Fluids / Electrolytes Principles of Homeostasis

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Fluids / Electrolytes Principles of Homeostasis

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Title: Fluids / Electrolytes Principles of Homeostasis

1
Fluids / ElectrolytesPrinciples of Homeostasis

Silver Cross EMSS CME
October 2012 3rd Trimester

2
Our Agenda Today

System news!
Our main topic today Fluids and Electrolytes
CHF vs. COPD a quick but important refresher
(ALS) Strip O the Month PEA/Asystole

3
System News!

Please Press Take! For everything you remove
from the Pyxis, you must press take. 5 IV
catheters, 5 presses. 3 canulas, 3 presses.
Etc. The supply people cant restock the machine
properly otherwise and it leaves your fellow
providers short of supplies.
IDPH fees and online process for license apps and
renewals went into effect September 1st.

4
Body Systems Working Together

Integumentary
Skeletal
Muscular
Lymphatic
Respiratory
Digestive

Nervous
Endocrine
Cardiovascular
Renal / Urinary
Reproductive

5
Body Systems

Parceling out vital functions to several
different organ systems results in
interdependence of all body cells.
No individuals organ systems work in isolation.

6
Necessary Life Functions

Must be able to maintain their boundaries.
Internal environment must remain distinct from
the external environment
Single cell organisms
Human beings

7
Necessary Life Functions

Movement
by muscles and the skeletal system
walking, running, writing
also other movement
blood moved through cardiovascular system
foodstuffs moved through digestive system
urine moved through urinary system
at the cellular level
the ability of cells to move by shortening
(contractility)

8
Necessary Life Functions

Responsiveness
the ability to sense changes (stimulus) in the
environment and respond to them
reflex - like touching a hot stove
carbon dioxide levels and respiratory rate

9
Necessary Life Functions

Digestion
the process of breaking down ingested foodstuffs
to simple molecules that can be absorbed into the
blood.
Nutrient rich blood is then distributed to all
areas of the body
Amoeba
a single celled digestion factory

10
Necessary Life Functions

Metabolism
a broad term that includes all chemical reactions
which occur within body cells
catabolism breaking down
anabolism building up
all catabolism all anabolism equals metabolism

11
Necessary Life Functions

Excretion
the process of removing wastes from the organism
get rid of non-useful substances
toxins

12
Necessary Life Functions

Reproduction
cellular
cell division
Mitosis and meiosis
organism
eggs and sperm

13
Necessary Life Functions

Growth
increase in size of a body part or the organism
usually the result of an increase in the number
of cells
may be due to increased size of existing cells
in any case it is the result constructive
activities occurring at a rate faster than
destructive activities

14
Survival/Physiological Needs

nutrients
oxygen
water
normal body temperature
atmospheric pressure

15
The body has a natural tendency to keep the
internal environment constant.
Temperature Water Sugar Blood
Volume Oxygen Carbon Dioxide Heart
Rate Respiratory rate Blood Pressure
HOMEOSTASIS
16
Homeostasis

Greek for like fixed conditions
Walter Bradford Cannon (1871-1945) established
our basic understanding about the global function
of the adrenal gland/sympathetic nervous system
axis

17
Homeostatic Control Mechanisms

Variable
Receptor/affector
Control center
Brain
Effector

Negative feedback
furnace thermostat
Positive feedback
bleeding
delivery
hormone balance

18
Negative Feedback Loop

A stimulus produces a response that opposes the
original stimulus
Thermostat controls heating/cooling
When the room temperature rises/falls, the
thermostat (control center) triggers an EFFECTOR
response that restores normal temperature
Can be either to warm up or to cool off

19
Brains Negative Feedback Loop

The brain is the control center for regulation of
body temperature
Receptor-sensors in skin/cells of
thermoregulatory center (affector pathway) sense
temperature outside the normal acceptable range

20
Brains Negative Feedback Loop

The brain sends a command, via EFFECTOR pathways
for the skin and sweat glands to react and
balance the heat in the body to regain
homeostasis

21
Positive Feedback Loop

Initial stimulus produces a response that
reinforces a stimulus
EX thermostat wired so when temperature is low,
the heater turns on rather than the air
conditioning
Initial stimulus (decreased heat/temp) causes
response (heater on) and heat stimulus
strengthened instead of cooled

22
Thermoregulation

If the thermoregulation center in the brain is
unable to function, the body would die from
either hyperthermia or hypothermia

23
Homeostatic Control Mechanisms

Antagonist
blocks a physiological response
reverses or opposes
-olytic

Agonist
causes a physiological response
-mimetic

24
FLUIDS
25
Water

Water is an essential medium which forms the
chief environment in which cells live and
function
Transport medium for nutrients, hormones, blood
cells and waste products
Regulates body temperature

26
Some additional quick terminology...
intra
cellular
within
pertaining to cells
extra
vascular
outside of
pertains to vessels
27
Hyper-
Hypo-
high / increased
low / decreased
heme, hema, hemo
blood
-carbia
carbon dioxide
28
WATER

Most abundant substance in the human body
60 of total body weight
Fluid Compartments
Intracellular
Extracellular
intravascular
interstitial

75
25
7.5
17.5
29
Fluid compartments of the body.
30
Intracellular Fluid (ICF)

Basic unit of organ structure
Contains nucleus, mitochondria, endoplasmic
reticulum and lysosomes

31
Extracellular Fluid (ECF)

Water that surrounds the cell/outside the cell
Interstitial fluid bathes cells
Intravascular fluid plasma portion of blood
found in circulatory system/in the vessel.
Plasma carries RBC, WBC, platelets, electrolytes,
hormones, waste, etc.

32
Water Intake

How do we get it into our bodies?
Well of course drinking water and other fluids.
From eating fruits and vegetables
Oxidative metabolism

33
Water Intake

But also by eating foods not typically thought of
as containing a great deal of water
Actual fluids 1640cc/day
Food 750 cc/day
Oxidative metab. 350 cc/day
TOTAL 2,740 cc/day

34
Water Output

All the water excreted from the body as urine but
also
Water excreted including the lungs, skin and
intestines

35
Sources of OUTPUT
How much intake fluid is required?

Urine 1700 cc
GI tract 150 cc
Sweat 150 cc
Vapor in resp. 400 cc 2400 cc

Insensible losses
HOMEOSTASIS
36
Monitoring Water Balance

Daily weight
1 kg (2.2lbs) means a fluid loss or gain of 1
liter of fluid
Takes 3,000 ml of ECF deficit to produce signs of
dehydration (4 of total body wt.)

37
Abnormal decrease in total body water

Insensible losses (saliva, sweating,
respirations)
such as from fever states
Sweating
Internal losses (Third Spacing)
Plasma losses (Burns, surgical drains, fistulae)
Gastrointestinal losses (diarrhea, vomit)
Implies loss of electrolytes (increased metabolic
rate)

38
Signs and Symptoms

Dry mucus membranes
Thirst
Poor skin turgor
Tachycardia
Hypotension
In infants, sunken fontanel, lack of tears, fewer
diaper changes
Dark urine

Orthostatic hypotension
Absence of normal sweating
Hematocrit elevated in pure
dehydration, may be decreased if
actively bleeding
Increased respiratory rate
Confusion, Coma, Death
Decreased urinary output

DEHYDRATION
39
Treatment

ALS/ILS
Get fluid in
IV isotonic solution
Well get to this part later!

DEHYDRATION
40
An excess of total body water

May aggravate Congestive Heart Failure
Chronic overhydration can cause renal failure

The major sign of over-hydration is EDEMA.
OVERHYDRATION
41
Signs and Symptoms

Hypertension may indicate overload
Jugular Vein Distention (JVD)
Tachycardia
Dependent edema / crackles
Hematocrit decreased
Shortness of Breath
Headaches, confusion, coma, seizures

OVERHYDRATION
42
Treatment

GET THE WATER OFF!
How would you do this as a paramedic?
How does the body do this on its own?

OVERHYDRATION
43
Kidney Function

Regulates blood volume/blood pressure
Adjusts volume of H2O lost in urine
Regulates hormones erythropoietin renin release
Regulates concentration of plasma ions of Na,
K, Cl- by controlling amount lost in urine
Controls blood pH by controlling loss of H ions
and HCO3- ions concentrated in urine

44
(No Transcript)
45
Production of Urine

Blood flows through the glomerulus
Glomerular pressure pushes fluid out of the
glomerular capillaries and into the Bowmans
capsule at the rate of 180 L / day
Peritubular capillaries reabsorb water, glucose,
sodium and other nutrients and put it back in the
general circulation
Peritubular capillaries also secrete hydrogen
ions, potassium ions and ammonia

46
Urine Regulation

Aldosterone
ADH
Atrial natiuretic factor hormone
Prostaglandins and kinins

47
Aldosterone

hormone secreted by the adrenal gland
stimulates tubules to reabsorb sodium salts to
attract and hold water

48
ANTIDIURETIC HORMONE (ADH)

Secreted in the posterior pituitary gland
osomoreceptors are stimulated by an increase in
the osmolality of body fluids
atrial receptors are stimulated by a fall in
venous blood volume
makes distal and collecting tubules permeable to
water, thus increasing water reabsorption
water is therefore retained in the presence of ADH

49
Increased ADH production

high plasma osmolality compared to interstitial
fluid
low circulating volume sensed by baroreceptors
stimulation of sympathetic nervous system
Drugs-- morphine, oxytocin, diabinase
head injuries, meningitis - syndrome of
inappropriate ADH Secretion

50
Decreased ADH production

Decreased production of ADH results from--
Decreased plasma osmolatity
Increased circulating volume
Alcohol consumption
Caffeine
Cold

51
Atrial Natiuretic Factor/PeptideANP

Secreted from cells in the right atrium of the
heart when pressure in the right atrium increases
ANF inhibits ADH secretion and reduces the
ability of the kidney to concentrate urine

52
Prostaglandins Kinins

Formed in the kidneys
Promote vasoconstriction and increased capillary
permeability
Part of the inflammatory process
Influence the rate of filtrate formation and
sodium ion reabsorption

53
Cant you make it any easier?

Kidneys have two options--
Retain water, put it back in the intravascular
space.
-or-
Dump (water) urine into the urinary bladder

54
Administration of Diuretic Therapy

Furosemide (Lasix)
inhibits sodium and chloride reabsorption by the
loop of Henle
also causes venous dilation
used primarily for acute pulmonary edema CHF

55
Furosemide (Lasix)

Contraindicated in pregnancy
Precautions
dehydration
electrolyte depletion (hypo-kalemia)
contributing to digitalis toxicity
Side effects
hypotension
ECG changes
chest pain
electrolyte deficiencies
Dosage
20-40 mg IVP (at medical control discretion)

56
ELECTROLYTES

Related to 5 physiologic processes
Water distribution
Osmotic pressure
Neuromuscular activity
Acid/Base Balance
Support of cellular metabolism

57
Electrolytes

Chemical substances (ions) that dissociate
charged particles when placed in water and are
usually measured in milliequivalents (mEq/L).

58
ELECTROLYTES

The Endocrine system and the kidneys are the
primary way of regulating fluids and
electrolytes.
Osmoreceptors in the hypothalamus monitor fluid
concentrations.
Hypothalamus secretes ADH
ADH stored in the Posterior pituitary gland
Kidneys release Renin which in turn controls
release of Aldosterone
Aldosterone helps controls pH, electrolyte and
fluid balance

59
ELECTROLYTES
Anions have a negative charge
Cations have a positive charge
60
ESSENTIAL CATIONS

SODIUM (Na)
Prevalent in the extracellular fluid
Normal range is 135-145 mEq/L
Helps regulate distribution of water
Helps transmit nerve impulses

Na
Na
Na
Na
Na
Na
Na
Na
Na
Na
Na
Na
Cell
Na
Na
Na
Na
Na
Na
Na
Na
Na
Na
Na
61
Sodium (Na)

Changes in concentration stimulate pituitary
gland to secrete or withhold ADH
Electrolyte of ventricular depolarization

62
Sodium (Na)

Kidneys are the chief regulator of Na
Moves rapidly between vascular and interstitial
spaces
Rapid movement of water (in and out of cell)
causes concentration of Na to change quickly,
even though Na does not cross cell wall
membranes easily

63
Hyponatremia

Water retention
ECF becomes hypotonic to the cell and water
shifts into ICF. This causes ? blood volume and a
large portion of the body fluid in the cell
pitting edema
Osmolality ? r/t ? Na resulting in fluid
(osmosis) movement from ECF to ICF

64
Hyponatremia

vomiting and diarrhea
3rd space losses of ECF from peritonitis,
ascites, ileus
CHF, peripheral edema
Excessive use of oral water intake
When crackles/rales are present volume is ? at
least 1500 ml from normal

65
Hyponatremia

Signs and symptoms
Mental confusion, delusions
? blood volume, ? BP, tachycardia
Muscle weakness, abdominal cramping
Flat neck veins
Flushed skin, increased body temperature
Headache
Dry mucous membranes

66
Hyponatremia

Treatment
IV normal saline (isotonic) for dehydration
Diuretics for CHF with Na deficit
What are some of the common diuretics patients
take?

67
Hypernatremia

Sodium excess, water loss without salt loss
What happens?
ECF becomes hypertonic and water shifts from ICF
to ECF until equal

68
Hypernatremia

Decreased intake of fluids, especially in hot
weather
Febrile states, increased sweating
Copious watery diarrhea
Salt H2O retention related to inability to
excrete Na r/t starvation, severe illness,
dehydration

69
Hypernatremia

Sodium reabsorption from steroid use
? capillary permeability during inflammation or
allergic process
? plasma proteins in nephrosis or cirrhosis or
from renal failure

70
Hypernatremia

Results from burns, excessive sweating and DKA
(diabetic ketoacidosis/hyperglycemia
Hypothyroidism, Cushings Syndrome and toxemia
during pregnancy

71
Hypernatremia

Drugs that ? Na levels
Diuretics
Heparin
NSAIDS
antidepressants

Drugs that ? Na levels
Steroids
Antibiotics
Cough meds
Laxatives
Oral contraceptives

72
Hypernatremia

Treatment
Sodium restriction
diuretics

73
ESSENTIAL CATIONS

Potassium (K)
Prevalent in the intracellular fluid (ICF)
Key role in the transmission of electrical
impulses/cell excitability

Extracellular
Intracellular
K
K
Na
Na
K
K
K
K
74
Potassium (K)

Normal range 3.5 5.2 mEq/L
Renal failure causes K to not be flushed out
normally causing toxicity
K continually moves in and out of cells
Entrance into cell depends on normal metabolism
and utilization of glucose

75
Hyperkalemia

Renal failure, burns
Tissue trauma, massive crush injuries
Excessive K intake
Respiratory/metabolic acidosis
When tubules excrete H ions to ? pH levels, K
accumulates in the blood

76
Hyperkalemia

Signs/symptoms
Muscle weakness, irritability
Nausea, diarrhea
Intestinal colic, muscle cramp pain
EKG changes
Wide QRS, peaked T wave, depressed S-T segments,
no P wave, cardiac arrest/asystole

77
Hyperkalemia

Treatment
Elimination of K intake
IV infusion of normal saline in large volume
CaCl- IV to antagonize K affects on myocardium
Glucose and insulin to drive K into cells

78
Hypokalemia

K deficit caused by excessive loss of K
Metabolic alkalosis
Diuretic therapy
Acute alcoholism
Uncontrolled diabetes
Excessive perspiration

79
Hypokalemia

Signs/symptoms
Apathy, lethargy, muscle weakness
Tachycardia
Abdominal distention/gas
Weak pulse
DIB, shallow respirations
Metal depression
EKG flat T wave, depressed ST segment, VF

80
Hypokalemia

Treatment
KCl- (potassium chloride)
IV lactated ringers

81
Potassium (K)

Drugs that ? levels
Diuretics
Laxatives
ASA

Drugs that ? levels
Heparin
Epinephrine
Mannitol
Histamines

82
ESSENTIAL CATIONS

Calcium (Ca)
Plays major role in muscle contraction
Plays major role in nerve impulse transmission
Assists with Na and K crossing cell membrane

Extracellular
K
Na
Ca
Intracellular
83
Calcium Ca

Normal range 9.0-10.5 mg/dl
Helps to coagulate blood
Maintains normal heart depolarization of the SA
and AV nodes
Maintains plasma membrane permeability

84
Calcium (Ca)

Gate to allow Na to enter into cell for
depolarization (contraction) to occur. Increased
levels of Ca block this gate, leading to
decreased cell permeability and depressed
peripheral nervous system

85
Calcium (Ca)

Regulated in the bone, intestine and kidney
Parathyroid hormone (PTH) and vitamin D maintains
levels of Ca. PTH is released in response to
low Ca and renal tubules and intestine reabsorb
Ca through Vitamin D

86
Hypercalcemia

Increased Ca absorption
Prevention of renal excretion
Hypercalcemia which decreases cell membrane
permeability resulting in decreased
neuro-muscular excitability

87
Hypercalcemia

Renal disease
Excessive ingestion of milk or Vit. D
Prolonged immobilization bed rest
Bone cancer (Ca is released from the bone in
large amounts)
hyperthyroidism

88
Hypercalcemia

Signs and symptoms
Fatigue, depression

89
Hypocalcemia

Massive infections, peritonitis, pancreatitis
Chronic renal failure
Burns
Hypothyroidism

90
Hypocalcemia

Signs/symptoms
Muscle cramps
Muscular excitability, twitching, tetany
Signs of malnutrition, chronic alcoholism
Anxiety
Increased GI motility (N,V,D)
Laryngeal spasms, hypoxia
EKG prolonged QT interval
Decreased BP
Hyperventilation, increased respirations

91
Testing for Hypocalcemia

Just for fun, dont try this!!
Trousseaus Sign Place BP cuff on arm and
inflate to exceed systolic pressure for 3
minutes. Note carpal spasm with contraction of
thumb and fingers. Note inability to open the
hand.
Hyperexcitaility is due to decreased Ca that is
enhanced by the ischemia
THIS IS ONLY A POTENTIAL TEST.DO NOT DO THIS IN
THE FIELD

92
Hypocalcemia

Treatment
IV fluids, normal saline
Calcium gluconate, CaCl- or Vitamin D
To reverse hyperventilation (alkalosis), have
patient rebreathe CO2

93
ESSENTIAL CATIONS

Magnesium (Mg)
Necessary for
several biochemical processes, neuromuscular
transmission/excitability, metabolism of carbs
and proteins

94
Magnesium (Mg)

Normal range 1.2 2.0 mEq/L
Intracellular cation that is bound to ATP energy
and found mostly in bone (67) and muscle (20)
Modifies enzyme activity
Found in legumes, grains, green veggies, meat
seafood

95
Magnesium (Mg)

Essential for glycolysis which is necessary for
ATP production
Activates the Na/K ATPase pump
More on this in cardiology!!

96
Magnesium (Mg)

Therapeutic effects
Bronchodilating properties for acute asthma
Stops seizure activity in eclampsia
Treat alcoholism withdrawal
Treats tachycardia in digoxin toxicity
Acute MI for increased resuscitation outcome
(pts generally have low levels)

97
Hypermagnesemia

Very rare
Chronic renal failure
Laxative/cathartic abuse
Antacids, maalox, pepto, milk of magnesia

98
Hypermagnesemia

Signs/symptoms
Respiratory depression
Lethargy, confusion,
GI r/t nausea and vomiting
Uncontrolled diabetes
EKG short QT interval, prolonged PR and QRS
intervals, bradycardia and heart blocks

99
Hypermagnesemia

Treatment
Control diabetes and GI loss
Treat cardiac dysrhythmias
Administer Ca
dialysis

100
Hypomagnesemia

Decreased dietary intake, alcoholism
Fistulas
GI disorders
AMI, post CABG
DKA due to diuresis
Decreased K

101
Hypomagnesemia

Signs/symptoms
Weakness, irritability
Tremors, tetany
Vertigo, seizures
HTN, hx of AMI
Increased systemic vascular resistance
(tachycardia)
Insulin resistance

102
Hypomagnesemia

Treatment
Administer Magnesium Sulfate (MgSO4)

103
Magnesium

Drugs that ? levels
Antacids
Thyroid meds
Antibiotics
diuretics

Drugs that ? levels
Insulin
antibiotics

104
ESSENTIAL ANIONS

Chloride (Cl-)
Balances the positive charge associated with the
cations
Plays major role in fluid balance and renal
function by maintaining osmotic pressure
Close association with sodium

105
Chloride (Cl-)

Normal range 90-110 mEq/L
Extracellular anion
Combines with H ions to produce hydrochloric
acid to aid in acid/base balance

106
Hyperchloremia

Dehydration
Eclampsia
Metabolic acidosis, respiratory alkalosis
hyperthyroidism

107
Hyperchloremia

Signs/symptoms
Lethargy, weakness
Deep respirations
Kussmauls respirations
Decreased cognition

108
Hypochloremia

Overdhydration
CHF
Burns
Metabolic alkalosis, respiratory acidosis
burns

109
Hypochloremia

Signs/symptoms
Shallow respirations
Decreased BP
Tetany, hyperexcitability

110
Chloride

Drugs that ? levels
Cortisone
Estrogen
Anti-inflammatory

Drugs that ? levels
Bicarbonate
diuretics

111
ESSENTIAL ANIONS

Bicarbonate (HCO3- )
Principle Ion of the Buffering System
Controlling pH levels of the body
ECF

112
Bicarbonate (HCO-3)

Normal range 135-145 mEq/L
Intracellular
Renal component of acid/base balance
Binds H ions to form carbonic acid in the
process of buffering metabolic acidosis caused by
anaerobic metabolism and lactic acid production

113
Bicarbonate

Carbonic acid rapidly crosses into cells causing
a worsening of intracellular hypercarbia (too
much carbon) and acidosis which depresses
myocardial and cerebral function
Bicarbonate crosses into cells more slowly

114
Sodium Bicarbonate

Medical indications for NaHCO3
Late in cardiac arrest after defib, CPR, ET,
oxygenation/ventilation and at least 2
administrations of epinephrine
Overdose with tricyclic antidepressants (binds
Na channels)
Alkalinize urine in drug overdoses

115
Sodium Bicarbonate

Effects of administration
Fluid retention (cardiovascular)
Tissue necrosis at IV site (skin)
Can cause metabolic alkalosis (electrolyte)

116
Sodium Bicarbonate

IMPORTANT NOTE
Do not mix NaHCO3- with calcium agents as it will
precipitate
Monitor for fluid overload
Crackles
Pink, frothy sputum
Peripheral edema

117
Fluid and Electrolyte Imbalance

There comes a point where the body (especially
the kidney) can no longer maintain
interrelationships of fluids and electrolytes
essential to normal function resulting in
imbalance
Your job is to prevent further imbalance by
recognizing the s/s AND knowing what therapy to
administer

118
Problems with Fluids and Electrolytes

Result from
Volume disturbance (too much/too little)
Irregularities in transportation of fluid (CHF,
shock)
Ratio of fluid and electrolytes imbalanced
(acidosis, alkalosis)
Shifts of fluid to the wrong places
(edema/ascites)

119
SEMIPERMEABLE MEMBRANES

Cell membrane which allows passage of certain
substances and restricts the passage of others.
Allows
Oxygen, Carbon Dioxide, Water
Restricts
Proteins, Glucose

120
Only capillaries have walls thin enough to let
solutes pass through.
121
Colloids vs. Crystalloids

Colloids
Contains proteins or high molecular weight
(large) molecules
salt-poor albumin, dextran
Crystalloids
Primary compounds used in pre-hospital
Lactated Ringers, Normal Saline, D5W

122
COLLOID SOLUTIONS

Advantages
Requires less solution to replace vascular volume
Maintains colloid oncotic pressures
Effective as volume expanders

Disadvantages
More expensive
Pulmonary complications
Allergic reactions
Interference with platelet function
Renal complications

123
CRYSTALLOIDS

Advantages
Inexpensive
Readily available
Causes no allergic reactions
No infectious disease transmission
Effective volume expanders
Cleared by lymphatics

Disadvantages
Need large amounts of solution to replace
vascular volume
3 to 1 ratio -adult
20 cc/kg peds

124
Were going to be especially interested in three
spaces.
Where do we put fluid?
Intracellular space
Interstitial space
Intravascular space
Via intravenous catheters
125
TONICITY
(Concentration of molecules)

ISO Same
Hyper More
Hypo Less

tonic
Number of molecules
tonic
tonic
126
Tonicity

The degree of concentration (osmolarity) of a
solution depends on the amount of solutes
(particles) dissolved in water
Tonicity controls movement of water across the
membrane

127
Tonicity
Cell
Interstitial
128
Isotonic (Iso means same right?)
Cell
Interstitial
129
TONICITY

HYPERTONIC -- A state where a solution has a
higher solute concentration on one side of a
semipermeable membrane compared to the other side.

Cell
Interstitial
Intravascular
130
Cell
Interstitial
131
TONICITY

HYPOTONIC -- A state where a solution has a lower
solute concentration on one side of a
semipermeable membrane compared to the other side.

Cell
Interstitial
Intravascular
132
Cell
Interstitial
133
Hypotonic Hypertonic
Cell
Interstitial
134
What is the tonicity of these?
Cell
Interstitial
135
?
?
Cell
Interstitial
136
Water and Electrolyte Distribution

One of the forces that govern the movement of
water/electrolytes is passive transport
Passive transport moves substances down their
concentration gradient through the appropriate
transport proteins

137
Passive Transport

Osmosis
Diffusion
Facilitated Diffusion
PASSIVE TRANSPORT MEANS NO ATP ENERGY IS
REQUIRED FOR MOVEMENT
Ex fish that swim with the current

138
OSMOSIS The movement of water across a
semipermeable membrane from an area of relatively
lower solute concentration to an area of
relatively higher solute concentration.
Cell
Interstitial
139
Osmosis

Water moves along the concentration gradient from
an area of low solute concentration to an area of
high solute concentration to achieve equilibrium
The force that makes the water move is called the
osmotic pressure

140
Osmosis
141
Osmotic Pressure

The amount of pressure required to stop osmosis
and water moving across the semipermeable membrane

142
Osmosis

How are patients affected by osmosis?
Increased ICP due to cerebral edema
Give manitol as a hypertonic solution as the
particles will pull water
Diabetic ketoacidosis (DKA)
Increased glucose make plasma hypertonic to
interstitial fluid
Fluid moves from interstitial space to vascular
space

143
Osmosis

How are patients affected by osmosis?
Can experience dehydration acidosis
Give infusions of normal saline (isotonic) to
dilute the plasma and rehydrate interstitial
compartment

144
DIFFUSION The movement of solutes across a
semipermeable membrane from an area of relatively
greater solute concentration to an area of
relatively lower solute concentration.
Cell
Interstitial
145
Diffusion

Spontaneous process that distributes molecules
Molecules continually are in motion and collide.
The collisions cause molecules to change
direction and spread out until they are uniformly
distributed

146
Diffusion

Move down the concentration gradient because they
diffuse from regions of higher concentration to
lower concentration
Solutes move more slowly than water
Ex O2 and CO2 in the lungs

147
And now for something Completely Different!

Lets take a few minute break, then come back.

148
CHF vs. COPD

We are seeing a lot of this in narratives lately
Patient exhibiting difficulty breathing with
wheezes. Patient given Albuterol via nebulizer,
no change in condition.

149
CHF vs. COPD

Then as we read further, we see information like
this
Patients BP 160/100. Patient hx CHF/pulmonary
edema/left-side heart failure. Patient EKG
atrial fibrillation. Patient meds lasix,
Cardizem, coumadin.

150
RED FLAGS!!!

History of CHF/pulmonary edema and/or afib
High blood pressure
Trouble breathing
Noisy lungs

151
Consider CHF!

Red flags indicate high suspicion for CHF, NOT
COPD
Nebulized albuterol is not going to help.
Will just raise heart rate and work heart further
Might help a tiny bit if the patient has
co-morbid COPD or asthma, but not much
You can always throw an in-line neb on the CPAP
if you suspect a bit of COPD too.

152
But remember CHF is not a respiratory issue

Congestive heart failure and pulmonary edema are
cardiac issues.
Need a cardiac solution
Your go-tos
CPAP
Nitro
Lasix and Morphine with medical control approval
CPAP and nitro are miracle-workers in CHF!

153
Then why do we hear wheezing?

In the field, occasionally hard to differentiate
between wheezes and crackles/rales.
Wheezes are musical
More common during expiratory phase
Crackles, well, crackle (and pop and click and
bubble)
More common during inspiratory phase

154
Online!

If you have a moment, Google lung sounds. Its a
great way to learn the difference!
An example of a good lung sound site
http//www.stethographics.com/main/physiology_ls_i
ntroduction.html

155
Strip O the Month

Asystole/PEA

156
Asystole (Cardiac Standstill)

Asystole is a total absence of ventricular
electrical activity
There is no ventricular rate or rhythm, no pulse,
and no cardiac output
Some atrial electrical activity may be evident
P-wave asystole

157
Asystole ECG Characteristics
158
Asystole Causes

Pulmonary embolism
Acidosis
Tension pneumothorax
Cardiac tamponade
Hypovolemia
Hypoxia
Heat/cold (hypothermia/hyperthermia)
Hypokalemia/hyperkalemia (and other electrolytes)
Myocardial infarction
Drug overdose/accidents (cyclic antidepressants,
calcium channel blockers, beta-blockers, digoxin)

PATCH-4-MD
PATCH-4 MD
159
Asystole Intervention

Confirm the absence of a pulse
Perform immediate CPR
Confirm the rhythm in two leads
Consider possible causes of the rhythm
Pharm Epinephrine 110,000 1mg IV/IO
No More Atropine!!!

160
Pulseless Electrical Activity (PEA)

Pulseless electrical activity is a clinical
situation, not a specific dysrhythmia
Formerly called electromechanical dissociation
(EMD)

161
Pulseless Electrical Activity

PEA exists when organized electrical activity
(other than VT) is present on the cardiac
monitor, but the patient is pulseless

162
PEA Causes

Pulmonary embolism
Acidosis
Tension pneumothorax
Cardiac tamponade
Hypovolemia (most common cause)
Hypoxia
Heat/cold (hypothermia/hyperthermia)
Hypokalemia/hyperkalemia (and other electrolytes)
Myocardial infarction
Drug overdose/accidents (cyclic antidepressants,
calcium channel blockers, beta-blockers, digoxin)

PATCH-4-MD
163
PEA Intervention