1. Homeostasis and homeostatic regulation. Control systems, negative feedback
and levels of physiological regulation.
Homeostasis
- maintenance of a constant internal environment within the body by coordinated
physiological mechanisms
- internal environment, cells do not communicate with external world directly
- they are surrounded by an internal environment: extracellular uid
- cells are capable of living, growing and performing their special functions only if proper
and constant condition ( e.g. pg, temperature, chem. compositions usw) is maintained
- if homeostasis fails: death or diseases may occur
Control systems and homeostatic regulation
- all organs and tissues of the body perform functions that help maintain the constancy
of internal environment
- control system def: device or set of devices managing, commanding, directing or
regulation the behavior of other devices or systems
Types:
1) open loop control system
2) closed loop control system
- goal of homeostatic control: maintain constancy of the parameters of the internal
environment
- homeostatic control systems are basically closed- loop control systems with a negative
feedback
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, Positive feedback
- output enhances original stimulus
- e.g. some features of hormone action causes more secretion of the hormone
- examples: delivering ( Oxytocin) , ovulation ( FSH), blood clotting
Negative feedback
- output inhibits original stimulus
- almost all homeostatic control mechanism are neg. feedback
- examples: control of blood sugar caused by insulin. When blood sugar rises, receptors
sense a change. in turn, the pancreas secretes insulin to lower the blood sugar. Once
blood sugar levels reach homeostasis, the pancreas stops secreting insulin
Levels of physiological regulation
Types of regulation:
proportional
derivative
integral
anticipatory
Levels of regulation:
intracellular
local
organ/system
whole body
Neural regulation:
- involved in fast adaption to changes in external and internal environment
- regulation of movement
- precise targeting and adaption
- e.g. neural regulation of blood pressure
Endocrine regulation:
- slower responses
- more di use in uences
- involved in long- term regulation of metabolism, growth, reproduction
- neural and endocrine control systems interact and regulate each other
- neuro- endocrine re exes
- endocrine glands are controlled by hypothalamus and autonomic nerves
- hormones modulate neuronal activity
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,2. Structure and function of the cellular membrane. General characteristics of
membrane transport, Passive transport across the cellular membrane.
Structure and function of the cell membrane
- separates the cytoplasm from the cell environment
- participates in binding and signaling ( chemical and electrical) to be integrated in a
complex living organism
- regulation of what enters and leaves the cell. Creates di erences in extra and
intracellular uid composition—> for biochemical
processes
Cell junctions in epithelial cells. Cell adhesion proteins
fl ff
, - lipid rafts and caveolae: specialized membrane microdomains enriched in sphingolipids
and cholesterol
- function in variety of cellular processes: endocytosis, transcystosis, signal
transduction and receptor recycling
Membrane transport
- plasma membrane is selectively permeable to gases, hyrophobic molecules, small polar
molecules
- large polar molecules and ions can penetrate the cell membrane via membrane
channels or carrier proteins ( integral)
Ion channels:
- selective for particular ions or groups of ions
- regulation: gating, trafficking
- voltage- gated
- ligand- gated
- mechano- gated ( stretch activated)
- non- gated ( always open)
- water can move through phospholipid bilayer or membrane channels—< aquaporins
( gating or trafficking)
Passive transport
- No metabolic energy required
- down the electrochemical gradient
- simple diffusion
- facilitated diffusion
- osmosis
- filtration
Simple diffusion:
- driven by concentration difference between both side of the membrane and direction of
the net movement is down the electrochemical gradient
- net diffusion stops when the concentration on both sides of the membrane is equalized
- energy is released during the movement of a solute down its concentration gradient
- factors affecting: First Ficks law for free diffusion —> J= -D(dc/dx)
for diffusion across membrane—> J= -P(C1-C2)
- Diffusion of ions: electrical potential differences are created during ion diffusion
net diffusion of ions stops when concentration and the electrical
gradients are in equilibrium, the electrochemical gradient = 0
- liner in graph
Facilitated diffusion:
- requires carrier proteins-> binding to carrier increases rate of diffusion
- no metabolic energy
- driving force is concentration gradient ( electrochemical gradient) of solute
- characterized by: 1) specificity 2) competition 3) saturation ( non- liner in graph)
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