placed over motor points
17. Electrical Agents:�Muscle Contractions Muscular Contractions (cont.)
Large nerve closer to electrode are recruited first
If nerve is denervated, then DC or monophasic with a long pulse duration can be used to depolarize the motor unit
18. Electrical Agents:�Muscle Contractions Pulse Amplitude
As intensity increases so does the strength of the contraction
Depth of penetration increases as the peak current increases, thus recruiting more nerve fibers
Pain inhibits maximal contraction of fibers
19. Electrical Agents:�Muscle Contractions Pulse Frequency
Pulse rate of less than 15 pps = twitch contraction
Pulse rate between 15 and 40 pps = summation of stimuli
This will increase to the point of tetany
Further increase in frequency will promote fatigue of the muscle
20. Electrical Agents:�Muscle Contractions Pulse Frequency (cont.)
Strong tetanic contraction is needed to delay atrophy
Low pps decreases fatigue, but, produces less force
High pps are more comfortable
21. Electrical Agents:�Muscle Contractions Phase Duration
To recruit motor units a moderate phase duration should be used
300 to 500 microseconds
Strength Augmentation
Voluntary contractions are better than electrically induced contractions
22. Electrical Agents:�Pain Control Reduce pain by assisting in the healing process or affecting pain transmission
High pulse frequency, short duration, sensory level currents are thought to activate the gate control theory
Low pulse frequency, long duration, high intensity and noxious stimuli are thought to stimulate release of opiates
23. Electrical Agents:�Pain Control During initial phases of pain control, electricity stimulates the dorsal horn of the spinal cord
The placebo effect of electrotherapy can not be overlooked
24. Electrical Agents:�Circulation Electrically induced contractions increase local blood flow the same as voluntary contractions
Sensory level stimulation has not been found to effect blood flow
25. Electrical Agents:�Wound Healing Use of lower intensity DC may reduce the time needed for superficial wound healing by 1.5 to 2.5 times
Depending on the polarity, certain inflammatory mediators can be attracted or repelled from the area
26. Electrical Agents:�Wound Healing What occurs in the body:
Increased circulation
Increased blood clot formation
Antibacterial effects
Influences on migration of cells
Presence of an injury potential (theorized to electrically control tissue repair)
27. Electrical Agents:�Control and Reduction of Edema Sensory-level stimulation
Attempts to stop formation of edema by preventing the fluids, plasma proteins, and other solids from escaping into surrounding tissues
Motor-level stimulation
attempts to assist the venous and lymphatic system in returning the edema substances back to the torso
28. Electrical Agents:�Sensory-Level Stimulation for Edema Control Used in acute trauma to attempt to decrease edema formation
Intensity is kept below motor threshold
Why does it work?
Reduction in capillary pressure and capillary permeability
Produces a vascular spasm and prevents fluid from leaking out of the vessels
29. Electrical Agents:�Motor-Level Stimulation for Edema Control Works by squeezing the vessels and milking the fluids out of the area
Referred to as muscle milking or muscle pump
Use 1 pps or tonic contraction with a 50% duty cycle
Not as good as voluntary contractions
If used limb should be elevated
30. Electrical Agents:�Fracture Healing Electricity has traditionally been used to heal nonunion fractures
Current research is also looking into acute fractures
Theory:
Bone cannot differentiate between the bodys innate charges need for normal bone growth and those from outside sources
31. Electrical Agents:�Fracture Healing Devices are known as bone growth generators
Generally use AC for transcutaneous use and DC for implanted electrodes
Usefulness is debatable
Decrease in bone growth
Time out due to surgical implant & removal
M.D. is the person who prescribes the unit
32. Electrical Agents General Contraindications:
Cardiac disability (Stimulation of thorax or neck may effect respiration or heart)
Pacemakers
Pregnancy
Menstration
33. Electrical Agents General Contraindications: (cont.)
Cancerous lesions
Sites of infections
Exposed metal implants
Severe obesity
Epilepsy
Electronic Monitoring Equipment
34. Electrical Agents Therapeutic Uses for Electricity:
Controlling acute and chronic pain
Reducing edema
Reducing muscle spasm
Reducing joint contractures
Inhibiting muscle spasm
Minimizing disuse atrophy
Facilitating tissue healing
35. Electrical Agents Therapeutic Uses: (cont.)
Facilitating muscle re-education
Facilitating fracture healing
Strengthening muscle
