Modalities Ch. 14

Question 1

what is sound

Answer 1

form of vibrational or acoustic energy

sounds travel in waves

Question 2

what sounds can we hear?

Answer 2

16,000 - 20,000 Hz

Question 3

ultrasound

Answer 3

inaudible, acoustic vibrations
high frequency
may produce thermal and/or nonthermal physiologic effects

Question 4

types of ultrasound

Answer 4

diagnostic
-internal structure imaging
-5MHz, 3.4 mW/cm2
surgical
-tissue destruction owing to thermal and mechanical effects
-0.10 MHz, 20-100 W/Cm
therapeutic
-thermal and subthermal effects
-0.75 to 3 MHz,

Question 5

therapeutic ultrasound

Answer 5

advantage over other nonacoustic heating modalities
tissues high in collagen (tendons, muscles, ligaments, joint capsules, meniscus, and cortical bone) can be heated to a therapeutic range

Question 6

anatomy of an ultrasound machine

Answer 6

generator
-where electrical current is generated
applicator
transducer
-converts electrical energy to acoustic energy
-houses the crystal
crystal

Question 7

how does ultrasound work

Answer 7

generator produces a high-frequency alternating current
current travels through the coaxial cable
crystal in the transducer converts electrical energy to sound energy
-reverse piezoelectric effect

Question 8

reverse piezoelectric effect

Answer 8

mechanical energy being produced by electric energy

Question 9

what happens to the crystal

Answer 9

crystal expands and contracts

• rarefaction - crystal expands
• neutral
• compression - crystal has a high molecular density
• neutral
• rarefaction
• etc.

Question 10

attenuation

Answer 10

decrease in energy as ultrasound passes through various tissue layers
Law of Grotthus-Draper
-the more energy that is absorbed by superficial leaves less energy to be absorbed by deeper tissues

Question 11

ultrasound effects on tissue

Answer 11

penetrates through tissues high in water content
-fat
absorbed in tissues high in protein
-muscles
-nerves
refracted at joints
reflects or bounces off bone
-certain degree is absorbed in superficial bone

Question 12

how is tissue heated

Answer 12

ultrasound is absorbed by tissue
causes molecules to rotate and bounce off one another
results in heat or nonthermal effects

Question 13

Effective Radiating Area (ERA)

Answer 13

portion of the sound head that is producing the therapeutic effect

Question 14

ERA determinants

Answer 14

size of sound head
size of crystal
quality of crystal

Question 15

beam nonuniformity ration (BNR)

Answer 15

amount of variable intensity within the ultrasound beam
Ratio = variability:average output intensity
should be as close as possible to 1:1
most manufacturers accept <6:1
8.5 w/cm2 can damage tissue

Question 16

PAMBNR

Answer 16

peak area of the maximum BNR

Question 17

ultrasound parameters

Answer 17

duty factor
frequency
intensity
treatment length
treatment size
application technique

Question 18

duty factor

Answer 18

pulsed or continuous

Question 19

frequency

Answer 19

1 and 3 MHz

Question 20

intensity

Answer 20

power

Question 21

treatment length

Answer 21

depends on treatment goals

Question 22

treatment size

Answer 22

depends on area you are treating and sound head size

Question 23

continuous ultrasound

Answer 23

sound waves are delivered continually at the determined frequency

Question 24

pulsed ultrasound

Answer 24

sound waves are delivered in pulses

Question 25

pulse period

Answer 25

length of entire pulse including the off time

Question 26

pulse duration

Answer 26

length of the on time of the pulse

Question 27

duty cycle ratio

Answer 27

% “on time” (pulse duration) in relation to “pulse period”

Question 28

when do you use pulsed?

Answer 28

when you do not want the therapeutic effects

Question 29

frequency

Answer 29

how many times does the crystal change shape
determines depth of treatment
-3 MHz: surface to 2.5 cm
-1 MHz: 2.5-5 cm

Question 30

power

Answer 30

the total amount of ultrasound energy produced by the generator
measure of pulse width and frequency
measures in watts

Question 31

intensity

Answer 31

the rate at which power is delivered to the tissue
determined by power and ERA
measured in W/cm2
greater intensity = greater rate of heating

Question 32

what should the patient feel?

Answer 32

heat

warming

Question 33

treatment length depends on

Answer 33

goals
size of area to be treated
intensity used
frequency (MHz)

Question 34

rate of heating (per minute)

Answer 34

0.5 intensity (W/cm2) - 0.04 C at 1 MHz and 0.3 C at 3 MHz

Question 35

dose according to goals

Answer 35

subacute inflammation

-

Question 36

thermal effects

Answer 36

increased
-extensibility of collagen fibers
-metabolism
-blood flow
decreased
-muscle stiffness
-pain perception
-muscle spasm
altered nerve conduction velocity

Question 37

thermal effects

-duration determined by

Answer 37

desired tissue temp. increase
frequency
intensity (patient comfort)
duty cycle of ultrasound: continuous

Question 38

nonthermal/mechanical effects

Answer 38

calcium ion influx
cell membrane alteration
attraction of immune cells to the injured area
vascular regeneration
tissue regeneration
wound healing
increased
-histamine release
-phagocytic activity of macrophages
-protein synthesis
-capillary density of ischemic tissue
-fibroblasts

Question 39

mechanical effects

Answer 39

another name for thermal effects
mechanical vibrations occurring at the cellular level owing to
-stable cavitation
-acoustic streaming

Question 40

cavitation

Answer 40

result of the physical forces of the soundwaves on microenvironmental gases within a fluid
compression and rerefaction cause these bubbles to expand and contract
good: stable cavitation (no tissue damage)
bad: unstable or transient cavitation (tissue damage from implosion or collapse of bubbles)

Question 41

stable cavitation

Answer 41

compression and expansion of small gas bubbles in the blood and tissue

• cellular effects
• -increase in cell membrane diffusion
• -increased cellular activity

Question 42

unstable cavitation

-occurs when

Answer 42

intensity is too high
when the soundhead is not moved
from a high BNR

Question 43

acoustic microstreaming

Answer 43

mechanical pressure applied to the sound wave produces unidirectional movement of fluid along and/or around the cell membrane
can alter the cell membrane’s structure and function

Question 44

acoustic microstreaming cellular effects

Answer 44

stimulates protein synthesis
increases capillary density
increases ion flux
stimulates serotonin release
pain control

Question 45

thermal effects

Answer 45

increased
-extensibility of collagen fibers
-metabolism
-blood flow
decreased
-muscle stiffness
-pain perception
-muscle spasm
altered nerve conduction velocity

Question 46

thermal effects

-duration determined by

Answer 46

desired tissue temp. increase
frequency
intensity (patient comfort)
duty cycle of ultrasound: continuous

Question 47

nonthermal/mechanical effects

Answer 47

calcium ion influx
cell membrane alteration
attraction of immune cells to the injured area
vascular regeneration
tissue regeneration
wound healing
increased
-histamine release
-phagocytic activity of macrophages
-protein synthesis
-capillary density of ischemic tissue
-fibroblasts

Question 48

mechanical effects

Answer 48

another name for thermal effects
mechanical vibrations occurring at the cellular level owing to
-stable cavitation
-acoustic streaming

Question 49

cavitation

Answer 49

result of the physical forces of the soundwaves on microenvironmental gases within a fluid
compression and rerefaction cause these bubbles to expand and contract
good: stable cavitation (no tissue damage)
bad: unstable or transient cavitation (tissue damage from implosion or collapse of bubbles)

Question 50

stable cavitation

Answer 50

compression and expansion of small gas bubbles in the blood and tissue

• cellular effects
• -increase in cell membrane diffusion
• -increased cellular activity

Question 51

unstable cavitation

-occurs when

Answer 51

intensity is too high
when the soundhead is not moved
from a high BNR

Question 52

acoustic microstreaming

Answer 52

mechanical pressure applied to the sound wave produces unidirectional movement of fluid along and/or around the cell membrane
can alter the cell membrane’s structure and function

Question 53

acoustic microstreaming cellular effects

Answer 53

stimulates protein synthesis
increases capillary density
increases ion flux
stimulates serotonin release
pain control

Question 54

US indications

Answer 54

soft tissue healing and repair
resolving pitting edema scar tissue and joint contracture
heat and stretch routine
chronic inflammation
bone healing
assessing stress fractures
pain
effects of deep heat

Question 55

low intensity US for bone

Answer 55

unadjustable preset low intensity pulsed US parameters
-1.5 MHz frequently
-20% duty cycle
-0.15 W/cm2
20-30 minutes daily
may or may not work

Question 56

US contraindications

Answer 56

heart disease and pacemakers
pregnant uterus
testes
directly over the heart, eyes, spinal cord, carotid sinus, cervical stellate ganglion, or vagus nerve
directly over areas of absent or diminished sensation

Question 57

more contraindications

Answer 57

malignant tumors or cancerous lesions
over areas of circulatory insufficiency
acute or severe sepsis or local infection
over epiphysis in growing bones (calcium influx)
-females 15.5 years old
-males 17.5 years old
danger of hemorrhage immediately after injury

Question 58

size of the treatment area

Answer 58

should be limited to an area no more than twice the size of the soundhead

Question 59

transducer movement

Answer 59

use slow strokes covering about 4 cm/sec.

• can use back and forth or circular strokes
• keep the faceplate flat on the surface being treated

Question 60

application technique - coupling medium

Answer 60

ultrasound requires a medium or couplant to be placed between the soundhead and the skin so that air does not interfere with transmission of ultrasound
gel: most common
water: water immersion technique over bony prominences
gel pads: over bony prominences

Question 61

immersion technique

Answer 61

used to treat small areas when soundhead cannot lie flat on the tissue surface (bony prominences)
soundhead does not touch tissue, but is held 0.5 cm away from and perpendicular to the target tissues
may need to increase intensity by as much as 50%

Question 62

ultrasound gel pads

Answer 62

small areas
bony prominences
use gel between both soundhead and pad and pad and skin

Question 63

other uses of US

Answer 63

phonophoresis

• ultrasound to increase cell membrane permeability
• facilitates the delivery of medication molecules to precise locations in the body

Question 64

common medications used in phonophoresis

Answer 64

anti-inflammatories
-cortisol
-salicylates
-dexamethasone
analgesics
-lidocaine

Question 65

heat and stretch

Answer 65

heat the area before

• or during stretching
• joint mobilizations
• friction massage

Question 66

stretching window

Answer 66

time period (window of opportunity) of vigorous heating when stressed tissues undergo their greatest extensibility and elongation
tissue heated to 40C will drop to 38C within 5-10 minutes after an ultrasound treatment has terminated

Question 67

guidelines for use

Answer 67

obtain history
determine goal
position patient comfortably
inspect treatment area
obtain appropriate size of the soundhead
determine frequency
set duty cycle
apply couplant
set treatment time
maintain contact
adjust intensity to perception of heat
terminate treatment
assess efficacy
record treatment response and parameters