CNUR 203 Introductory Lecture: General Assessments & Fluid Balance PDF

Summary

This document is an introductory lecture for CNUR 203 on general assessments and fluid balance. It covers topics including vital signs, pain assessment, health history, and fluid and electrolyte imbalances, as well as intravenous fluids. The lecture details the process of a general survey and systems assessment, along with important concepts like fluid compartments, fluid shifts, and IV solutions.

Full Transcript

CNUR 203
INTRODUCTORY LECTURE: GENERAL ASSESSMENTS AND FLUID BALANCE
INTRODUCTION OBJECTIVES

 Demonstrate proper assessment techniques and vital signs techniques (Review Powerpoint
& in Lab)
 Demonstrate the ability to perform a pain assessment (Review Powerpoint & in Lab)
 Understand the pathological processes, risks and complications for a patient with fluid and
electrolyte, and acid-base imbalances.
 Identify problems and prioritize nursing interventions for a patient with fluid and electrolyte
imbalances.
 Understand the different types and uses of intravenous fluid replacement therapy.
 Interpret and analyze abnormal lab values.
 Understand the basic concepts of Anemia
 60 SECOND ASSESSMENT
HEAD TO TOE
NEEDS TO BE PAIN ASSESSMENT
SYSTEMATIC
HEALTH HISTORY
AND
ORGANIZED VITAL SIGNS
SYSTEMS ASSESSMENT
LAB VALUES
 What is included in a general survey?
 Physical appearance
 age, sex, LOC, skin colour, facial
features
 Body structure

GENERAL  stature, nutrition, symmetry,
posture, position, body build,
contour
SURVEY  Mobility
 Gait, range of motion
 Behaviour
 Facial expression, mood and
affect, speech, dress, personal
hygiene
SUBJECTIVE DATA VERSUS OBJECTIVE DATA

 Subjective Data  What YOU observe… assessment using your
senses
 They say it
 Systems assessment
 What the client tells you
 Lab values
 Health history
 Imaging reports

 Objective Data
HEALTH HISTORY

 Biographical data
 Reason for seeking care
 Present health or history of present illness
 Past health history (childhood illnesses, accidents or injuries, serious or chronic
illnesses, hospitalizations, operations, obstetrical history, immunizations, last
examination date, allergies, current medications, health of immediate relations)
 Review of systems
 Self-care abilities
 Activities of daily living
HEALTH HISTORY: PAIN ASSESSMENT

**In addition to the Health history data , also include a detailed pain
assessment**
Review Chapter 11 in Jarvis

Two types of Pain:
1. Nociceptive – caused by damage tissue
2. Neuropathic – nerve pain caused by associated conditions
HEALTH HISTORY: PAIN ASSESSMENT (OPQRSTUV)

Jarvis Pg 188
 Onset
 Provocation/palliation
 Quality
 Radiation
 Severity
 Treatment/timing
 Understanding of pain
 Value
HEALTH HISTORY: PAIN ASSESSMENT

 The BEST indication of how much pain the client is in is – What the
client TELLS you!

 PAIN is Subjective

 Once you have completed a subjective assessment of pain, you can
also look at other non-verbal/objective factors…
NON-VERBAL PAIN ASSESSMENT

 Cardiac  GU
 Tachycardia, elevated BP,  Urinary retention, Spasm
increased CO  MSK
 Respiratory  joint Stiffness
 Hypoventilation, Hypoxia  Immune
 GI  Impaired wound healing
 Nausea, Vomiting, Ileus
PACSLAC
VITAL SIGNS

 Once you have completed a general  SpO2
survey  How to take Vital signs was taught in
and a health history, including a pain year 1- please review your notes.
assessment…
 Do a set of Vital signs:
 Additional review is available in Jarvis
 Temperature on pages 158-175
 Pulse
 Blood pressure
 Respiratory rate
ALTERATIONS IN VITAL SIGNS

 Understanding how to interpret vital signs is a crucial component of
a thorough assessment

 Ensure you are familiar with the normal parameters, and what
actions to take if vital signs are abnormal.
ALTERATIONS IN VITAL SIGNS: TEMPERATURE

Oral:
35.8 – 37.3 ° C
Axillary:
0.6 C lower than oral
Rectal:
0.4 – 0.5 higher than oral
Tympanic Terms:
Febrile or Afebrile
+/- 0.2 to oral Temp 38.1: Mrs. N
is..........
ALTERATIONS IN VITAL SIGNS: TEMPERATURE-
ALGORITHM

Asses The Please note: Infection
s Environment Geriatric clients Dehydration
Anesthesia may not show Blood transfusion
Cold fluids/ ice an elevation. reaction
False reading
Do Recheck No action Stop Blood
reading needed transfusion
Notify RN Notify RN
WHAT ARE THE FOUR TYPES OF ASSESSMENT
TECHNIQUES THAT NURSES USE TO EXAMINE A CLIENT?

 Inspection
 Palpation
 Percussion
 Auscultation
Fluids and Electrolytes
FLUID, ELECTROLYTE AND ACID-BASE IMBALANCES
 Fluids and electrolytes are important to the maintenance of
homeostasis – the state of equilibrium maintained within the
internal environment of the body.
 The body produces many acids during normal metabolism, altering
the internal environment and must be regulated to maintain
homeostasis.
 Many diseases, or treatments for disease, alter fluid and electrolytes
or acid-base balance.
 Nurses play a role in recognition of risks for, or signs and symptoms
of imbalances. They can then intervene with appropriate actions.
WATER PERCENTAGE OF THE BODY WEIGHT IN DIFFERENT
LIFE STAGES
REVIEW

 Water accounts for approximately 60% of adult body weight.

 On average we have 40 liters of body fluid (40,000 ml)

(42 liters in a 70 kg man)
 Two major fluid compartments are:
 Intracellular – (inside the cells) approximately 2/3 of total water (approximately 25 liters or 40% of
weight)
 Extracellular (outside the cells) consists of primarily interstitial fluid and intravascular fluid (plasma)
(20% of weight)
 It is important to remember that these amounts may change with age, gender, and body size
FLUID BALANCE

 Under normal circumstances, the kidney can adjust water and electrolyte
excretion to maintain fluid homeostasis.
 Osmolality
 Is the concentration of solutes per weight of water.
 Affects cells by playing a key role in fluid balance.
 Is used to evaluate concentration of solutes for plasma, urine and body fluids
 Sodium, glucose and urea are key ingredients for osmolality calculation
 Urine osmolality.
 Serum osmolality
FLUID GAIN AND LOSS

 One liter of fluid weighs 1 kg
 Body weight change is an excellent indicator of overall volume loss or gain
 Examples-
 A patient who is fasting for surgery could lose 0.5 to 1 kg per day
 A patient receiving a diuretic drug (therapeutic action is to increase urine production) who loses 2
kg in two days has experienced a fluid loss of 2 liters.
 Doctors often order daily weights to help determine fluid balance
 Fluid loss of 20% can be fatal and a fluid loss of 10% is dangerous
 MOVEMENT OF FLUID IN THE BODY

 Osmosis – movement of water between two compartments separated by a semipermeable
membrane – (water moves but not solute)
 Diffusion – movement of molecules from an area of high to low concentration. Examples
include gases (oxygen, C02) and urea (main product of protein metabolism)
 Hydrostatic pressure – force within a fluid compartment. E.g in blood vessels it is the blood
pressure generated by contraction of the heart
 Oncotic pressure – osmotic pressure exerted by colloids in solution. Major colloid in the
vascular system is protein (albumin). Protein molecules pull fluid from tissue space into
vascular space.
ELEMENTS CARRIED BETWEEN BLOOD AND CELLS

 Oxygen and carbon dioxide
 Nutrients and cell waste products
 Electrolytes (K+, Na++, etc.)
FLUID MOVEMENT

 Fluid normally moves between capillaries and the interstitial space. This water or body
fluid is the vehicle by which electrolytes and nutrients are transported into and out of cells.
 Capillary hydrostatic pressure, plasma oncotic pressure, interstitial hydrostatic pressure,
and interstitial oncotic pressure determine the amount and interaction of movement
 If capillary or interstitial pressures are altered fluid shifts occur resulting in edema or
dehydration.
REGULATION OF FLUID BALANCE

 Hypothalamic regulation
 Pituitary regulation
 Adrenal cortical regulation
 Renal regulation
 Cardiac regulation
 Gastro-Intestinal regulation
 Insensible water loss
FLUID SPACING
 Term used to describe the distribution of fluids in the body
 First spacing is normal distribution between ICF and ECF
compartments
 Second spacing is an abnormal accumulation of interstitial fluid
(edema)
 Third spacing occurs when fluid is accumulated, trapped, and
unavailable for functional use. Examples are fluid in the abdomen
associated with peritonitis or edema associated with burns, trauma,
or sepsis.
FLUID SHIFTS: PLASMA TO INTERSTITIAL FLUID

 Increasing venous hydrostatic pressure inhibits fluid movement back into the capillary.
Causes include fluid overload, heart or liver failure, obstruction of venous return to the
heart by tourniquets, blood clots, or restrictive clothing or venous insufficiency.
 Decrease in plasma oncotic pressure occurs when plasma protein content is low. This
occurs in burns, malnutrition, liver disease and renal disease
 Elevation of interstitial oncotic pressure occurs with damage to capillary walls. This can
occur with inflammation, burns, and trauma.
 Increased capillary permeability caused by allergies, inflammation or burns cause both
water and solutes to move out into the tissues.
 Lymph obstruction causes fluid and protein to be retained in interstitial spaces.
FLUID SHIFTS: INTERSTITIAL FLUID TO PLASMA

 Fluid is drawn into the plasma space whenever there is an increase in plasma osmotic or
oncotic pressure. Administration of colloids (e.g. albumin), dextran, mannitol, or
hypertonic IV solutions all draw fluid from the interstitium into the vascular space.
 Increasing tissue hydrostatic pressure also causes a fluid shift. Wearing elastic
compression gradient stockings is an example of a therapeutic application.
INTRAVENOUS FLUIDS: REVIEW

Crystalloids Colloids
Contain small molecules (solutes) that are Contain large molecules, can’t pass through
easily dissolved in a solution semi-permeable membranes (capillaries)
Solutes may be electrolytes (Na+, K+) or non- Remain in intravascular space (inside the
electrolytes (glucose) vessel)
Move easily across semi-permeable Expand intravascular volume
membranes
Example: Ringer’s Lactate Exert oncotic pressure to “pull” fluid into
vascular space
Example: Albumin
First choice for fluid resuscitation Protein solutions
INTRAVENOUS SOLUTIONS CONTINUED
Hypotonic Isotonic Hypertonic
Concentration of dissolved Osmotic pressure inside & Concentration of dissolved
particles is lower than outside of cells remains particles is higher than
plasma. constant intracellular fluid & plasma
Lowers osmotic pressure
within the vascular space.
Hydrates cells but also Remain in extracellular Infusion increases osmotic
decreases volume in space & distributed between pressure in vascular space.
intravascular space – can intravascular and interstitial Draws fluid from intracellular
worsen hypotension compartments to extracellular space
Have potential to cause Ideal fluid replacement for a Useful in treatment of
cellular swelling patients with ECF deficit hypovolemia &
hypernatremia
Pulls fluid into cells Doesn’t affect size of cells Pulls fluid out of cells
Often used for maintenance Contraindicated in lactic Primary use is in provision of
fluids acidosis because body calories
unable to convert lactate to
EFFECTS OF WATER STATUS ON RED BLOOD CELLS
 ASSESSMENT OF FLUID AND ELECTROLYTE BALANCE IN THE
HOSPITALIZED PATIENT

Extracellular Assessment findings Extracellular Assessment findings
Fluid Volume Deficit Fluid Volume Deficit Fluid Volume Excess Fluid Volume Excess
Hypovolemia – low circulating Vital signs: tachycardia, Hypervolemia – fluid overload Vital signs: full bounding pulse,
blood volume hypotension, increased RR due to increased BP, jugular venous
decreased perfusion distension
Caused by vomiting, diarrhea, Dry mucous membranes, cool Caused by heart, liver, renal Respiratory: crackles, SOB,
diuretics, wounds etc. skin, failure etc. dyspnea
Poor tissue turgor
Treatment: Fluid & electrolyte Irritability, confusion Treatment: Fluid restriction, Weight gain
replacement Weight loss sodium restriction, diuretics etc.
IV bolus or continuous infusion, Decreased urine output
oral or enteral replacement
Flat neck veins, weak pulse, Mental status changes
reduced capillary refill
HOW DO WE KNOW FVE HAS RESOLVED?

 Stable CV status with  BP
 Diuresis
 Balanced intake & output, weight loss
 Decreasing edema
 Improving lung sounds (↓ crackles, ↑ AE)
 Improved mental status
 Stabilizing bloodwork
Serum Proteins & Electrolytes
PLASMA PROTEINS (PRIMARILY ALBUMIN)

 Protein 64-83 g/L
 Albumin 35-50 g/L
 Affects serum osmolarity (The pressure exerted by proteins on the blood vessels).
 The main negatively charged intravascular fluid anions.
 Pull water into the vascular space and keep it there.
 Too big to cross the semipermeable capillary wall so the concentration is highest in the
vascular space.
 Plasma proteins create colloid osmotic pressure which pull water in and holds it in the
vascular bed.
PROTEIN IMBALANCES
Causes Assessment findings Treatment (Do) Teaching

Decreased food intake Edema – caused by Provide a high Teach about reasons
decreased oncotic carbohydrate, high for breakdown of
Starvation pressure protein diet and protein
dietary protein Elevated basal
Liver disease Slow healing supplements metabolic rates
Catabolic states
Massive burns Anorexia Enteral nutrition (tube fever
feeding) or total infection
Loss of albumin in Fatigue parenteral nutrition malignancies
renal disease may be used if patient
Anemia cannot meet protein Protein is needed for
Major infection needs orally cell growth and repair
Muscle loss – results
GI disease from breakdown of
(malabsorption) body tissue to meet
the body’s need for
Etc. protein
ELECTROLYTES

What do they do What happens if
What are they? that makes them there is an
so important? imbalance?
Positive and negative Produce energy Negative effects on all
electrically charged Help with electrical body systems
ions/salts dissolved in conduction Our cells will not function
body fluids and dispersed Help your nerves and without them
throughout the body into muscles to function
all compartments. Regulate acid-base
balance
Help to regulate the
extracellular and
intracellular fluid balance
MAIN ELECTROLYTES

Extracellular Intracellular
 Sodium  Potassium
 Chloride  Magnesium
 Calcium  Phosphorus
ELECTROLYTE BALANCE

 Potassium is the dominant particle in intracellular fluid (ICF)
 Sodium is the dominant particle in extracellular fluid (ECF)
 Osmolarity (total solute concentration) is the same in ECF and ICF
even though the numbers of each of the electrolytes (solutes)
differs.
 Osmolarity is higher when there are more electrolytes in solution
 Three factors govern osmolarity: electrolytes (especially sodium
Na+), glucose and urea, plasma proteins (albumin)
ELECTROLYTES / LIVER PANEL / RENAL PANEL
NORMAL VALUES IN ADULTS

 Potassium (K): 3.5-5.0 mmol/L
 Sodium (Na): 135-145 mmol/L
 Chloride (Cl): 98-106 mmol/L
 Bicarbonate (HC03- ): 21-28 mmol/L
 Magnesium (Mg2+ ): 0.74-1.07 mmol/L
 Calcium (Ca2+): 2.25-2.75 mmol/L
 Phosphate (P04-3): 0.97-1.45 mmol/L
 Protein Total: 64-83 g/L
 Albumin: 35-50 g/L
NA+ SODIUM
 Most abundant electrolyte in extracellular fluid. Very common
electrolyte disorder!
 Na+ attracts water and plays a major role in fluid balance.
 Sodium imbalance usually means a fluid imbalance.
 Absorbed in intestines/ excreted by kidneys
 Works with potassium to maintain electrolyte balance between ICF
and ECF ( sodium potassium pump)
 Primary acute clinical manifestations are neurological.
CELL CHANGES WITH SODIUM IMBALANCES

As water shifts – either into or out of the cells
- neurological changes are the most common

clinical manifestations.

Water follows sodium. Cells will either shrink or swell.
 HYPONATREMIA
NORMAL 135-145 MML/L
CRITICAL VALUE < 120 MML/L
Causes Assessment findings Treatment (Do) Teaching

Sodium Loss: Decreased ECF volume (sodium Accurate intake and output Teach about commercially
GI losses: diarrhea, vomiting, loss) Intake includes oral, IV, tube available oral rehydration fluids
fistulas, NG suction Irritability, confusion feedings, any retained containing electrolytes to
Renal losses: Hypotension irrigation fluids prevent sodium loss in cases of
Diuretics, adrenal insufficiency, Tachycardia Output includes urine, excess diarrhea and vomiting.
Skin losses: burns, wound Nausea and vomiting perspiration, wound or tube
drainage Dry mucous membranes drainage, vomiting and Teach patients with heart
Weight loss diarrhea failure to monitor weight daily
Water gain: (sodium dilution) Tremors, seizures, coma Monitor vital signs and observe and report sudden increase.
SIADH (syndrome of trends
inappropriate antidiuretic Fluid restriction is often all that
hormone secretion) Normal or increased ECF is needed.
Heart failure volume (water gain) Daily weights
Excessive IV or oral fluids Skin assessment and care
Headache, apathy Safety Considerations:
Weakness, confusion Administer IV fluids as ordered.
Nausea and vomiting Hypertonic saline solution (3%
Weight gain or 5%) can be used for a
Increased BP limited time and requires very
Muscle spasms, seizures, coma close monitoring.
Rapid correction of
hyponatremia can cause
permanent brain damage –
osmotic demyelination
 HYPERNATREMIA NA+ 135 -145 MMOL/L
CRITICAL VALUE > 160 MMOL/L

Causes Assessment findings Treatment (Do) Teaching

Hypernatremia (water deficit) Decreased ECF (water loss) Treat the underlying cause Teach older adults to drink
Increased insensible water loss Intense thirst; dry, swollen In primary water deficit: water regularly.
or perspiration (high fever, tongue Replace fluid orally or with
heat stroke) Restlessness, agitation, isotonic 0.9% sodium chloride Explain treatment goals to
Diabetes insipidus twitching For sodium excess – dilute patients
Osmotic diuresis (seen in type Seizures, coma sodium concentration with salt
1 diabetes) Weakness free IV fluids e.g 5% Dextrose
Postural hypotension in water (hypotonic)
Sodium gain Weight loss Promote excretion of sodium
IV hypertonic NaCl with diuretics
IV sodium bicarbonate Normal or increased ECF
Salt water near-drowning (sodium gain) Safety considerations:
Intense thirst Na + Levels must be reduced
Restlessness, agitation, gradually
twitching Older adults or cognitively
Seizures, coma impaired individuals are at high
Flushed skin risk. Regular administration of
Weight gain oral fluids must be
Peripheral and pulmonary incorporated in the plan of care
edema
Increased BP
K+ - POTASSIUM

Critical values: < 3.3 mmol/L or > 6.0 mmol/L
Many cellular and metabolic functions
Transmission & conduction of nerve impulses
Maintenance of normal cardiac rhythms
Skeletal and smooth muscle contraction
Promotes cellular growth
Kidneys are primary route for K+ loss
Diet is source of K+
 HYPOKALEMIA K+ < 3.5 MMOL/L
CRITICAL VALUE < 3.3 MMOL/L

Causes Assessment findings Treatment (Do) Teaching

Deficient dietary intake Weak, irregular pulse Administration of K+ Signs & symptoms of
supplements orally or IV (oral hypokalemia
ECG changes – ventricular route preferred) Importance of increasing
dysrhythmias, flattened T Dilute liquid in water or juice dietary K+ if taking thiazide
wave, presence of U wave, Give pills with food or loop diuretics
bradycardia etc. For patient taking K+
GI losses ( diarrhea, vomiting, Skeletal muscle weakness, Safety Considerations: sparing diuretics explain
NG suction) fatigue IV K+ is irritating to the that salt substitutes and
Lethargy vein assess IV site hourly foods with high K+ content
Low, shallow respirations for phlebitis and infiltration should be avoided
If taking K+ supplements
Diuretics – especially in Leg cramps – K+ can cause necrosis &
sloughing take as directed with a full
patients with high aldosterone Limp muscles glass of H20
K+ given IV must be diluted
levels If taking digoxin or at high
Never IV push
Skin losses - diaphoresis May be asymptomatic IV bags should be inverted risk of hypokalemia serum
several times to ensure K+ levels should be
even distribution monitored regularly
Never add K+ to a hanging
IV bag to avoid a bolus dose
**Think slow and low
POTASSIUM RICH FOODS
 HYPERKALEMIA K+ > 5.1 MMOL/L
CRITICAL VALUE > 6.0 MMOL/L
Causes Assessment findings Treatment (Do) Teaching

Failure to eliminate K+ Irregular pulse Mild: Explain rationale for treatment
Renal disease Cardiac standstill if Eliminate oral and IV K+ intake and provide teaching about
K+ sparing diuretics hyperkalemia sudden or severe medications.
Adrenal insufficiency Moderate:
ACE inhibitors ECG changes – tall peaked T Increase elimination of Reinforce self-management of
wave, loss of P wave, potassium renal insufficiency – dietary
ventricular fibrillation, etc. Diuretics (furosemide) restrictions etc.
Dialysis
Irritability/anxiety Ion-exchange resins
(Kayexalate)
Weakness of lower extremities Increased fluid intake
Shift of K+ out of cells: Severe (ECG changes)
Acidosis Paresthesia Force potassium from ECF
Tissue catabolism (e.g. to ICF
fever, sepsis, burns) Abdominal cramping/diarrhea Give IV insulin (along with
Crush injury glucose)
Tumour lysis syndrome Administer sodium
Excess potassium intake bicarbonate if acidosis
Excessive or rapid IV present
Reverse membrane effects
administration
K+ containing drugs of elevated ECF K+ by
Potassium containing salt administering calcium
substitute gluconate IV
 CA –CALCIUM
NORMAL VALUE 2.25 – 2.75 MML/L

 Obtained from diet
 More than 99% combined with phosphorus and concentrated in the skeletal system.
 Calcium and phosphorus have inverse relationship – as one increases the other
decreases
 Functions: transmission of nerve impulses, myocardial contractions, blood clotting,
formation of teeth and bone, and muscle contractions.
 Present in serum in 3 forms: free or ionized; bound to albumin; and complexed with
phosphate, citrate, or carbonate. Ionized form is biologically active. Total calcium
includes all three forms
 Calcium balance is controlled by parathyroid hormone and vitamin D.
 HYPERCALCEMIA CA ++ 2.25 – 2.75 MML/L
CRITICAL VALUE > 2.75 MMOL/L

Causes Assessment findings Treatment (Do) Teaching

Increased total calcium Lethargy Basic treatment is promotion of Teach about medications and
Malignancies (1/3 of cases) Weakness excretion by administration of why they are being
Prolonged immobilization Decreased memory a loop diuretic and hydration administered.
Hyperparathyroidism (2/3 of Confusion/personality changes with isotonic saline solutions
cases) Anorexia, nausea vomiting Mobilization with weight-
Vitamin D overdose Bone pain, fractures bearing activity
Thiazide diuretics Polyuria, dehydration Synthetic calcitonin to lower
Nephrolithiasis (kidney stones) Ca++ levels
Stupor, coma In cases of malignancy the
Increased ionized calcium drug of choice is pamidronate
acidosis ECG changes which inhibits the activity of
osteoclasts
Safety considerations:
Careful monitoring when
giving IV saline as fluid
overload can occur in patient
who cannot excrete excess
sodium due to renal
insufficiency.

Consider fall risk and safety
 HYPOCALCEMIA CA++ 2.25- 2.75 MMOL/L
CRITICAL VALUE < 2.25 MMOL/L

Causes Assessment findings Treatment (Do) Teaching

Decreased total calcium Easy fatigability Aimed primarily at correcting Teach about risk for fractures
Chronic renal failure Depression, anxiety, confusion cause
Vitamin D deficiency Numbness & tingling in Increase calcium in diet Teach about need for dietary
Primary extremities and around mouth Vitamin D supplementation changes or about
hypoparathyroidism Hyperreflexia supplementation with oral
Elevated phosphorus Muscle cramps If severe: calcium if prescribed.
Loop diuretics Chvostek’s sign IV calcium
Chronic alcoholism Trousseau’s sign
Multiple blood transfusions
Safety considerations:
Laryngeal spasm
Etc. Tetany, seizures
Any patient undergoing
ECG changes thyroid or neck surgery
should be observed closely
in the post-op period for
manifestations of
hypocalcemia because of the
proximity of surgery to
parathyroid glands
TESTS FOR HYPOCALCEMIA

 Chvostek’s sign is contraction of facial muscles in

response to a light tap over the facial nerve in front of the ear

 Trousseau’s sign is a carpal spasm induced by inflating a

blood pressure cuff above the systolic pressure for a few
minutes. (carpal spasms become evident within 3 minutes if
hypocalcemia is present)
MAGNESIUM IMBALANCE

Not commonly seen unless kidneys are not functioning normally.
Magnesium plays an important role in essential cellular processes. It
is a co-factor in many enzyme systems. Muscle contraction and
relaxation, normal neurological function, and neurotransmitter release
depend on Mg++

 Primary clinical manifestations are neuromuscular and cardiac.
 HYPOMAGNESEMIA - MG++ 0.74-1.07 MMOL/L

Causes Assessment findings Treatment (Do) Teaching

Diarrhea Resembles hypocalcemia If asymptomatic – oral Teach about increasing dietary
Vomiting Neuromuscular manifestations magnesium supplements intake of magnesium or oral
Chronic alcoholism are common: supplements if ordered.
Impaired GI absorption Muscle cramps Cardiac or neurological
Prolonged malnutrition Tremors symptoms
Large urine output Hyperactive deep tendon IV Mg sulfate administered
NG suction reflexes slowly
Hyperaldosteronism Chvostek’s sign Safety considerations:
Trousseau’s sign

Neurological manifestations: Monitor vital signs when
Confusion administering magnesium IV
Vertigo
Seizures Use infusion pump because
rapid administration can
lead to hypotension, cardiac,
and respiratory arrest.
 HYPERMAGNESEMIA - MG++ 0.74-1.07 MMOL/L

Causes Assessment findings Treatment (Do) Teaching

Usually only occurs with an Initial manifestations: Initially: avoidance of oral Teach about decreasing dietary
increase in magnesium Hypotension magnesium intake intake of magnesium.
intake accompanied by Facial flushing
renal insufficiency or failure Lethargy If renal function is adequate, If renal function is adequate
(Maalox, Milk of Magnesia Urinary retention increased fluids and diuretic teach about increasing fluids
are high in Mg++) Nausea & vomiting promote urinary excretion

Can develop in pregnant Later: Dialysis is required in patients
women who receive MgSO4 Deep tendon reflexes are lost with impaired renal function
for management of Muscle paralysis and coma
eclampsia. Respiratory and cardiac arrest If symptomatic – calcium
gluconate administered IV
opposes effects of excess
magnesium on cardiac muscle
 PHOSPHATE: 0.97-1.45 MMOL/L
CRITICAL VALUE < 0.32 MMOL/L

Essential to function of muscle, RBCs and nervous system
Stored in the bones
Excreted through the kidneys
Calcium and phosphate influence each other in opposite ways. For
example, when calcium levels increase; phosphate levels decrease
Can result in cardiac dysrhythmias, muscle weakness, CNS
dysfunction etc.
 HYPER & HYPOPHOSPHATEMIA - PO4 0.97 – 1.45 MMOL/L
CRITICAL VALUE < 0.32 MMOL/L

Hyperphosphatemia:Causes Assessment findings Hypophosphatemia: Causes Assessment findings

Main Cause: Hypocalcemia Malabsorption syndrome Remember the word: “BROKEN”
B- Breathing problems due to
Renal failure Glucose administration muscle weakness
Muscle problems, tetany Total parenteral nutrition R- Rhabdomyolysis- rapid
Other causes: Alcohol withdrawal necrosis of skeletal muscles
Excess Vitamin D intake Deposition of calcium, Phosphate binding antacids which leads to renal failure. Renal
failure occurs as a result of
Excessive ingestion of milk or phosphate precipitates in skin, Recovery from diabetic myoglobin being released into
phosphate containing soft tissue, joints, blood ketoacidosis the blood due to muscle death.
laxatives, vessels etc. Respiratory alkalosis Myoglobin is toxic to the kidneys
O- Osteomalacia (softening of the
chemotherapy bones); cardiac Output is
decreased
K- Kills the immune systems with
immune suppression and
decreased platelet aggregation
(increased risk of bleeding)
E- Extreme weakness,
ecchymosis due to decreased
platelets.
N- Neuro changes (irritability,
confusion, seizure, coma)
Acid Base Balance
 ACID-BASE IMBALANCE
PH 7.35 – 7.45

 Normally there is a steady balance between acids produced during
metabolism and bases that neutralize and promote excretion of acids.
 Vomiting and diarrhea cause loss of acids and bases
 Renal insufficiency results in inability to compensate for acid load so older
adults are often at risk
 Older adults have decreased respiratory function which impairs the body’s
ability to compensate for acid base imbalance
 Lung diseases such as COPD cause retention of carbon dioxide, an acidic gas
 All seriously ill patients are at risk for acid-base imbalance
 ARTERIAL BLOOD GASES – NORMAL VALUES

 pH – 7.35- 7.45
 PC02 – 35-45 mm Hg
 Bicarbonate level – HC03 – 21 -28 mmol/L
 P02 – 80-100 mm Hg
 ACIDOSIS PH < 7.35
ALKALOSIS PH > 7.45

Respiratory Respiratory Metabolic Acidosis Metabolic Alkalosis
Acidosis Alkalosis
Causes: Causes: Causes: Causes:
COPD Hyperventilating Diabetic ketoacidosis Severe vomiting
Overdose Stimulated respiratory Lactic acidosis Excess gastric suctioning
Severe pneumonia center (sepsis, brain Starvation Potassium deficit
Pathophysiology: injury etc.) Severe diarrhea Pathophysiology:
C02 retention by lungs Pathophysiology: Renal failure Loss of strong acid or
due to hypoventilation Increased C02 excretion Shock gain of base
Lab findings: by lungs Pathophysiology: Lab findings:
Decreased pH Lab findings: Gain of fixed acid, Increased pH
Increased paC02 Increased pH inability to excrete acid Increased HC03
Etc. Decreased PaC02 or loss of base
Lab findings:
Decreased pH
Decreased HC03
LAB VALUES

Blood is the body fluid most frequently analyzed in the lab
Used to assess many body processes and disorders
Usual reasons for blood work:
To establish a medical diagnosis ( e.g. renal failure)
To rule out a clinical problem (e.g. hypokalemia)
To monitor therapy (e.g. insulin or anticoagulant)
To establish a prognosis (decreasing CD4 counts in HIV)
To screen for disease (PSA levels. FIT test)
To determine effective drug dosage and prevent toxicity (i.e., digoxin, phenytoin…)
LAB VALUES

 An important part of patient assessment
 “Blood work” contains valuable information about nutritional,
hematologic, metabolic, immune and biochemical status of patient
 3 general methods used: venipuncture (venous blood), arterial, and
skin or capillary puncture
COMMON TESTS

 Complete Blood Count and Differential : CBC and Diff
 Electrolyte Panel (K+, Mg, Ca, Cl, Na…)
 Liver Function Tests/ Liver Panel
 Renal Panel
 Lipid Panel (LDL, HDL, TG, TC)
 Coagulation Screening (PT, PTT, INR)
CBC

 Red blood cell (RBC) count
 Hemoglobin
 Hematocrit
 RBC indices
 White blood cell (WBC) and differential count
 Blood smear
 Platelet count
 Mean platelet volume
RED BLOOD CELL INDICES

 Red blood Cell Indices provide information about the size,
colour and hemoglobin content of the RBC. Useful in
classifying anemias.
 Includes: Mean Corpuscular Volume (MCV), Mean
Corpuscular Hemoglobin (MCH), Mean Corpuscular
Hemoglobin Concentration (MCHC), Red Blood Cell
Distribution Width (RDW)
RED BLOOD CELL COUNT

Normal findings in adults:
Male: 4.3-5.7 x 1012/L (SHA- 4.7-6.1 x 1012/L )
Female: 3.8-5.1 x 1012/L (SHA- 4.2-5.4 x 1012/L)

 Repeated serially in patients with ongoing bleeding
 Low values have many causes: hemorrhage, hemolysis, dietary
deficiency (iron or B12),bone marrow failure, chronic illness,
ingestion of drugs affecting RBCs, other organ failure
CBC - HEMATOCRIT

 Hematocrit is the percentage of total blood volume that is
composed of RBCs.
 Helpful in diagnosing and assessing blood diseases, nutritional
deficiencies and hydration status
 Male: 0.39--0.50 L/L (SHA- 0.42-0.52L/L volume fraction 40-50%)
 Female: 0.35-0.47 L/L (SHA-0.37-0.47 L/L volume fraction 37-47%)
HEMOGLOBIN (HGB)

Hemoglobin is a protein in red blood cells that carries oxygen throughout the body.
The hemoglobin molecule contains iron
Normal findings:
Adult male: 132-173g/L (SHA 140-180 g/L)
Adult female: 117-160g/L (SHA120-160g/L)
If hemoglobin falls too low the CV system is strained leading to risk of angina, MI, heart
failure and stroke. If too high – risk of stroke and organ infarction
CBC - HEMOGLOBIN

 Decisions concerning need for blood transfusion are usually based
on hemoglobin or hematocrit.
 In an otherwise healthy person transfusion is not generally
considered if hemoglobin > 80
CBC - WHITE BLOOD CELLS AND DIFFERENTIAL

WBC and differential provide two elements of information
A total count of WBCs per liter of peripheral blood.
The differential count – the percentage of each type of leukocyte

Normal value: 4.0-10.0 x 109/L
Clinical significance
High: infection; inflammation; burns; trauma; heart attack; surgery; leukemia
Low: Bone marrow disorders or damage; lymphoma; autoimmune disorders (ie..,
lupus); disease of immune system (i.e., HIV); aplastic anemia; chemo/radiation
therapy
DIFFERENTIAL

Neutrophils: 2.5 – 7.5 x 109/L
Watch for Bands
Lymphocytes: 1.0 -- 4.0 x 109/L
Monocytes: 0.1 -- 0.7 x 109/L
Eosinophils: 0.00–0.5 x 109/L
Basophils: 0.02 -- 0.05 x 109/L
Determination of whether each kind of WBC is present in proper
proportion.
CBC - PLATELET COUNT
NORMAL VALUE: 150-400 X 109/L

Platelet activity is essential to blood clotting. Platelets circulate
in the bloodstream and bind together to form a clot over a
damaged blood vessel.
Determining platelet count is vital in assessing patients for
tendencies of bleeding and thrombosis
Counts lower than 150 x 109/L are considered to indicate
thrombocytopenia.
Thrombocytosis is diagnosed when counts exceed 400 x 109/L
CBC - PLATELETS

Thrombocytopenia (decreased levels) found in:
Idiopathic thrombocytopenia; hemorrhage; bone marrow disorders; viral infection;
certain drugs; metastasized cancer to the bone marrow; leukemia; Lupus; cancer
treatment… etc.

Thrombocytosis (increased levels) found in:
Acute infection; cancers of lung, GI, ovarian, breast or lymphoma;
myelodysplastic disorder such as chronic myeloid leukemia; polycythemia vera;
postsplenectomy syndrome; inflammatory conditions (RA; inflammatory bowel
disease); iron deficiency anemia; chronic pancreatitis; cirrhosis, chronic
granulocytic leukemia;..etc.
ANEMIA

A reduction in one or more of the major red blood cell (RBC)
measurements obtained as a part of the complete blood count
(CBC): *RBC; hematocrit (Hct); hemoglobin(hgb)
Normal ranges of hemoglobin/Hct may not apply to certain
populations
One of the most common problems seen in clinical practice
Not a disease, it is a symptom of underlying pathophysiological
process
In many cases, the cause is not readily apparent and multiple
conditions may be related to anemia
ANEMIA-CLINICAL MANIFESTATIONS

Caused by the body’s response to tissue hypoxia

Depends on the severity of anemia and the types of anemia

Severity of anemia is determined by hemoglobin levels

Mild: 100-120 g/L

Moderate: 60-100 g/L

Severe: