Physiology for fluid therapy and patient assessment Flashcards
Fluid distribution in the body
60% body weight = water
of this
5% = intravascular compartment - inside blood vessels
- for delivery of O2, nutrients and transport of waste
55% = extravascular compartment - outside blood vessels
- 40% H2O inside cells
- 15% H2O between cells
Fluid movement
Fluid is not static
movement between intravascular and extravascular compartments is influenced by starlings forces
Fluid distribution around body
Plasma proteins and hydrostatic pressures influences distribution of fluid around the body
What causes fluid balance to get disrupted?
Changes in volume e.g dehydration and hypovalemis
Changes in content e.g. electrolyte disturbances, changes in blood glucose, changes in blood protein levels
Changes in distribution e.g. Third spacing
Increase vs decrease in fluid volume
Increase in fluid volume: Hypervolaemia - can lead to volume overload
Decrease in fluid volume = Hypovalemia (inside the blood vessels), dehydration (outside the blood vessels)
What is hypovolaemia?
- Fluid is lost quickly from the intravascular space
- This results in tissue hypo perfusion aka ‘shock’
- so decreased delivery of O2 and removal of waste
- e.g. bleeding following an RTA
What is dehydration?
- Fluid is lost slowly from the extravascular compartment - patient is unable to keep up its ‘ins’ with its ‘outs’
- There is time for fluid to be distributed across all body compartments
- Results in water being lost equally from all compartments from the body
- e.g. an animal without access to fluid and water
Physiological consequences of hypovolaemia
Blood loss
Reduced pre-load (amount of blood returning to the heart)(endiastolic volume decreases)
Reduced stroke volume
Decreased cardiac output
Vasoconstriction (increases total peripheral resistance) and tachycardia (fall in BP to compensate)
Leads to
Maintenance of BP to heart, brain and lungs
Changes in mucus membrane colour and CRT
How to asses a patient’s intravascular volume?
- heart rate
- Pulse quality
- Mucus membrane colour
- Capillary refill time - normal = 1.5-2s
- Blood pressure
- Mentation = mental awareness
- (Temperature)
Hypovolaemia peramaters canine
Normal
HR= 6-120
Mucus membrane colour = pink
CRT = <2
Pulse quality = ‘normal’
Systolic BP (mmHg) = >90
Mentation = Normal
Mild shock (compensatory)
HR = 130-150
MMc = Normal to pinker
CRT = <1
Pulse quality = Bounding
Systolic BP (mmHg) = >90 (factors above all adjusted to keep BP 90)
Mentation = Normal
Moderate shock
HR = 150-170
MMc = Pale pink
CRT = 2
Pulse quality = weak
Systolic BP (mmHg) = >90
Mentation = Normal -obtunded (diminished response to stimuli)
Severe shock (decompensatory) - no longer able to maintain perfusion to vital tissues
HR = 170-220 - if above 220 be suspicious of tachyarythmia as a cause
Mmc = Pale pink - white
CRT = >2
Pulse quality = very weak
Systolic BP (mmHg) = <90
Mentation = obtunded - disminished response to stimuli
Why will the body never have a HR of above 220?
<220 will mean the heart can’t properly fill with blood as not enough time so it would actually decrease CO
How to assess a patients extravascular volume?
- Moistness of mucous membranes
- Skin tutor e.g. skin tenting (cat and dog above hear, horse and cattle skin above eye)
- Weight
- Globe position
- (urine output)
