second-order neuron

• Fast pain: Sharp and localized carried by A-delta fibres
• Slow pain: Dull and diffuse carried by C fibres

• Up-regulation: Generation of more hormone receptors on a cellular surface – often caused by low levels of the hormone.
• Down-regulation: A reduction in the number of receptors in the presence of high hormonal levels that persist over time – often caused by prolonged exposure to high hormone levels.

The organic components include:

• Osteoblasts (immature) and Osteocytes (mature) are bone-forming cells
• Osteoclasts – large cells that resorb or break down bone matrix (more on cells later)
• Osteoid – unmineralized bone matrix composed of proteoglycans, glycoproteins, and collagen.

• Dorsal column–medial lemniscal pathways
• Spinothalamic pathways
• spinocerebellar tracts

Flexion reflexes are polysynaptic reflex pathways that cause an arm or leg to be pulled away from noxious stimuli

They rely on divergent pathways in spinal cord

A painful stimulus can activate multiple excitatory and inhibitory interneurons in spinal cord

In the affected limb, flexors are activated and extensors inhibited

In the opposite limb, extensors are activated and flexors are inhibited.

For example: step on something sharp, other limb will be activated to give balance and not fall over

• Step 1: Hormone binds to receptor
• Step 2: The receptor changes shape → G protein binds to the receptor → the guanosine diphosphate (GDP) bound to the G protein is displaced by a high-energy GTP. It is now “on”
• Step 3: The now active G protein moves and binds to its effector – adenylate cyclase.
• At this point GTPase cleaves off a Pi from GTP leaving GDP bound to G protein (the G protein is now inactive and free to roam)
• Step 4: The now activated adenylate cyclase generates cyclic AMP (cAMP). This process requires energy (ATP). cAMP is the intracellular second messenger
• Step 5: cAMP diffuses through the cell triggering a number of chemical reactions typically involving protein kinases (enzymes).

Heat Exhaustion

• Heat-associated collapse after vigorous exercise, evidenced by elevated body temperature, mental confusion, pale complexion, and fainting
• Primarily due to dehydration and low blood pressure
• Body temperature is between 37.5 and 39º C but heat-loss mechanisms are fully functional.

Heat stroke

• Heat exhaustion can progress to heat stroke if the body is not cooled and re-hydrated
• The skin is flushed and dry
• Immediate and rapid cooling is necessary because enzymes begin to denature at 41º C.

Impulses from pyramidal neurons in precentral gyri pass through pyramidal (lateral and ventral corticospinal) tracts. 

Descend directly without synapsing until axon reaches end of tract in spinal cord.

In spinal cord, axons synapse with interneurons (lateral tract) or ventral horn motor neurons (ventral tract).

Direct pathway regulates fast and fine (skilled) movements.

• The sensory structure for the utricle and saccule are called the maculae
• The maculae are composed of hair cells embedded within another gelatinous mass (otolith membrane) topped with calcium carbonate and protein particles called otoliths
• Gravity or linear acceleration can cause the otoliths to move and the otolith membrane moves with them
• This bends the hair cells embedded within the otolith membrane.

• Step 1: Hormones lock into place and the receptor changes shape (same)
• Step 2: Binding of inactive G protein to the receptor occurs → G protein becomes “active” as GTP displaces GDP (same)
• Step 3: The G protein binds to and activates membrane bound phospholipase C (the effector enzyme) – the G protein then becomes inactive
• Step 4: Phospholipase C (enzyme) splits a plasma membrane phospholipid (PIP2 – phosphatidyl inositol biphosphate ) into 2 second messengers: DAG (diacylglycerol) IP3 (inositol triphosphate)
• Step 5: DAG activates specific protein kinases (e.g. protein kinase C) IP3 triggers the release of Ca2+ from the endoplasmic reticulum and other sites. 
• Step 6: Free Ca2+ acts as a second (or technically third) messenger by:
  • Altering activity of enzymes and plasma membrane Ca2+ channels
  • Binding to calmodulin
  • Once calmodulin is activated, enzymatic activity increases and cellular responses are amplified.

Radiant: Heat loss via infrared or other wavelengths -  accounts for almost half of bodily heat loss

Conductive: Heat loss through contact with another object (e.g. pumping gas in winter)

Convective: Heat carried away from the body by air that is warmed

Evaporative: Heat lost in evaporated water (e.g. sweat, respiratory tract).