Cold Pack Procedure PDF

Summary

This document provides a detailed overview of superficial cold and heat therapy. It discusses the different modalities, methods of heat transfer, and learner objectives related to the topic. Relevant terms and procedures are explained in detail, including the concepts of ice massage, cold packs, and others. The document also contains questions related to the topics covered.

Full Transcript

Lect HO\#1 - PTH 121 Unit 3 - Superficial **Cold** and Heat

[Reference:]

Michlovitz: Ch2

Fairchild: Ch3

O'Sullivan: Ch25

**Learner Objectives:**

Upon completion of this unit, including lecture and laboratory
attendance, completion of reading assignments and review of handout
materials, the student will be able to:

A1. Identify the different modalities used for superficial cold and
heat.

A2. Describe the cooling and heating methods of radiation, conduction,
convection, and evaporation.

A3. Characterize each thermal modality according to its method of
cooling or heating.

B1. Discuss the physiological effects, treatment goals, indications,
contraindications, precautions, and treatment procedures for the
following

a. b. Ice massage

c. Cold packs

d. Ice compression pumps (Game Ready, Therm-X)

e. Contrast baths

f. Vapocoolant spray

g. Hot pack

h. Paraffin

i. Fluidotherapy

j. Infrared

B2. Demonstrate safety precautions and knowledge of equipment
maintenance for the modalities noted in

B3. Given a patient scenario, determine and demonstrate the appropriate
application of a thermal modality

(noted in B1 above) based on the criteria on the check-off grading
rubric. (7D15, 7D17, 7D18, 7D19,

7D20, 7D21, 7D23c, 7D23g, 7D23h)

B4. Based on the patient scenario in B3, document a full SOAP note for
the treatment (thermal modality)

C1. Describe the therapeutic use of ultraviolet light in physical
therapy.

C2. Discuss the physiological effects, treatment goals, indications,
contraindications, precautions, and

treatment procedures for ultraviolet light. (7D21)

C3. Given a patient scenario, describe how to determine the MED and
progression of a treatment session.

--------------------------------------
**What are therapeutic modalities?**
--------------------------------------

- Represent the administration of [thermal, mechanical, acoustic,
electromagnetic (includes light) energies] for a
specific therapeutic effect.

Indications: ↓ pain, ↑ range of motion, ↑ tissue
healing or ↑ \*muscle recruitment

recall "motor unit" = a single cell + axon + all fibers it innervates

↑muscle recruitment = ↑ motor unit = ↑ contraction (strength)

-----------------------------------------------
**Types of cooling modalities used in rehab**
-----------------------------------------------

- Ice/Cold packs -- ice cubes or crushed ice in water, (water:
alcohol=3:1)

- Commercial cold pack -- "Coldpac" (\~ -5°C)

- Instant cold packs --one time use, disposable; works with a chemical
reaction

- Ice Compression Pump -- ice/water flowing through tubing to pack
(Cryocuff; Polar Care-circulating water, Game Ready, Therm-X)

- Ice massage -- ice cube/ice cup

- Vapocoolant spray ("Spray & Stretch")

Contrast baths (heat and cold)

------------------------------
**Methods of heat transfer**
------------------------------

1. **Radiation**- (non-thermal and thermal use) Classified according to
the specific frequency of the electromagnetic (EM) wave, therapeutic
EM radiation includes Short Wave Diathermy (SWD), infrared radiation
(IR), and ultraviolet (UVA and UVB) radiation. (Ch 6)

2. **Evaporation**- cooling that occurs when a [liquid] is
transformed into a [gaseous] state (Example: Vapocoolant
sprays such as "Spray and Stretch" (rx needed; penta- and
tetrafluoromethane) "Instant Ice" (rx not needed) are nonflammable,
liquid aerosol skin refrigerants, as the liquid leaves the
pressurized canister, it begins to evaporate. When this transition
occurs, the [stream cools] and extract heat upon contact
with the skin.

3. **Conduction**- transfer of heat by direct interaction of the
molecules in the warmer area with those in the cooler area (Example:
ice or cold pack over an area). Usually medium is solid material
(such as ice pack)

4. **Convection**- heat abstraction occurs when there is direct contact
between the skin and moving fluid particles (Example: cold
whirlpool-water moves over skin via turbines that circulate the
water).

**Quiz:**

1. Which is the faster method of heat transfer? Convection vs
Conduction.

2. In the order of faster -\> slower method of heat transfer?
Conduction, Convection, Radiation.

(Think how do I get warmer the fastest?)

------------------------------------
**Cold Therapy Modalities (Ch 2)**
------------------------------------

- The use of cold to induce therapeutic and
physiological responses that result from a decrease in tissue
temperature.

- Cooling is accomplished by [removing or abstracting
heat] from an object (NOT adding cold).

- Superficial effect: [1-3 cm] depending on temperature
gradient and exposure time. More intense cold & longer exposure
times result in greater decreases in tissue temp & deeper
penetration.

- Most significant cooling occurs [up to 1cm] --
[superficial] structures-nerve endings

- Cooling of muscles and joints only possible when they are located
superficially

- Primary method of heat transfer (heat abstraction/cooling) are
[**conduction** (= direct physical contact)] and
[**convection** (= movement of molecules, air/wind or
water)]

1. "Ice pack over an injured area becomes cooler" = conduction vs
convection

2. "Playing in a pool 77-82 °F, you will be freezing in 30mins" =
conduction vs convection

Note: Cool or cold immersion use [both conduction and
convection] methods for heat transfer.

**Class activity -- state the method(s) of cooling (or *heating*) for
each modality.**

Ice/Cold packs

Commercial cold pack

Instant cold packs

Ice Compression Pump

Ice massage

Vapocoolant spray

Contrast baths (later in HO)

*Hot pack*

*Paraffin*

*Infrared*

*Fluidotherapy*

Factors Influencing Response to Cold Therapy: see **Box 2.1 Michlovitz**

- Temperature difference between cooling object and the soft tissue

- Time of exposure (duration)

- [Thermal conductivity] of area being cooled

- Type and size of cooling agent

- Total body surface area cooled

- Activity level (increased activity → increased circulation → faster
rewarming)

- Ability of cooling agent to maintain its temperature

Trying to verify with NPTE if they use F or C in board exam. (Bean
9/13/24)


OR

F = (9/5 × C) + 32

C = 5/9 (F -- 32)

The rate of heat transfer by conduction:

*D = Area × **k** × (T1 -- T2)/thickness of tissue*

*D is the rate of heat loss (calories/second). Area is the extent of
body surface cooled or heated (cm2), and [k is the thermal conductivity
of tissues] (calories/second/cm2 ×°C/cm2) (Table 2-2), and
T1 and T2 are the temperatures of the warm and cool surfaces (°C).*

- Thicker tissue =\> heat loss (cooling effect) is less vs more?

- Bigger area =\> heat loss (cooling effetct) is less vs more?

A screenshot of a graph Description automatically generated

**Quiz**- Which material is the best agent as a cooling material? (note,
bone and muscle are equal in terms of heat conductivity)

From our text...

"Most clinicians will agree that, in the acute phase (24 to 48 hours),
cold should be the modality of choice and should be administered as soon
as possible after injury. Even though cold may be uncomfortable for the
patient during the first few minutes, pain will ultimately be reduced,
and edema, inflammation, and muscle spasm will most likely be lessened".

Beyond the acute phase of injury, heat may be the agent of choice for
intervention. But in many cases, [cold has been a successful part of a
therapeutic regimen to facilitate muscle contractions],
reduce joint pain caused by arthritis, and [lessen muscle
spasm]. One study demonstrated that the use of [repeated
cold applications in individuals with chronic lateral epicondylitis was
as effective as exercise or exercise plus cold in reducing pain and
improving function]." (p.35)

---------------------------
**Goals of cold therapy**
---------------------------

Limit edema formation

Reduce pain

Facilitate muscle relaxation

Limit secondary hypoxic tissue injury

**Physiological Effects of Tissue Cooling**

Study \#1 in 1946.

Orthopedic surgical procedures (n=824 cases)

Group 1 (n=479): no cooling

Group 2 (n=345): ice bags over their soft casts for a 48-hour period;
replaced every 4 hours

- Group 2 required fewer swelling-related splitting of casts (5.31%)
compared with the non-iced group (41.3%).

- Group 2 had less inflammation and fewer fevers above 101°F (38.3°C)

- No subject in the iced group had apparent hematomas or hemarthrosis.
(vs 16 of those in the group that received no ice)

- Fewer narcotics were administered to those subjects who were treated
with ice, indicating that their pain was less.

Study \#2 for TKA (systematic review)

- No substantial effect on the variables of (blood) transfusion rate,
pain on POD\# 1 and 3, use of analgesics, and length of hospital
stay.

- The addition of cryotherapy had a [significant effect on
postoperative blood loss], [pain on POD\#
2], and ↑ [knee ROM (ext/flex) at dc].

Study \#3 for THA (systematic review)

- Similar results for patients following TKA and THA with [decreased
blood loss] and [decreased pain on postoperative day
2].

Study \#4 for [severe ankle sprain]

- Treatment was continued for a minimum of 3 days for all patients.

- The early cold (within the first 36 hours) returned to full activity
(running and jumping without pain) an average of [8 days
sooner] than those treated with heat (1) or delayed cold
(2).

- The time at which cryotherapy is initiated following trauma can
influence the time course for functional outcome.

-----------------------------------
**Effects of cold to the tissue**
-----------------------------------

1\. Vasoconstriction of superficial blood vessels -\> leads to
[↓] in local blood flow

2\. Cooling of tissue can occur to depths of 1-3 cm (recall most
significant cooling occurs up to 1 cm-superficial structures, nerve
endings)

3\. [↓] elasticity and [ ↑]viscosity of tissues
(reverse of heat)

4\. [↓] metabolic rate

5\. [↓] oxygen demand of tissues

6\. [↓] fluid in interstitial space by affecting cell wall
permeability

7\. [↓] accumulation of metabolites and chemical irritants
thus [ ↓] inflammatory reactions

8\. [↓] nerve conduction velocity and sensitivity of free
nerve endings -- this results in numbness and [ ↓] pain
([increase] pain threshold)

9\. [↓] mm spasm due to pain reduction

10\. [↓] HR and [↓] RR

More to consider...

11\. ↓ Metabolic rate; slows production of metabolites; ↓ oxygen demand
in tissues (\#1 & \#2 = ↓

edema)

12\. ↓Temp within joint - after prolonged exposure - can ↓ activity of
cartilage destroying enzymes

13\. ↓ Nerve conduction velocity, ↓ sensitivity of free nerve endings →
numbness

14\. ↑ Pain threshold

15\. ↓ Ms spindle activity → ↓ Spasticity by decreasing activity of
muscle spindles

16\. ↓ Ability to perform rapid movements - 2° ↑ ms viscosity or ↑
contraction/relaxation times

17\. \* ↓ Force output of muscles following ice.

18\. ↓ inflammatory response - histamine release & cell membrane
permeability

19\. Presence of adipose tissue affects the depth of cold penetration -
insulator

\*\#17 above. Would you perform an intervention (tx) that challenges
pt's muscle force generation after cold was applied? Do you wait longer
to do 1-RM

exercise after cold modality vs heat modality?

Note, when you compare the effect of ice and heat modality- it takes
longer to return to baseline temperature after cold modality than heat
modality. (It takes longer to warm up after ice than cool down after
heat.)

-------------------------------------------------------
**Effects of Cold on Peripheral Nerves- see Box 2.3**
-------------------------------------------------------

1. Increases threshold for depolarization -- think it will be
stimulated, desensitized

2. Slows nerve conduction velocity

3. Extreme cold can block nerve conduction

**Note:** The fibers least sensitive to cold were small-diameter
unmyelinated fibers such as \_\_\_\_fibers.

Cooling to 53.6°F (12°C) blocked conduction in [A] fibers,
while considerably lower temperatures were required to block
[C-fiber] conduction. Think C fibers are too "hot", very
stubborn, to be cooled off.

- If we use ice/CP, we can reduce the impulse from A-delta fibers (aka
pain).

BUT

More importantly, sensory nerves cannot be selectively cooled. If you
cool off one area, then you will be cooling off everything (including
motor nerves). Reduced motor ability should be considered if your
patient will be doing tx AFTER the application of cold modality.

Interesting but rare cases -- young athletes experienced neurapraxia (n=
3) and axonotmesis (n=1)

-------------------------------------------
**Effects of cold on Muscle Performance**
-------------------------------------------


1. ↓ ability of a muscle to general tension

After cold immersion of healthy legs for [30 minutes] at
50°F to 53.6°F (10°C to 12°C), Oliver et al found that muscle
temperature and plantarflexion strength decreased. [At 45 minutes
postimmersion], plantarflexion strength began to increase
over pretreatment values and continued to do so for the next 3 hours.

- Cold can alter muscle force generation, strength assessments on
patients during initial and follow-up examinations should be done
prior to or several hours after cold modality is used. (be
consistent with time -- when to do MMT before/after icing)

- Because muscle performance is negatively affected with [cooling for
10 minutes or longer], caution should be taken if
strenuous exercise or athletic activities are to be performed after
muscular cooling

- Any examination or intervention that challenges balance,
proprioception, accuracy, or agility should be avoided for a period
of time after the application of a cold modality due to the
reduction in somatosensory input that these tasks require.

-------------------------------------------
**Clinical indications for cold therapy**
-------------------------------------------

1\. **Spasticity** - for local treatments only - the rest of body should
be warm.

Spasticity: increased resistance to passive stretch; in increase in deep
tendon reflexes (DTR) [spastic gait](spastic%20gait)

Clonus: spasmodic alteration of contractions between antagonistic muscle
groups because of a hyperactive stretch reflex from an Upper Motor
Neuron lesion. [Ankle clonus](Ankle%20clonus)

2\. **Early acute (1st 12-24 hrs) injury or inflammation** (contusions,
sprains, strains, spasm, etc). Use in conjunction with elevation
([PRICES -- protection, rest, ice, compression, elevation,
stabilization)] **Table 2.5**

3. **Pain and Muscle spasms** - (break up pain-spasm-pain cycle) ROM
*may* ↑ if pain is reduced; cold is a counterirritant and may lessen
pain sensation by stimulating thermal receptors. Analgesia is a
direct effect of therapeutic cold.

**Quiz**: Cooling the skin can elevate an individual's pain threshold
and reduce pain. True or False?

**Quiz**: Cold acts as a counterirritant and stimulation of thermal
receptors in the skin ([A-delta nerve fibers]) may override
pain signals from [C fibers.]

4. Myofascial pain syndrome = "the sensory, motor, and autonomic
symptoms caused by myofascial trigger points." Trigger points are
thought to be present in skin, ligaments, and fascia.

5. **Migraines?** Despite this relatively widespread application for
migraine treatment, there is relatively little evidence supporting
the effectiveness of cold therapy. "a gel cap over the head to
administer a cold, with participants wearing the cap for 25 minutes.
The intervention was effective at decreasing reports of pain,
suggesting that cold therapy alone can improve migraine symptoms."
(p.40)

6. **Minor burns (sunburn)**

7. **Edema - acute** = first 12-24 hours (Michlovitz: Ch2) Use with
elevation. Cold application in combination with compression is more
effective than compression alone for the management of edema.

8. **Hyperthermia** - ↑ body temp 2° fever or overexertion

----------------------------------------------------------
**Clinical contraindication for cold therapy Table 2.7**
----------------------------------------------------------


1. Cold intolerance ("I don't like cold")

2. Cold urticaria (ur-tih-KAR-e-uh) -- (hives Fig. 2.15)

a. Local response: welts (raised, reddened areas).

b. Systemic response: Facial flushing, drop in BP, increase in HR
and syncope. The welts are produced by a rapid release of
histamine brought about by IgE antibodies and a type of white
blood cell (Eosinophil- often involved in allergic reactions) in
response to the cold. Rapid cooling, as from the evaporation
when one gets out of a swimming pool, can trigger cold urticaria
even on a warm day. [For people with cold urticaria, swimming in
very cold water is quite dangerous, sometimes even causing
death.]

3. Raynaud's Phenomenon= decreased blood supply to distal extremities
secondary spasms of arterial smooth muscle- exhibit cycles of
pallor, cyanosis, rubor and normal color in hands and feet in
response to cold.

4. Paroxysmal cold hemoglobinuria- also known as [Donath-Landsteiner
syndrome], is a disease of humans that is characterized
by the sudden presence of hemoglobin in the urine (called
hemoglobinuria), typically after exposure to cold temperatures

5. Cryoglobulinemia (kry-o-glob-u-lih-NEE-me-uh) - a medical condition
in which the blood contains large amounts of cryoglobulins --
proteins (mostly immunoglobulins themselves) that become insoluble
at reduced temperatures.

6. Over [a regenerating peripheral nerve]

7. Over [an area of circulatory compromise]

8. Over [an area of peripheral vascular disease]

**Quiz**: If the patient had a PVD in B feet, can we apply ice on either
UE?

**Precautions: (cont table 2-7, p 43) ["Proceed with
caution!"]**

1. HTN - monitor B/P throughout if pt is hypertensive. Why?

2. Thermoregulatory disorders why? - esp elderly. ↓vasoconstriction & ↓
shivering → decreased ability to conserve or produce heat

3. Over a superficial peripheral nerve. Why?

4. Over an open wound. Why?

5. Over an area of poor sensation. Why?

6. With individuals with poor cognition. Why?

7. In very young or very old. Why?

8. Persons with aversion to cold. Why?

-------------------------------------------------------------------------------------------------------------------------------------
**Effects of Prolonged Exposure to Cold (Adverse Effects)** Systemic response - when local tissues were exposed to cold too long...
-------------------------------------------------------------------------------------------------------------------------------------

1. **[Prolonged]** **[cold]** can
[↑] mm tone as the body shivers to produce heat, can
increase

spasticity

[\*Note, if the cold is used appropriately, it can ↓ spasticity by ↓
muscle spindles activity]

2. [Hunting Response/Lewis Reaction/Hunting Reaction of
Lewis]:

"Cold-induced vasodilation following the initial period of
vasoconstriction, resulting in cyclic periods of vasodilation and
vasoconstriction and in cyclic warming and cooling of the skin of
the face, hands, fingers, feet, and toes." A protective reaction that
is normal. However, it can become a problem if it is a continuous
response.

3. Decrease in tissue temperature to 10° C (50°F) or below may result
in thermal damage to tissues. Thermal damage may trigger an
inflammatory response and result in an increase in edema.

--------------------
**Contrast Baths**
--------------------


**Contrast Baths: (p.155 Michlovitz)**

- Distal extremities are alternately immersed in both warm and cold
baths.

- Alternating between heat and cold water is thought to trigger a
vascular pumping action caused by dilation and construction of the
vessels. -\> [in theory,] stimulate blood flow and
promote healing.

- Little evidence supporting this theory - stimulation of the local
circulation (ie. R foot) and, to a lesser extent, increased
circulation in the opposite untreated extremity (ie. L foot).

- Typical **Heat : Cold baths ratios = 3-4 min : 1 min** (longer in
the warm bath and shorter in cold water)

- Any adverse effects of both heat & cold are less likely to occur
when both heat and cold are used.

- Sensations experienced by the patient usually appear in 7-15 min
(cold, burning, aching, numbness)

Indications: ([more research is needed]**)**

- Impaired venous circulation

- Sub-acute and chronic inflammatory conditions

- Chronic Edema

- Sinus HA= applied to hands/feet & blood is shunted from the head to
the periphery?

- DOMS: A few studies reported improved recovery of isometric force
and dynamic power and a reduction in localized edema. (after LE
exercises)

Contraindications:

- Same as with superficial heat and cold

- Circulatory compromise.

-

cold temps may cause vasospasm & ↓ circulation (worsens arterial
insufficiency)

-

FYI: difference between Venous and Arterial Leg Ulcers.

Precautions:

- Insensate skin

- Elderly and very young (\< 4 yo) 2° unreliable thermoregulatory
systems

Procedure:

- Check skin as with other modalities

- Have the patient go to the bathroom.

- Prepare 2 containers of water, thermometer, towels

- Warm bath: 38-43° C (100-110° F), Cold bath: 13-18° C (55-65° F)

- Repeat until **Rx time is 20 - 30 min example: (4minHOT+1minCold) x
4-cycle= 20mins**

- Tx may end in either warm or cold bath - warm for comfort.

- Dry the area & follow with assessments, exercise.

- While the pt is in 1 bath, you may need to replace the water in the
other to keep the water temp constant.

**Documentation of Superficial Cold and Heat Modalities**

Thorough documentation is needed including modality/method used;
temperature of water; durations of heat/cold phases, area treated;
patient position; start/stop sequence; patient response during and
following treatment.

If you see below (compared to baseline skin check)

-\> Indicate areas of cold injury. If they appear, rewarm the area,
document the occurrence and file an incident report as appropriate for
your facility.