Homeostasis Flashcards
Negative feedback
- returns the variable to the set-range after disturbance of the variable
- change is proportional to the size of initial variation
Feed Forward
Anticipatory changes before change to the variation e.g. incretin effect
Positive feedback
- amplifies any changes to the variable
- de-stabilises and accelerates transitions between different states e.g. uterine contractions and coagulation cascade
Molarity
Moles per litre solution
Molality
Moles per kg solvent
Tonicity
Describing two solutions separated by a membrane:
- Hypotonic - lower osmotic pressure outside cell (cell lyses) 600mM
- Isotonic - equal osmotic pressure in and out of cell 300mM
- Hypertonic - higher osmotic pressure inside cell (cell crenates) 100mM
Homeostasis
Maintenance of a constant condition in the internal environment
[NA+] = 145mM [K+] = 4mM Osmolarity = 300mOsm kg-1 Temperature = 37.1 pH = 7.4
Dual effectors/antagonistic effectors
Increase precision of control of homeostatic systems e.g. blood glucose regulation by insulin and glucagon
What is the osmolarity of mammalian fluid?
300 mosmolar (ions, proteins, sugars, lipids etc all contribute to this)
Osmotic pressure
Minimum pressure which needs to be applied to a solution to prevent inward flow of water across a semipermeable membrane.
(It depends on number of particles present per unit volume of solvent)
By definition: 1 g of a non-dissociating substance in 1kg of water exerts an osmotic pressure of 1 ormolu
What is the equation for osmotic pressure (π)?
π = MRT
M - molarity, R - gas constant, T - thermodynamic temperature
Why do proteins exert a very small osmotic pressure?
Their molecular mass is very high (per g of protein - osmotic pressure is much lower)
