Human Structure and Function Full Notes PDF

Summary

These notes provide a comprehensive overview of human structure and function, covering foundational concepts like osmosis and diffusion, physiology, and homeostasis. The text also explores various systems of the body such as the nervous system, muscular system, and cardiorespiratory system in detail. The notes provide an academic and scientific perspective on human biology for students likely to be of undergraduate level.

Full Transcript

 Contents

Foundations
Osmosis and Diffusion............................................................................................................................................... 3
Physiology and Homeostasis.....................................................................................................................................4
Drugs......................................................................................................................................................................... 6
Embryology................................................................................................................................................................ 8
Membrane Potential.................................................................................................................................................12
Central Nervous System.......................................................................................................................................... 13
Peripheral Nervous System..................................................................................................................................... 16
Action Potential........................................................................................................................................................ 18
Drugs: Agonists........................................................................................................................................................20
Drugs: Antagonists...................................................................................................................................................21

Neuromuscular
Neuromuscular Junction.......................................................................................................................................... 22
Sensory receptors....................................................................................................................................................24
Somatic Reflexes..................................................................................................................................................... 26
Excitation Coupling.................................................................................................................................................. 27
Force Relationship................................................................................................................................................... 30
Muscle Physiology................................................................................................................................................... 32
Autonomic Nervous System.....................................................................................................................................34
Autonomic Pharmacology........................................................................................................................................ 35

Musculoskeletal
Foundations of Anatomy.......................................................................................................................................... 38
Muscular system & muscles.................................................................................................................................... 39
Skeletal system & bones..........................................................................................................................................42
Articular system & joints...........................................................................................................................................44
Vertebral Column & Back.........................................................................................................................................46
Upper Limbs.............................................................................................................................................................47
Lower Limbs.............................................................................................................................................................50

Cardiorespiratory
Vascular system and vessels...................................................................................................................................54
The Heart................................................................................................................................................................. 58
Coronary and Great vessels.................................................................................................................................... 62
Cardiac Muscle Physiology......................................................................................................................................65
Blood Vessels.......................................................................................................................................................... 72
Baroreflex.................................................................................................................................................................77
Cardiovascular Pharmacology................................................................................................................................. 82
Gas Transport and Exchange.................................................................................................................................. 88
Thoracic Walls and Diaphragm................................................................................................................................ 92
Upper Respiratory Tract...........................................................................................................................................96
Lower Respiratory Tract...........................................................................................................................................98
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Mechanics of Ventilation........................................................................................................................................ 101
Neural Control of Ventilation.................................................................................................................................. 103

Guts and Gonads
Female Reproductive System................................................................................................................................105
Male Reproductive System.................................................................................................................................... 107
Reproductive Physiology....................................................................................................................................... 109
Abdominal Walls.....................................................................................................................................................119
Digestive Organs................................................................................................................................................... 123
Accessory Digestive Organs..................................................................................................................................125
Gastrointestinal Physiology....................................................................................................................................128
Urinary System...................................................................................................................................................... 136
Kidney Function & Filtration................................................................................................................................... 138
Renal Physiology................................................................................................................................................... 141

Therapeutics
Drug absorption, distribution and elimination.........................................................................................................149
Acid-base regulation.............................................................................................................................................. 153
Toxicology, adverse effects & tolerability............................................................................................................... 157
Drug Discovery...................................................................................................................................................... 160
Drug development & Evaluation............................................................................................................................ 162
Drugs in Clinical Practice....................................................................................................................................... 164
Respiratory Therapeutics.......................................................................................................................................168
Gastrointestinal Therapeutics................................................................................................................................ 172

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 Osmosis and Diffusion
Two fluid compartments in the body
1. Extracellular fluid; fluid outside the cell (ECF)
Plasma: Fluid portion of the blood, restricted to the circulatory system, contains: dissolved proteins, and ions
Interstitial Fluid: Fills the space between cells in the body, similar to plasma, very few dissolved proteins. Surrounds
cells.

2. Intercellular fluid; fluid inside the cell (ICF)
In the cytoplasm, very different to ECF
Surrounds the cell

Barriers
Plasma: interstitial - capillary wall
Interstitial: intracellular - cell membrane

Intracellular contents - - high K+ and low Na+
Concentration gradient: Na+ wants to enter the cell & K+ wants to leave the cell

Diffusion - Movement of particles dissolved in a solution to even the distribution of that particle
Process where molecules move to even their concentration throughout a space
Occurs when the net flow is from a region of high concentration to low concentration.
Does not require extra energy; therefore is a passive process.
Net movement of the substance will continue down its concentration gradient until it is distributed evenly in the space.

Osmosis - Movement of water across a semipermeable membrane to even the concentration of dissolved substances on both
sides

★ Diffusion cares about individual identity of the molecules, osmosis only cares about the number of molecules.

Concentration describes the number of a particular molecule dissolved in a volume of solution (specific particle, molar M)
Osmolarity describes the total number of dissolved particles in a volume of solution (total of particles, milliOsmolar mOsM)
Tonicity describes the cell behaviour of non-penetrative solvents (can’t cross membrane)

Isotonic - Balanced. Cells retain their normal size, no net movement.
Hypertonic - Cells lose water and shrink in a solution of higher concentration (water leaves to make inside more concentrated)
Hypotonic - Cells gain water and enlarge in a solution of lower concentration (water enters to make inside less concentrated)

Diffusion across membranes
Phospholipid bilayer regulates what enters and leaves the cell, and type of transport (active, facilitated diffusion, or diffusion)
Easily diffuses: hydrophobic molecules, small, polar, uncharged molecules (water)
Can not cross: large, uncharged, polar molecules and ions
Substances carried in the blood require a transport protein.

Fick’s law of diffusion determines how easily something can cross a barrier
Factors that increase rate of diffusion
High concentration gradient (Δ diffusion ∝ Δ concentration)
High permeability (permeability ∝ lipid solubility/molecule size)
Less distance to travel (Δ diffusion ∝ 1/Δ distance)
Larger surface area (Δ diffusion ∝ Δ SA )

3
 Physiology and Homeostasis
Homeostasis
Maintenance of a relatively stable internal environment. Self-regulating.
Disease occurs when oscillations go beyond optimal range.

Negative feedback
Closed loop, self-regulating. Always returns to homeostasis.
Positive feedback
Open loop, feedback amplification. Shifts back and forth between stages, e.g. childbirth contractions

Negative feedback control system features
1. Variable being regulated - controlled condition
2. Sensor (or receptor) that can detect the controlled variable
3. Input system - can carry messages to the integrator (afferent)
4. Control centre (aka integrator) can compare actual value with intended value
5. Output system - carry message to response system (efferent)
6. Effector - the response system
7. Response

e.g. blood glucose levels drop
- Blood glucose monitor detects fall in glucose
- Signals to the integrating centre via afferent pathway
- Pancreas cells will release a hormone called glucagon
- Hormone travels via efferent pathway to muscles to use stored glucose for ATP

Positive feedback amplification
Stimulus results in activation of a response
Response acts as a stimulus to reinforce (amplification)

- Myometric contraction
- Blood clotting
- Action potential
- Endocrine control of ovulation

Requires regulatory signals to shut off

e.g childbirth
- As the head pushes against the cervix, it stimulus more contractions
- More contractions push the head further out
- More pushing leads to more contractions

4
Control of homeostasis
Neurotransmitters
Chemical messengers that carry signals through neurons

Synapse - the point at which two neurons meet
Synaptic cleft - gap between neurons

Hypothalamus
Region of the brain that acts as the ‘integrator’ for many homeostatic reflexes
Regulates the endocrine and autonomic nervous system
Neural control of homeostasis
Produces neurosecretory cells
- Produce oxytocin (for birth and delivery)
- Produce antidiuretic hormone called vasopressin (causes blood vessels to constrict, increasing pressure)
- Releases tropic

Posterior Pituitary gland
Neurosecretory region
Two neurosecretions; oxytocin and antidiuretic

Anterior Pituitary gland
Hormone secretion; releases tropic

Region of hypothalamus makes constant with blood vessels, drains into anterior, releasing hormones going out to the rest of the
body to release more hormones

Neurosecretions of hypothalamus into the anterior pituitary
RH - releasing hormone
Stimulates release of tropic hormones from the anterior pituitary
IF - inhibitory factor
Inhibit release of tropic hormones from the anterior pituitary

Tropic - A hormone that stimulates another gland to release hormones

Basic regulatory patterns
1. Skeletal muscle movement
2. Antidiuretic hormone (vasopressin)
3. FSH- androgen binding protein
4. Thyroid hormone
5. FSH- oestrogen
6. Insulin

5
 Drugs
Drug - A medicine or other substance which has a physiological effect or a chemical substance which has a biological effect.
- Drug class produces information on mechanism of action.

Drug targets
4 regulatory proteins
Receptors: receive and transduce responses to chemical mediators
Ion channels: allow passage of ions across cell membranes when open; not a fixed number
Enzymes: biological catalysts
Carrier molecules: transport fixed number of substances across cell membrane

Pharmacokinetics
Rate and extent of movement of drugs into the body is affected by absorption and distribution.
Rate and extent of movement of drugs out of the body is affected by metabolism and excretion.

Signalling between cells
Chemical signalling allows for communication between cells.
Released molecules bind receptors on target cells
Local mediators, neurotransmitters, hormones, growth factors, metabolites

Bound receptors interact with effector/s which begin cellular response
Enzymes, channels, transporters, transcription factors

Drug molecules can disrupt or mimic cell communication

Types of communication
Endocrine
Soluble chemical signals secreted from cells enter circulation and are transported to a distant location.
Cells must express a receptor to receive a signal and elicit a cellular response; target cells.

Paracrine
Communication between nearby cells.

Autocrine
Cell signals to itself by receiving signals that bind to receptors expressed on its own surface.

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Types of receptors

Ligand-gated ion channels
Open when a molecule binds to specific ligands.
Allows movements of ions through the pore; chemical → electrical signal
Is a receptor and effector, very rapid cellular response (milliseconds)

G-protein coupled receptors
Single polypeptides with 7 transmembrane domains
Receptor activation elicits a conformational change and resulting interaction with a G
- protein allows signals to be transduced from outside the cell to inside.
Multi-step process, intermediate time for cellular response (seconds)

Catalytic receptors
Subunit comprises of
- Extracellular ligand-binding domain
- Transmembrane-spanning domain
- Intracellular domain with intrinsic catalytic activity

Binding of ligands to receptors leads to activation of downstream signaling pathways.
Often involves changes in gene transcription and protein translation
Found on cell surface; very accessible
Long time for cellular response (hours)

Nuclear receptors
Located in the nucleus or cytoplasm
Elicits effects after it has migrated into the nucleus following binding of ligands
Can enhance or repress gene transcription.
Long time for cellular response (hours)

Receptors as amplifiers
Second messengers able to amplify signals and direct signals to specific cellular locations
Second messenger concentrations must therefore be tightly regulated
Regulation is made possible as
- Generation of second messenger occurs in response to a signal; allows it to be very rapid
- Mechanisms exist in place to inactive second messengers

1. Single drug molecule binds to a G-protein coupled receptor
2. G-protein mediated actiation of a membrane bound enzyme
3. Subsequence generation of multiple second messengers
4. Each messenger can module the activity of downstream effectors

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 Embryology
Fertilisation to end of 2nd week (conceptus), 3rd week - end of 8th week (embryo), 3rd month to birth (foetus)
Stages
1. Ovulation - An oocyte exits the ovary into the oviduct
2. Fertilisation - The oocyte travels up the oviduct, and is penetrated by a sperm creating a zygote (fertilised egg)
3. Cleavage - Zygote undergoes numerous rounds of mitotic cell divisions
4. Morula - Solid ball of cells that form as a result of the mitotic division
5. Blastocyst - Morula enters the uterus and the cells drift apart producing a hollow ball of cells (blastocyst)
6. Implantation - Blastocyst attaches itself to the uterine lining, and inner mass begins to form primary germ layers

Blastocyst two types of cells
Outer epithelial layer (trophoblast); forms extraembryonic structures
Inner cell mass

Two germ layer stage
Inner cell mass splits
Cavities form
Form embryonic disc

Epiblast gives rise to embryo
Hypoblast gives rise to extraembryonic structures

Gastrulation formation of primitive streak
On upper surface of bilaminar disc (epiblast), a line of thickened cells appear (primitive streak)
Primitive streak invaginates to form primitive groove
Cells of epiblast migrate medially into primitive groove

First cells move into the hypoblast to form the embryonic endoderm.
Later cells move between epiblast and endoderm, becoming embryonic mesoderm.
Celle left in epiblast become embryonic ectoderm
Three layer stage

Raphe - Connective tissue that provides support to muscles meeting in the midline of the body.
Node - Important for setting up left-right symmetry
- Cilia within the node rotate creating leftward fluid flow.
Situs Invertus - Organs are mirrored from normal position

Formation of the notochord
Cartilage-like transient structure
Guides the folding of the embryo
Cranial midline extension to form hollow tube
Tube grows in length (cells added from primitive streak)
Primitive streak regresses
Mesodermal

Formation of neural plate and neural tube
Ectodermal cells above notochord thicken and differentiate
Extension and folding of neural plate
Convergence of neural folds
Neural tube closure

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Neural Plate
Induced by notochord
Cranial to primitive node
Ectodermal cells differentiate into thick plate of pseudostratified, columnar neuroepithelial cells = neuroectoderm

Neural tube
Formation = neurulation; derived from ectoderm.
Invagination of neural plate
Develops into the spinal cord and brain (CNS).
Neural crest cells give rise to: dorsal root ganglia, enteric ganglia, schwann cells, melanocytes

Segmentation of neural tube
Neural tube initially one layer thick and hollow
Cranial end begins to swell and forms vesicles which give rise to brain
Remainder of cranial cells give rise to spinal cord

Body folding
End of third week: embryo is flat, ovoid, trilaminar disc
Fourth week: embryo grows rapidly, especially in length
- Embryonic disc grows rapidly, yolk sac experiences almost no growth
- Developing notochord, neural tube, and somites stiffen dorsal axis
Growth of the neural tube drives embryonic folding

Germ Layers
Ectoderm outer layer
Epidermis, sweat glands and hair cells & epithelial lining of mouth & anus
Nervous system; nerves, spinal cord

Mesoderm middle layer
Paraxial mesoderm
Forms somites which produce muscle, bones, and dermis
Intermediate mesoderm
Forms the urogenital system
Kidneys, gonads, and respective duct systems
Lateral mesoderm
Divided into somatic and splanchnic mesoderm
Bones, heart, vasculture, wall of gut.

Mesoderm gives rise to all supporting tissue, dermis, muscle types, and blood vessels walls. Notochord.

Endoderm
Epithelial lining of digestive and respiratory tract (stomach and lung cells)
Liver, pancreas, thymus, thyroid and parathyroid glands (in pharynx)

Somitogenesis in paraxial mesoderm
Formation of somites
Somites - bilaterally paired blocks of paraxial mesoderm that form along the anterior-posterior axis of the developing embryo

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Gut tube
Lateral folding of the embryo completes the gut tube
Mesoderm is recruited to gut wall
Mesodermal layer of the gut tube from splanchnic mesoderm
Somatic mesoderm lines body cavity

Overview of germ layer fate

Development of cardiovascular system
Vasculogeneis - de novo assembly of blood vessels from mesodermally derived cells
Angiogenesis - blood vessels forming from preexisting vasculature

Development of stomach
Distal part of foregut, around middle of fourth week
Enlarges and broadens ventro-dorsally
Dorsal part grows faster than ventral part: greater curvature of stomach
90 degree rotation clockwise whilst growing
Ventral border (smaller curvature) moves to right, dorsal bored (greater curvature moves to left)
Rotation superiorally bends duodenum into C-shape

Development of other endodermal organs
Endodermal thickening, cells proliferate to form bud
Continuous lengthening and bifurcation/branching

Development of lungs
Ventral out-pocketing of endoderm= respiratory reticulum → will form trachea
Grows ventro-caudally. (forward-down)
#1 Bifurcation of lungs forms the bronchi.
#2 Bifurcation forms secondary bronchial buds. 3 buds on the right, 2 on left.
#3 Bifurcation forms tertiary bronchial buds and bronchopulmonary segments.
14 more branches until terminal bronchioles.

10
Gut and its derivatives
Foregut
Pharynx, oesophagus, stomach, proximal duodenum
Thyroid, parathyroid, thymus, lungs, liver, gallbladder, pancreas
Midgut
Distal duodenum, half of colon
Hindgut
Other half of colon to anus
Urinary bladder

Pharyngeal arches
Outer covering of ectoderm
Mesenchymal core derived from mesoderm as well as neural crest cells
Lines inside with endoderm

Each arch contains:
Central cartilaginous skeletal elements (Derived from neural crest)
Striated muscle rudiment (Derived from head mesoderm)
Arch-specific cranial nerve
Aortic arch artery (endothelial cells derived from mesoderm)

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 Membrane Potential
Active transport - direct expenditure of energy (via ATP hydrolysis) to pump Ca+ out of the cell against its concentration
gradient.
Facilitated diffusion - passive movement of ions down their concentration gradient

Selective permeability of the membrane to K+ allows positive charge to leave the cell
The K+ concentration gradient favours K+ efflux from the cell
The efflux of K+ from the cell carries positive charge out of the cell, leaving anions behind (which can’t pass)

Membrane potential - difference in charge across the cell membrane
Resting membrane potential - change difference across the membrane when it is at rest. Only leak channels active.
More permeable to K+, the more negative RMP will be because more K+ will leave the cell

Action potential phases
Depolarisation - Membrane potential increases to above 0mV.
Repolarization - Membrane potential decreases back towards RMP
Hyperpolarization - Membrane potential decreases to less than RMP (overshot); due to excess of K+ efflux

Nernst equation predicts equilibrium potential of any ion
Two sources of potential energy driving the movement of an ion; chemical concentration gradient, and electical charge
Equilibrium potential - When the two driving forces (chemical and electrical) are balanced, and net ion movement is zero.
Eₖ is typically more negative than the RMP.
If the conductance across the membrane for K⁺ increases, K⁺ will leave the cell and the membrane will hyperpolarize.
Increasing conductance for Na⁺ (potential needs to go up) will result in Na⁺ entering the cell, depolarizing the
membrane.

Driving force sum of all force on a particular ion pushing/pulling the movement of an ion
★ Driving force = membrane potential - nernst equation
Na has greater driving force than K
- Opening a Na+ selective ion channel will depolarise the membrane
- Opening a K+ selective ion channel will hyperpolarise the membrane
Monovalent cation channel - equally permeable to K+ and Na+

Channels
Leak channel - a channel that is always open
Voltage gated ion channel - An ion channel that opens or closes depending on the polarity of membrane potential.
Ligand gated ion channel - Open or closed state depends on the presence or absence of a ligand (chemical) bound to receptor
Mechano-gated ion channel - Mechanical stimulus opens or closes the ion channel. e.g. stretch, touch, baroreceptor

At rest, the membrane is more permeable to K+, so the membrane potential is closer to that of K+.

When Vm > Ek, K+ will flow out of the cell.
When Vm A NA > A NA and A A >> NA

Influence Direct innervation Direct innervation Direct & circulatory Circulating adrenaline

Overall Stimulation Inhibition Stimulation Inhibition
Effect

34
 Autonomic Pharmacology
Autonomic Nervous System
Targeting the ANS
Advantages
Potential to pharmacologically alter a variety of tissue/organ functions; good way.
Targeting the ANS has wide therapeutic opportunities
Disadvantages
Potential to pharmacologically alter a variety of tissue/organ functions; do harm.
Targeting the ANS has great potential for adverse effects

Responses occur when the ligand (neurotransmitter) binds to and activates its receptor.

Cholinoceptors
Nicotinic: ligand-gated ion channel, influx of Na+. Fast, enables ganglion transmission & skeleton muscle responses
Muscarinic: G-protein coupled receptors, intermediate response time, postganglionic parasympathetic responses
Adrenoreceptors
α,β-adrenoceptors: GPCR, intermediate, postganglionic sympathetic responses.

Modulating chemical transmission allows manipulation of autonomic & somatic tissue regulation.

Steps in chemical transmission
1. Action potential propagation and depolarization of nerve terminal
2. Synthesis
3. Storage
4. Release
5. Receptor activation
6. Reuptake
7. Degradation

Drugs affecting neurotransmitter release
Ca2+ dependent vesicular exposure
1. Vesicle docks at active zone
ACh filled synaptic vesicles have synaptobrevin (a SNARE protein) which forms a SNARE complex with target SNAREs
(snap-25 & syntaxin). This brings vesicle close to plasma membrane.
2. Increase in Ca2+ sensed by synaptotagmin (protein) found on vesicle membrane
3. Ca2+ bound synaptotagmin triggers membrane fusion leading to neurotransmitter release
4. ACh binds to nicotinic receptors leading to muscle contraction

Botulinum Toxin
Heavy chain binds with high-affinity to specific receptors on the membrane of terminals containing ACh. Impacts cholinergic
transmission. Causes light chain to cleave SNARE proteins → SNARE complex can not form → Inhibit release of Ach →
neurotransmitter not released → muscle fibre paralysed.
Botulinum Poisoning
Caused by c.botulinum; anaerobic bacteria found in soil, plants and water - produce toxin under anaerobic conditions.
Progressive motor paralysis (varying degree of muscle weakness)
- Difficulty swallowing, facial weakness (droopy eyelids, hanging jaw), trouble talking, limb paralysis, may
progress to respiratory paralysis
Inhibition of parasympathetic-mediated effects
- Dry mouth, dry eyes, urinary retention, constipation
- Anti-SLUD (salivation, lacrimation, urination, defecation)
35
Transformed from poison to medicine
Cosmetic use: paralyses superficial muscles that pucker the skin to smooth wrinkles (local injection)
Clinical use: unwanted movement disorders, urinary incontinence associated with bladder overactivity, hyperhidrosis
(excessive sweating)

Drugs affecting neurotransmitter uptake
Inactivation of sympathetic neurotransmission via reuptake
Primary process: Neuronal uptake via high-affinity NA transporter (NET)
Secondary process: Extranauronal uptake via low-affinity organic cation transporter (OCT3)
- Following reuptake: NA is transported into vesicles via vesicular monoamine transporter (VMAT) for re-release
If not transported, it is metabolised by monoamine oxidase (MAO) in nerve terminal
Any NA taken up bt OCT3 also undergoes metabolism by COM in non-neuronal tissue.

Uptake inhibitor - Cocaine
1. Cocaine inhibits NET (NA transporter) → inhibits reuptake of of noradrenaline into nerve terminal
2. Greater concentration of NA in junction and prolonged presence in junction
3. More noradrenaline to bind and activate post-junctional adrenoceptor
→ enhanced tissue response (sympathomimetic)

Indirectly acting sympathomimetics (IAS) (mimic tissue responses of sympathetic activation indirectly)
Structurally similar to NA
1. Transported into nerve terminal by NET
2. Transported into vesicles by VMAT in exchange for NA.--> NA displaced into cytosol.
3. High amount displaced cytosolic NA exits the nerve terminal via NET (Ca2+ independent)
4. NA activates post-junctional adrenoceptors thus IAS are sympathomimetic.
5. IAS an be metabolised by MAO in the cytosol

e.g. pseudoephedrine
Nasal decongestant. Constricts arteries in nasal mucosa with limited central effects.

Inactivation of cholinergic neurotransmission via ACh metabolism →
1. Presynaptic terminal releases ACh
2. Release of ACh from synaptic vesicle binding to nicotinic receptors to elicit skeletal muscle contraction
3. ACh can be rapidly metabolised by AChE (acetylcholinesterase) → choline & acetic acid
4. Choline (precurses of ACh) can be taken back up into nerve terminal to make more ACh

Drugs inhibit AChE
AChE metabolises ACh
Anticholinesterases or acetylcholinesterase inhibitors
e.g. neostigmine for Myasthenia Gravis, or to reverse nondepolarizing skeletal muscle blockage

Normal NMJ function
1. Arrival of single nerve impulse releases a package of ACh
2. ACh binds to and activates nAChRs (nicotinic receptors) to elicit end plate potential
3. Influx of sodium ions in skeletal muscle fibre → end plate potential → skeletal muscle contraction
4. ACh is rapidly hydrolysed by AChE which helps end tissue response.

36
Myasthenia Gravis
1. Auto-antibodies block and target nAChRs for degradation
2. Less nAChR available to bind to ACh
3. Most ACh released following arrival of impulse rapidly degrade before sufficient receptors are activated
4. Only a weak end plate is generated → doesn’t reach threshold
5. Muscle weakness

Myasthenia Gravis: Treatment with Neostigmine
Neostigmine (acetylcholinesterase inhibitor)
1. Neostigmine inhibits AChE which prevents ACh metabolism
2. Enables lateral diffusion of ACh to bind to unaffected nAChRs (not yet targeted for degradation of antibodies), and
rebinding of ACh
3. Restores cholinergic transmission in NMJ (restore skeletal muscle contraction) leading to symptomatic improvement.

Sympathetic nerve-mediated responses
Numerous smooth muscles have different response to sympathetic activation (relatation, contraction, constriction etc)
Due to differences adrenoceptors - Control different biochemical pathways, and hence different physiological
responses.

Therapeutic benefits of selectively targeting a receptor subtype
- Elicit wanted responses and minimise adverse effects

Cholinergenic receptors: Muscarinic
Effects mediated by PNS: DUMBBELLS - defecation, urination, miosis, brachycardia, bronchoconstriction, emesis, lacrimation,
salivation
Atropine
Competitive reversible muscarinic receptor antagonist
Binds to the same sites as ACh on muscarinic receptors. Does not activate the receptor; it inhibits responses.
- Uses: Reduce secretions during anaesthesia, and treats anticholinesterase poisoning.

Cholinergic receptors: Nicotinic
Ligand gated ion channels
Two major subtypes
N1: Neuromuscular junction
N2: Autonomic ganglia

Numerous functional receptor isoforms identified. Differences in subunit comparison can lead to differences in:
Cation permeability
Physiological function
Pharmacological properties
- D-tubocurarine - nAChR antagonist (NMJ)
- Hexamethonium - nAChR antagonist (autonomic ganglia)

d-Tubocurarine:
Competitive reversible nicotinic receptor antagonist
Located in NMJ but also autonomic gangle at higher concentrations
Use: Neuromuscular blocking drug (muscle relaxant in anaesthesia - obsolete)
Adverse effects: Hypotension due to ganglion-block. Replaced with drugs that are less effective at autonomic ganglia.
E.g. pancuronium
- Used as an arrow poison due to its ability to paralyse skeletal muscles by blocking the neuromuscular junction
Can’t cross mucus membrane, humans can safely consume poisoned animals.
37
 Foundations of Anatomy

Cardinal planes and axes
Coronal (frontal): divides anterior and posterior
Sagittal (medial): divides left and right
Transverse: divides upper and lower

Comparison terms
Superficial: nearer to surface
Intermediate: between a superficial and deep structure
Deep: furthest from the surface

Hands: Palmar and dorsal (back); palmer posterior is anatomical position.
Feet: Plantar and dorsal (superior)

Movements
Flexion: bending, or decreasing the angle between body parts or bones
Extension: straightening, or increasing angle
Abduction: moving away from the midline
Adduction: moving towards the midline
Medial rotation: rotation toward the midline
Lateral rotation: rotation away from the midline
Elevation: movement in a superior direction (up)
Depression: movement in an inferior direction (down)

Protrusion: movement anteriorly
Retrusion: movement posteriorly
Protraction: anterolateral movement of scapula
Retraction: posterolateral movement of scapula

Pronation: rotation of radius medially so that the palm faces posteriorly from anatomical position
Supination: rotation of the radius laterally so the palm faces anteriorly.

Dorsiflexion: flexion of the ankle joint, lifting the front of the foot and toes off the ground
Plantarflexion: bending the foot and toes toward the ground (tippy toes)
Eversion: movement of the sole of the foot away from the midline (abduction)
Inversion: movement of the sole away from the midline (adduction)

38
 Muscular system & muscles
Muscle function
Produce movement
- Skeletal muscle for all locomotion and manipulation
- Cardiac muscle pumps blood
- Smooth muscle propels substances (food, water)
Maintain posture and body position: Skeletal muscle maintain posture, counteract gravity
Stabilise joints
Generate heat: Muscles generate heat when they contract; thermogenesis.

Properties of muscular tissue
Electrical excitability: Ability of muscle to respond to stimulus to produce action potentials
Contractibility: Contracts forcefully when stimulated by an action potential
Extensibility: Ability to stretch without being damaged (determined by connective tissue in the muscle)
Elasticity: Ability to return to original length and shape after contraction and extension

Types of muscles
Skeletal muscle
Striated
Voluntary
Cardiac muscle
Striated
Visceral
Smooth muscle
Unstriated

Increased use of muscle = minimal adipose tissue = healthy

Structure of skeletal muscle
Fibre: individual muscle cell wrapped in endomysium
Fascicle: bundle of individual muscle fibres wrapped in perimysium
Muscle: lots of fascicles wrapped in epimysium

Patterns of fascicle arrangement
Muscles have different shapes due to the arrangement of their fascicles
Muscles generate power by contracting or shortening their fibres which generates tension
Muscle fibres contract and lengthen only in the direction of their fascicles

Different fascicle patterns
Circular, Convergent, Parallel, Pennate

Circular fascicle arrangement
Fascicles arranged into concentric rings
Muscles surrounding external body openings (sphincters)
Opens/closes sphincters via contraction

Convergent fascicle arrangement
Broad origin, fascicles converge toward a single tendon
Strongest contraction
Triangular or fan shaped

39
Parallel fascicle arrangement
Length of fascicles runs parallel to the long axis of muscle
Greatest shortening during contraction
Straplike (sartorius) or,
Spindle shaped with an expanded belly (biceps)

Pennate fascicle arrangement
Short and attach obliquely
Unipennate: fascicles insert only one side of the tendon
Bipennate: fascicles insert onto the tendon from opposite sides
Multipennate: fascicles insert onto the tendon from many directions

Muscle attachment
Most skeletal muscles span joints and attach to bones/structures in at least two places.
Muscle contractions causes movement at the joint
When skeletal muscle contracts, it moves the articulating bones:
- One bone remains stationary, whilst the other bone is pulled toward the stationary bone
- Insertion moves toward origin (distal to proximal)
Muscle movement caused by exerting force on tendon

Connective tissues associated with muscle
Tendon: muscle belly to bone
Aponeurosis: muscle to bone (broader, flatter, greater area than tendon)
Raphe: muscle to muscle (line of fibrous tissue)
Ligaments: bone to bone (composed of collagen fibres and blend with periosteum)

Muscle fibres contract in response to innervation, and shorten only in the difection of their fasicle
Isometric contraction: Length does not change. No movement. (plank)
Concentric contraction: Muscle fibres shorten. Muscle force exceeds force of gravity. (rasing barbell)
Eccentric contraction: Muscle lengthens. Gravity exceeds muscle force (lowering barbel)

Arrangements of muscle permits them to work together or in opposition to produce movements
Prime mover: main muscle responsible for producing a specific movement (concentric)
- e.g. biceps brachii prime mover of elbow flexion
Synergist: complement action of prime mover by adding extra force or removing unnecessary movement.
- e.g. brachialis synergist of biceps in elbow flexion
Antagonist: muscle that opposes action of another muscle (eccentric)
- e.g. triceps brachii opposes biceps during elbow flexion
Fixator: steadies proximal parts of a limb while movements occur in distal parts (isometric)
- e.g. rotator cuff muscles stabilise shoulder during elbow flexion

★ The action of a muscle can be inferred by the position of the muscle relative to the joint it crosses.

Above the knee, a muscle that crosses
anteriorly produces flexion
posteriorly produces extension
on the lateral side produces abduction
on the medial side produces adduction

40
Fascia wrap, package and insulate deep structures.
Superficial fascia - loose subcutaneous tissue
Deep fascia - thin, rough sheet made primarily of collagen fibres
- Strong, inelastic, no fat, covers most of the body, not found where expansion is required

Deep fascia structures
Fascial septum: extension of dense connective tissue
Retinaculum: thickening of deep fascia that holds down tendons

Neurovascular supply
One nerve, artery, and one or more veins serve each muscle. All enter or exit near centre of muscle.
Every skeletal muscle fibre is supplied with a nerve ending that controls activity.
Muscles have a rich blood supply.
Lots of energy, oxygen, and nutrients required (delivered via arteries)
Metabolic waste is produces (removed via veins)

Receive blood supply via muscular branches from adjacent arteries; drained via veins (huge blood supply)
Individual muscle fibres are in close contact with capillaries
Major source artery and vein enter muscle belly via neurovascular hilum
Motor nerves supplying skeletal muscle always enter the belly from a deep aspect.

Skeletal muscle is voluntary. Brain sends electrical signals down to the spinal cord, through nerves that activate fibres and
muscles contract.

Motor unit - a motor nerve fibre and all of the muscle fibres it innervates.
Motor neuron in ventral/anterior horn of spinal cord is stimulated by impulses down descending pathway
All muscle fibres supplied by that neuron contract simultaneously

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 Skeletal system & bones
Bone function
Support
Protection
Movement: skeletal muscle attach to bone; contraction pulls on bone to produce movement
Mineral homeostasis
Blood cell production: Red bone marrow produces red blood cells, white cells, and platelets
Triglyceride storage: Yellow bone marrow stores triglyceride in medullary cavity

Axial skeleton consists of about 80 bones
- (head, neck, trunk (ribs, vertebral column, sacrum)
Appendicular skeleton consists of about 126 bones.
Appendages (arms and legs)- limbs including pelvic and pectoral, clavicle, agnomical bone (hips)

Bone is a form of connective tissue; contains extracellular matrix surrounding cell
Contains organic compounds (collagen, water), and crystallised mineral salts (calcium phosphate, makes the bone
opaque)
- Deposited in collagen of extracellular matrix then hardens - calcification

Bone anatomy
Compact bone: Dense bone that forms outer shell. Composed of osteons.
Spongy bone: Underneath the compact shell. Composed of lamellae, arranged into trabeculae.
Periosteum: Dense layer of vascular connective tissue that surrounds bone (except at the surface of joints).
Bone shapes
Long bone: Bear a lot of weight
Short bone: Wide and good for support (includes sesamoid)
Flat bone: Flat, slightly served and good for protection
Irregular bone: Complicated shapes.

Long bone anatomy
Diaphysis: forms the long axis of bone
Epiphysis: proximal and distal ends
Metaphysis: between epiphysis & diaphysis. Contains epiphyseal growth plate.
Medullary cavity: Hollow space within diaphysis. Filled with yellow (fg at) marrow + blood vessels. Lined by
endosteum.
Articular cartilage (hyalin cartilage): covers the joint surface.
Endosteum: thin membrane, lines medullary cavity, internal bone surfaces, trabeculae, lines canals of compact bone

Vascular supply of bone
Bones are vascular and non innervated.
Periosteal arteries: supply periosteum and outer compact bone. Enter through small canals.
Large nutrient artery: enters via nutrient foramen at centre of diaphysis through compact bone. Enters medullary cavity,
courses toward epiphyses. Divides into medullary branches.
- Ends of long bone supplied by epiphyseal and metaphyseal arteries.

Periosteum nerves supply the periosteum. Carry small pain fibres which makes it sensitive to tearing.
Bones have sparse nerve supply, broken bones don’t hurt, the periosteum does.

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Cell types
Osteoblasts: bone building cells (bone deposit)
Synthesis and secrete collagen fibres, organic components to build the extracellular matrix of bone. Initiate calcification
Osteoclasts: break down bone ECM (bone resorption)
Releases lysosomal enzymes and acids to digest proteins and mineral components of the extracellular matrix (ECM).

Bone formation (ossification)
All bones are derived from mesenchyme (embryonic connective tissue) by one of 2 processes. During fetal development.
1. Intramembranous ossification: directly from mesenchyme
Mesenchymal models of bone form during embryonic period. Simple process.
2. Endochondral ossification: from cartilage derived from mesenchyme
Cartilage models of bones form from mesenchyme during foetal period, bone replaces cartilage

Intramembranous ossification
1. development of ossification centre. Cells differentiate.
2. Calcification occurs once ECM surrounds the cell
3. Formation of trabeculae; ECM develops into spongy bone
4. Development of periosteum
Flat bones of skull, facial bones, mandible, medial part of clavicle, form via intramembranous ossification.

Endochondral ossification
1. Development of cartilage model
2. Cartilage model grows
3. Development of primary ossification centre in diaphysis
4. Development of medullary cavity from ossification centre
5. Development of secondary ossification centre in epiphysis
6. Formation of cartilage and epiphyseal plate

Bone growth occurs in length and diameter until adolescence. Then only in diameter.
Epiphyseal cartilage → epiphyseal plate. Height growth stops once epiphysis closes.
Longitudinal bone growth
1. Interstitial growth of cartilage on the epiphyseal side of the epiphyseal plate
2. Replacement of cartilage on the diaphyseal side with bone via endochondral ossification

Appositional bone growth
Growth in width. New bone deposited on outer surface, old bone inside is destroyed.
Medullary cavity enlarges as bone increases in thickness

Epiphyseal plate: layer of hyland cartilage in the metaphysis
Chondrocytes proliferate on epiphyseal side. New chondrocytes replace older ones which are destroyed by calcification.
Epiphyseal plate → epiphyseal line.

Bone remodelling - combination of bone deposit (by osteoblasts), and bone resorption (by osteoclasts).
Factors: vitamins and minerals, exercise, hormones. Females undergo increased bone loss due to menopause.

Bone markings types
Sites of muscle and ligament attachment
Tuberosity, crest, trochanter, line, tubercle, epicondyle, spine, process
Projections that help to form joints; Head, facet, condyle, ramus
Depressions and openings for passage of nerves and vessels; Groove, fissure, foramen, notch, meatus, sinus, fossa

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 Articular system & joints
Joint is a point of articulation between two bones. Classified based on:
Presence or absence of space between articulating bones (i.e. synovial cavity)
Type of connective tissue that binds bones together (i.e. cartilage)

Cartilage is a flexible connective tissue, good for flexibility.
Nourished via diffusion, no blood vessels or nerves. Consists of a dense network of collagen and elastin fibres

Types of cartilage
Hyaline: Most common type, covers bony articular surfaces (epiphyseal). Found in nose, larynx, trachea bronci
Elastic: Flexible, contains a bundle of elastic fibres. Found in external eat, epiglottis.
Fibrocartilage: Forms specialised joints. Strongest cartilage. Fibrous tissue + hyalin cartilage, most collagen fibres.
Found in anterior hip joint.

Types of joints
Synovial (moveable)
Bones united by a joint/articular cavity.
Fibrous (solid, minimal movement)
Bones united by fibrous tissue
Degree of movement depends on length of fibres
Cartilaginous (solic, menial movement)
Provide strength and shock absorption

Fibrous joints
Solid. No joint cavity, held together by a dense irregular connective tissue
Sutures: Thin layer of connective tissue called a sutural ligament in skull
Gomphosis: Short collagen fibres running between root of tooth and bony socket. Periodontal ligament.
Syndesmosis: Occurs where two adjacent bones are linked by a ligament.

Cartilaginous joints
Immovable. No joint cavity, joined by hyalin or fibrocartilage.
Synchondroses: Bar or plate of hyalin cartilage between two ossification centres of a developing bone (growth plate)
Symphyses: Fibrocartilage connecting two separate bones. Permits limited movement.

Synovial joints
Plane joint
Allow sliding or gliding movement when one bone moves across the surface of another
Nonaxial
Hinge joint
Concave surface of one bone wraps around the convex surface of another
Uniaxial
Flexion/extension
Pivot joint
Rotation along its longitudinal axis
Uniaxial
Condylar joint
Convex oval projection of one bone fits oval depression of another
Biaxial
Flexion, extension, adduction, abduction

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Saddle joint
Biaxial. Allows more movement than condylar joint.
Biaxial
Flexion, extension, adduction, abduction
Ball-and-socket joint
Allows movement around all 3 anatomical axes; multiaxial
Flexion, extension, adduction, abduction, circumduction, rotation

Features of synovial joints
Articular cartilage
Hyalin cartilage covers articulating surfaces of bones
- Differs to synchondrosis joints as in that case cartilage joints to the bone. By coating it, maximal movement is enabled.

Joint capsule
Synovial cavity filled with fluid. Surrounded by 2 layered structure.
Inner synovial membrane: highly vascular, secretes synovial fluid
Outer fibrous membrane: dense connective tissue, attaches to periosteum (continuation)

Synovial membrane: Inner layer of double layer articular capsule. Connective tissue, lots of elastic fibres.
- Secretes synovial fluid; removes friction at joint, and is shock absorber. Supplies O2, removes waste.

Fibrous capsule: Encloses the synovial joint. Structures beyond this are intracapsular.
- High amount of tensile strength, lots of movement. Dense connective tissue made of collagen fibres.

Accessory structures
Articular discs and menisci intracapsular.
Made of fibrocartilage and connective tissue. Divides synovial cavity into two. Stabilises joint, and aids shock
absorption.

Labrum extracapsular
Fibrocartilage lip that extends from the edge of the joint socket. Depends the socket, increases contact surface area.

Fat pads intracapsular, extrasynovial.
Act as space fillers, helps spread synovial fluid.

Bursae and tendon sheaths extracapsular
Flattened fibrous sacs lined with synovial fluid, used as a lubricant to reduce friction.

Factors that affect movement of synovial joints
- How well the bones fit together. How strong and tight the joint is. Additional ligaments. Muscles that wrap around the
joint.

Joint Mobility
Range of motion (ROM): the range, measured in degrees of a circle (360) through which the bones of a joint can be moved.
6 factors
Structure/ shape of articulating bones
Strength and tension of joint ligaments
Arrangement and tension of muscles (Flexed thigh restricts hip flexion. Flexed knee increases hip flexion)
Contact of soft parts (ROM restricted when skin presses against skin)
Hormones
Disuse
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 Vertebral Column & Back
Function of vertebral column
Structure, Movement, Protection

First secondary curvature - Cervical
Second secondary curvature - Lumbar
Accentuated primary curvature = kyphotic
Accentuated secondary curvature = lordotic

Vertebra

Intervertebral contents
Spinal nerve roots Dorsal root ganglia Vessels

Intervertebral Joints discs
Annulus fibrosus
Attaches to epiphyseal ring. Keeps vertebrae together. Concentric lamellae of collagen.
Permits multiaxial movement and resists excessive rotation.
Nucleus Pulposus: Surrounded by annulus fibrosis. Keeps vertebrae apart. Absorb shock. Deforms.

Zygapophyseal Joints: Plane synovial joints formed between superior and inferior facets of vertebral bones.

Major Ligaments
Ligaments allow extra stretch
Posterior longitudinal
Anterior longitudinal
Interspinous
Supraspinous
Ligamentum flavum

Muscles of the back
Extrinsic - primarily attach to upper limb. Intrinsic - primarily attach to and act on the back

Erector spinae - primary movers
Concentrically extend the trunk
Eccentrically control trunk flexion

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 Upper Limbs
Bones & Joints
Upper limb - Attaches to anterior aspect of axial skeleton

Shoulder Girdle (clavicle & scapula)
Clavicle
Provides only upper limb articulation between appendicular & axial skeleton
Sternum and acromial ends

Scapula Clavicular Joints - sternoclavicular & acromioclavicular

Sternoclavicular
Saddle joint
Intra Articular disc
Strong capsule

Acromioclavicular
Plane joint
Strong coracoclavicular
ligament, weak capsule.

Humerus Ulna & Radius Elbow Joint
Hinge joint
Glenohumeral Joint Strong collateral ligament support
Ball and socket joint Humero-ulnar contact
Large humeral head + shallow glenoid fossa

Supportive features
Specialised fibrocartilage: glenoid labrum =
‘incongruent
Muscular: rotator cuff
Ligament: glenohumeral & coracohumeral

Proximal & Distal radio-ulnar joints Bone groups of the wrist & hand
Proximal - Pivot joint Sesamoid bones - metacarpophalangeal
Radial head to radial notch on ulna
Distal - Pivot joint
Ular head to ulnar notch on radius

Radiocarpal joints
Condyloid/Ellipsoid joint
Ulnar-carpel contact

Joints of the hand Joints of the fingers
Intercarpal joints Metacarpophalangeal joint - condyloid
Caropmetacarpal joints Interphalangeal joint - hinge
1st joint - saddle (thumb)
2-5th joint - plane
Opponens pollicis (thumb muscle)

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 Upper Limbs
Muscles, vessels, and nerves
Axio-appendicular muscles

← Anterior View
Pectoralis Major
Attaches to humerus
Movement & internal rotation

Pectoralis minor
Attaches to coracoid process
Helps tilt scapula over thoracic case
Secondary muscles for respiration

Scapulohumeral muscles
‘Rotator cuff’ muscles
Supraspinatus: superior to spine
Infraspinatus: inferior to spine; traverse over back
Teres Minor: lateral border; traverse over back
Subscapularis: anterior

Collective function: blend with joint capsule & compress humeral head into glenoid fossa.

Major movements
Abduction (supraspinatus)
External Rotation (infraspinatus and teres minor)
Internal Rotation (subscapularis)

Deltoid & Teres Major
Attach more distally on the humerus than rotator cuff
Deltoid
Prime mover
Produces shoulder flexion, abduction, and extension
Fan from humerus to scapula and clavicle
Teres Major
Attaches more anteriorly to humerus (from superior back)
Internal rotation at shoulder

Upper limb compartments & deep fascia
Muscles are separated into compartments by intermuscular septa
Deep fascia can be specialised

Arm Muscles Anterior Compartment
Biceps brachii (crosses elbow; flexor)
Coracobrachialis
Bracialis (crosses elbow)
All cross over in the anterior aspect of at least one joint and produce flexion)

Pronation muscles
Pronator teres Arm Muscles Posterior Compartment
Pronator quadratus Triceps Brachii (Extensor)
Flexor carpi radialis
All cross over at least one joint
Supination muscles to attach onto olecranon process
Supinator and produce extension.
Biceps brachii

Long head produces extension.

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Forearm muscles Anterior Compartment
Attach to carpal/metacarpal = wrist flexor
Attach to digits = finger flexor
Distal attachment to radius = pronator

Finger flexion: caused by muscles in anterior forearm, and palm

Forearm muscles Posterior Compartment
Attaches to caral/metacarpal = wrist extensor
Attaches to digits = finger extensor

Finger extension: Caused by muscles in posterior forearm, and dorsum of hand

Lateral epicondyle of humerus provides attachment for multiple superficial muscles

Hand Musculature
Thenar - radial side of hand; thumb muscle
Hypothenar - ulnar side; opponens digiti minimi
Interosseous - between the metacarpals

Brachial Plexus Organisation
Complex intertwining of axons and sensory supply to distinct regions of upper limb
Spinal roots: C5, C6, C7, C8, T1.

Anterior Nerves Posterior Nerves
Musculocutaneous Nerve
Continuation of the lateral cord
Anterior compartment of the arm Axillary nerve
Lateral cutaneous Immediately exits out of axilla (armpit)
Wraps humerus to supply deltoid & teres minor
Median nerve superior lateral cutaneous
Medial & lateral cord
Major supply for anterior forearm Radial nerve
Minor supply of hand musculature Largest branch of posterior cord
Anterior interosseous nerve arises Passes anteriorly over lateral epicondyle
Long posterior journey
Ulnar nerve Significant supply to posterior upper limb
Continuation of medial cord Arm & forearm
Posterior to medial epicondyle Arises from all 3 posterior trunks
Major supply of hand musculature Most cutaneous innervation
Minor supply for the anterior forearm
Passes superficial to metacarpal

Major upper limb arteries
Transverse over flexor side of joints. Anastomoses at joints.
Brachial artery - occluded during blood pressure reading
Ulnar artery - Larger branch. Principal supply for upper limb
Radial artery anastomoses with ulnar artery via palmar arch. Palpable.

Superficial Venous and Lymphatic network
Superficial veins
Highly variable, commonly visible
Begin on posterior hand as ‘dorsal venous arch’
Easily accessible
Lymphatic vessels
Follow superior veins
Flow into ancillary lymph nodes

Deep Venous pathway
Deep veins accompany major arteries
Two veins present on either side of the artery.

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 Lower Limbs
Bones & Joints
Sacrum articulates to pelvic bone
Lower Limb
Significant weight bearing
Bony framework position changes vital for upright posture and gait
Lateral shift of ala of the ilium

Line of gravity: behind hip joint, in front of knee, way in front of ankle

Pelvic Girdle
Interface between axial skeleton and lower limb
Ring structure permits force transfer and protection of pelvic contents
‘Hemipelvis’ formed by fusion of three bones
Female pelvis is less vertical, larger, weaker, wider.

Ala means ‘wing’ and is the large fanned superior component of the
ilium bone.

Sacrospinous ligament: splits
sciatic foramen into greater and
lesser.

Pelvic Girdle Joints
Sacroiliac joint (Sacrum-iliac)
Synovial joint
Significant ligamentous support for weight bearing
Sacroiliac ligaments
- Sacrotuberous and sacrospinous

Pubic symphysis (pelvic bones) Illium, ischium, and pubic articulate with femur.
Secondary cartilaginous joint (symphysis)
Direct articulation of pubic bones anteriorly

Femur
Largest bone in the body

Hip joint
Ball and socket joint
Large femoral head + relatively deep acetabulum = congruent (deeper than shoulder socket)
Least stable during full flexion

Supportive features
Specialised fibrocartilage: Acetabular labrum
Strong fibrous capsule
Ligament: iliofemoral, pubofemoral & ischiofemoral
- All blend into fibrous capsule.

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Tibia and Fibula
Tibia is larger; the weight bearing bone. More medial.
With significant articular surfaces at the tibial plateau and trochlear notch

Knee Joint
2 synovial joints within one capsule
Patellofemoral (femur to patella)
Tibiofemoral (femur to tibia)

Modified hinge joint
Allows flexion, extension, rotation.
Medial & lateral meniscus improves contact, absorbs shock, spread synovial fluid.
Strong ligamentous support but highly susceptible to damage. MCL, LCL, ACL, PCl ligaments.

Cruciate ligaments (ACL + PCL)
ACL more prone to damage.

Collateral ligament (LCL + MCL)
Medial resists valgus, lateral resits varus force.
Medial more prone to damage due to attachments.

Tibiofibular Joints
Superior Plane joint
Inferior Fibrous joint (syndesmosis)
Prevents tibia and fibula from separating.
Good stability + low loading → dislocation rare

Talocrural Joints (talus to leg)
Hinge joint (complicated)
Dorsiflexion & plantarflexion

Trochlea of the talus is wider and more anteriorly. This contributes to increased stability when the ankle is
dorsiflexed.

Bones of the foot
Short (tarsals)
Long (metatarsal, phalanges)
Sesamoid bones

Joints of the foot
Intertarsal
Tarsometatarsal
Metatarsophalangeal
Interphalangeal
1st metatarsophalangeal joint (toe) vital in creating efficient loading through the lower limb in gait.

Important movement of subtalar and midtarsal regions.
Inversion: rolling foot medially
Eversion: rolling foot laterally.

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 Lower Limbs
Muscles, nerves, and vessels
Pelvic girdle
Anterior
Iliacus + psoas major = ‘iliopsoas’
Strong hip flexor

Piriformis muscle
Gluteal region
Lateral rotation, abduction

Posterior
Gluteus maximus - hip extensor
Gluteus medium & minimus - hip abductors

Thigh Muscles Anterior compartment
Sartorius (hip flexion)
Quadriceps femoris
Vastus medialis, vastus lateralis, vastus intermedius, rectus femoris
Quadriceps femoris cross the anterior knee via soft tissue structures and the patella (knee extension)

Thigh Muscles Posterior compartment
Hamstrings
Semitendinosus, Semimembranosus, Biceps femoris (long and short heads)
Bicep does flexion only.
Cross the posterior aspect of the hip and knee joints → hip extension and knee flexion. Contribute to knee rotation.

Leg Muscles
Anterior Compartment Intrinsic foot muscles
Dorsiflexors & Toe extensors
← Plantar view
Lateral Compartment 3 major groups
Eversion & Weak plantiflexer
Hallucis muscles - 1st digit (big toe)
Posterior Compartment Digiti minimi muscles (5th digit (small toe)
Superficial Central muscles - varied attachment
Strong plantar flexors

Deep Dorsal view →
Plantar Flexors & toe flexors

Ankle tendon: Fibularis brevis & fibularis longus.
Crosses the ankle posterior to lateral malleolus.

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Fibularis Tertius tendon crosses ankle posterior to lateral malleolus and cross planter to surface of foot to attach to 1st metatarsal.
Lower limb neural overview
Lumbar and lumbosacral plexus supply the lower limb in addition to
components of the pelvis and lower abdomen

Anterior
Femoral nerve
Saphenous nerve
Receives input from L2-L4 anterior rami
Travels lateral to the psoas major
Leaves the abdomen by travelling deep to inguinal ligament with
major femoral vessels
Innervates anterior thigh

Obturator nerve
Receives input from L2-L4 anterior rami
Travels medial to the psoas major
Leaves the pelvis via the obturator canal
Splits into two branches; supplies medial thigh

Sciatic nerve
Main nerve
Supplies all leg and foot muscles.
Receives input from L4-S3 anterior rami
Forms within the pelvis, leaves via greater sciatic foramen
- Inferior to the piriformis
Two nerves in a common sheath; tibial, common fibular.

Common Fibular nerve
Travels posterior to knee joint
Wraps around the fibular neck and splits into two
Superficial fibular nerve (supplies lateral compartment)
Deep fibular nerve (supplies anterior compartment & dorsal foot)
Supplies lateral & anterior leg + dorsal foot
musculature

Tibial nerve
Travels posterior to knee joint
Supplies posterior leg compartment
Supplies majority of foot musculature (plantar)
Travels through tarsal tunnel to enter foot.

Major lower limb arteries
Abdominal branching gives ride to external iliac artery
External iliac artery → femoral artery when passes deep
to inguinal ligament
Femoral artery → popliteal artery
Femoral artery passes through adductor hiatus (anterior → posterior) to enter posterior thigh.
Femoral artery - initial incision and entry for embalming donors.

Major lower limb veins
Muscular venous pump is important for venous return
Venous valves permit a unidirectional flow

Lower limb lymphatics
Drainage courses
Planter digital vein → posterior tibial vein → popliteal vein → femoral vein
Dorsal venous arch → great saphenous vein → femoral vein

Drainage follows the path of the superficial veins of the lower limb
Drainage progresses for both limbs to enter the cisterna chyli and thoracic duct.

Superficial veins on left, deep veins on the right →

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 Vascular system and vessels
Circulatory System
Cardiovascular system
Pulmonary circulation (O2 poor blood to lungs for oxygenation)
- From pulmonary arteries
System Circulation (O2 rich blood to the body for circulation)
- From systemic arteries
Lymphatic system
Fluid in interstitial spaces
Drains surplus tissue fluid, plasma proteins, removal of debris from cellular decomposition, infection
Lymph plexuses; dense concentrations of lymph nodes, vessels, and extra tissues)

Development of vascular and lymph system
Vascular system is mesoderm derives; only present in mesoderm
Avascular and non-lymph structures: Epidermis (ectoderm); surface epithelium (endoderm); articular cartilage
(exception-mesoderm derived)

Types of blood vessels
3 types of blood vessels: arteries, veins, capillaries
All blood vessels have 3 layers (tunis) surrounding the (lumen)
Final distributing vessel arterioles, deliver O2 rich blood to capillaries
Arteries
Oxygen-rich blood away from the heart, excluding blood leaving right ventricle which goes to lungs to be oxygenated.
Blood under high pressure leaves the heart via arteries
High calibre vessels → low → Capillary bed → veins
Thicker tunic, smaller lumens
Greater smooth muscle composition than veins
Veins
Deoxygenated blood back to the heart
Thinner tunic, larger lumen; carries more blood than arteries (bigger)
Capillies
Capillary bed; nutrient and gas exchange takes place

Tunics of blood vessels
Tunica intima
Innermost lining, flattened epithelial cells supported by delicate connective tissue
Capillaries have only thus tunic basement membrane
Tunica media
Middle layer, mainly smooth muscle
Most variable - thickness relative lumen differentiates arteries, veins, lymphatic ducts
Tunia adventitia
Outermost connective tissue layer of the sheath

Arteries
Clinical importance
Arterial Bleeding - Blood flow in elastic and muscular arteries is pulsatile and at high pressure.
- Reflects systole and diastole; ventricle contraction and relaxation
- Blood tends to spurt and will be pulsatile blood flow when laceration to arterial vessels.
Venus bleeding - Continuous low-pressure flow from capillaries, thin-walled veins.

54
 - Veins have larger lumen, less elasticity and lower amounts of smooth muscle, largely held open by volume of blood.
- Laceration to vein will be low pressure, and continuous seeping.
Anastomoses
- Links between arteries or between arterioles.
- Provides potential detours for blood flow (collateral flow) if the usual pathway is obstructed. By joint position,
pathology, or surgical ligation
- Adjacent arteries tend to anastomose, and occur around joints, are significant only in muscle belly that crosses joint
End arteries
- Do not link with other arteries; no anastomose. Is not a ‘dead end’ - still branches into capillary beds drained by veins

Blood passes through arteries of larger to smaller calibre.

Types of arteries
Large elastic arteries (conducting)
Many elastic layers, resulting in the smooth flow of blood
Near the heart, aorta and its major branches
Medium muscular arteries (distributing)
Circular smooth muscle fibres, capable of vasoconstriction + blood flow
regulation
Majority of named arteries
Smooth muscle (autonomic) can contract vessels to reduce blood flow.
Small arteries and arterioles
Narrow lumina, thick smooth muscle walls
Flow into capillary beds, tonus regulated arterial pressure in vascular system
Can regulate blood flow and arterial pressure via vasoconstriction and
vasodilation

Heart pumps blood out at a high velocity and pressure. Elasticity in the large layers
compensate for the spurting high velocity and smooths it out creating a continuous blood
flow, rather than it being start and stop like heart beats.

Principles of arteries of the limbs
1. Single stem artery (brachiocephalic)
2. Changes name according to the region it traverses
3. Travels on the flexor aspect of joints
4. Where it crosses a hinge joint artery will anastomose to avoid compression
5. Terminal branches are generated as the artery crosses the middle joint

Upper limb: aorta → brachiocephalic → subclavian → axillary → brachial → radial & ulna.

Veins
More abundant than arteries; typically 80% of blood occupies veins
Walls are thinner, but with a diameter larger than the corresponding artery (Large capacity for expansion)
Usually depicted as a single vessel, but are typically double or multiple
Deep arteries accompanies by venae comitantes
Travel smallest to largest calibre; deep to proximal (opposite of arteries)
Vascular sheath - a covering made of connective tissue contains the entire assembly of arteries and veins.
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 Types of veins
Venules + small veins
Venules are smallest drain capillary beds, are unnamed
Small veins unite to form venous plexuses, are unnamed
Small amount of smooth muscle and no elasticity
Medium veins
Drain venous plexuses, accompany medium arteries
Often named according to artery then company
Contain valves where blood flow opposed gravity
Large veins
Wide bundles of longitudinal smooth muscle
Well-developed tunica adventitia
Same tissue makeup as medium but more collagen making up adventitia, no
elastic tissue, little endothelium lining lumen.

Valves in veins
Folds of endothelium lining veins, usually a pair of cusps
Enforce one way blood flow from distal to proximal; prevent backflow of blood
due to gravity.
Often located distal to entry of tributary

Principles of veins of the limbs
1. Superficial system of veins drains skin and superficial fascia
2. Deep system of veins drains deeper structures
3. Paired venae comitantes distally, single vessels proximally accompanying arteries
4. A set of communicating veins connects superficial and deep vein
- Superficial veins outside of deep fascia, communicating veins connects through fascial layers to the deeper
venus structures

Capillaries
Simple endothelial tubes connecting arterial and venous sides of circulation
Allow exchange of materials with interstitial and extracellular fluid
Arranged in beds that connect arterioles and venules
Many beds according to organs and body regions

Neurovascular supply
Vascular smooth muscle has tone (continuous partial contraction)
Modulated by visceral motor nerves - vasomotor nerves from neighbouring peripheral nerves
Almost exclusively part of sympathetic nervous system

Venous return flow
Vascular venous pumps
Venous flow returning to atria due to blood pressure, contraction of skeletal muscle, respiratory oscillation of
intrathoracic pressure
Vascular venous pumps result of arrangement of venae comitantes
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 Wrapped with connective tissue which resist expansion, arterial pulsation compresses blood in veins, valves direct flow
proximally
Musculovenous pump
Main method of venous return from limbs
Expansion of contracting muscles limited by fascia
Muscles contraction ‘milks’ blood superiorly, squishes the blood upwards and valves prevent backflow
Thoracic venous pump
Double pump mechanism linked to respiration
Descent of diaphragm
Inspiration - diaphragm descends, IVC shortens and empties and SVC lengthens and fills
Expiration diaphragm ascends, SVC shortens and empties, IVS lengthens and fills.

Lymph system
Runs parallel to the venous system, have valves, thinner walls, are more numerous
Widely distributed, clears interstitial spaces of surplus fluid, leaked plasma proteins, and cellular debris + returns
lymphocytes from lymph organs to blood
Comprised of lymphatic plexuses (capillaries), vessels, major trunks (ie. thoracic duct), lymph nodes, and lymphoid
organs.

Organisation of the lymphatic vascular system
Superficial (located under epithelium) and deep (in reticular layer of dermis) lymph capillaries
Lymph capillaries drain into lymphatics
- Larger tributaries with valves, one-way flow into venous system
Superficial → deep nodes before emptying into venous system

Lymphatic vessels
Like blood vessels have 3 tunis
Thinner walled than veins
Lymph drainage facilitated by smooth muscle contractile waves

Lymph nodes
Superficial and deep lymph vessels traverse multiple lymph nodes
Act as filters to trap particular in lymph and defend against foreign antigens
Flow through nodes is slow, vulnerable to secondary tumours
Become enlarges and tender when draining areas of infection
Clusters of lymph nodes in sites of high risk for pathogen entry: surface, digestive and
respiratory system

Lymphatic trunks and ducts
Lymph vessels become larger as they merge, large lymph vessels enter lymphatic trunks
- Trunks unite to form right lymphatic duct or thoracic duct
Ducts drain into the venous system at the neck; where internal jugular joins subclavian v
Lymph from right head and neck, right side of upper limb, right side of thorax, right side of upper abdo drain into veins
on right
From all other regions drain into veins on left side

Order of drainage
- Superficial lymphatic capillaries → superficial lymph nodes → lymph vessels → deep lymph nodes → deep lymph
vessels → lymphatic trunks.
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 The Heart
Internal body cavities
Closed to the outside, provide protection to the organs within them
Separated from one another by bones, muscles, ligaments, and other structures
Subdivided into several cavities:
- Cerebral, Vertebral, Thoracic, Abdominopelvic

Thoracic cavities
Formed by ribs, muscles of chest, sternum & thoracic vertebral column
Pleural cavity: Between layers of pleura around a lung
Pericardial cavity: Between layers of pericardium around the heart
Mediastinum: Central portion; contains heart, thymus, oesophagus, trachea + great
vessels

Pleural and pericardial cavities
Lungs + heart covered by thin double-layered serous membrane
Parietal serosa lines cavity walls
Visceral serosa covers organs (deep)
- Lubricating serous fluid between layers of serous membrane

Mediastinum - Centrally located region extending from sternum to vertebral column, from 1st rib to diaphragm and between
the lungs anteriorly.
Extends obliquely from 12-14cm from the second rib to the 5th intercostal space
Rests on the superior surface of the diaphragm
Anterior to the vertebral column and posterior to sternum
2/3 lies left of the midsternal line, apex projects to the left
Lungs flank heart laterally and partially obscure it

Coverings of the Heart - Heart is enclosed in the pericardium;
double-walled sac
Outer layer
Superficial part of the sac is fibrous pericardium
Anchors it to surrounding structure (base attached to the
central tendon of the diaphragm)
Prevents overfilling of the heart with blood

Inner layer
Deep to fibrous pericardium is serious pericardium
Thin, slippery two-layer membrane forming a closed sac around heart
Parietal layer: Lines the inner surface of the fibrous pericardium
Visceral layer: Adheres to the surface of the heart
- Joints at the roots of great vessels.

Pericardial cavity
Space between parietal and visceral layers
Filled with serious fluid
Allows uninhibited movement of the heart

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Orientation of the Heart
Anterior surface; sternocostal surface
Diaphragmatic surface; interior surface
Base; posterior surface
Left and right; pulmonary surfaces

Anterior Surface
Right ventricle
Right atrium
Left ventricle
Posterior Surface
‘Base of the heart’
Left atrium
Left ventricle
Proximal components of great veins
Fixed to the thoracic wall at the level of T5 to T8
Esophagus lies immediately posterior to the base.

The Valves
Cusps of fibrous tissue enforce one-way traffic of blood through heart.
Atrioventricular valves:
Separate the atria and the ventricles
Prevent backflow into the atria when the ventricles contract
Tricuspid & Mitral
- Tricuspid; Separates the RA from RV (3 cusps)
- Mitral; Separates the LA from LV (2 cusps)
Semilunar valves:
Between the great vessels and the ventricles
Prevent backflow into the ventricles
Aortic & Pulmonary
- Aortic; separates LV from aorta (3 cusps)
- Pulmonary; separates RV from pulmonary trunk (3 cusps)

Atria and Auricles
Anterior surface and each atrium has an auricle
Increases capacity of each atrium to hold a greater volume of blood
Little flaps upwards

Right Heart
Right Atrium
Blood enters via three veins
Superior vena cava (from regions superior to diaphragm)
Inferior vena cava (inferior to diaphragm)
Coronary sinus (blood from myocardium)
- Smooth posterior
- Anterior has ridges of muscles called pectinate muscles
Left and right atria are separated by interatrial septum
- Septum features fossa ovalis

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Right Ventricle
To the left of the right atria, forms the diaphragmatic surface
Pumps blood into pulmonary trunk
- To lungs for oxygenation
Internal walls of ventricle marked by trabeculae carneae
- Bulges on internal wall contribute to the papillary
muscles
Papillary muscles
- Anterior, posterior, septal
- Play a role in valve function
Chordae tendineae
- Chords of tendons attaching the papillary muscle to
tricuspid valve

Tricuspid Valve
Located between the right atrium and right ventricle
- Closes the right atrioventricular orifice
Attached to the internal wall of the right ventricle by the chordae tendineae
Contraction of papillary muscle anchors valve & prevents backflow in atrium during ventricular contraction (systole)

Pulmonary Valve
Fill the orifice between the right ventricle and the pulmonary trunk
Three semilunar cusps with free edges
- Free edges project into the pulmonary trunk
- Forced open by contraction of ventricle, blood flow into pulmonary trunk
- Backflow of blood after cessation of ventricular contraction fills the sinuses of valves & forces them closed

Left Heart
Left Atrium
Forms the majority of the base/posterior surface of the
heart
Blood enters via four pulmonary veins
- 2x left pulmonary veins
- 2x right pulmonary veins
Internal septum has fossa ovalis
- Oval depression in the interatrial septum
- Marks spot where an opening (foramen ovale) existed in fetal heart
Left Ventricle
Anterior to left atrium
Forms the apex
Longer and thicker walled than the right ventricle
- Thickest walled chamber
Pumps blood into aorta; Largest artery in body
Like right ventricle also has:
- Trabeculae carneae
- Papillary muscle
- Chordae tendineae

Tangent: Right vs Left Ventricle
Left ventricle - thicker wall, circular cavity
Right ventricle - crescent shaped & wraps around LV
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Mitral Valve
Separate the left atria and ventricle
2 semilunar cusps
Attached to left ventricular wall via chordae tendineae
Aortic Valve
Sits in between the left ventricle and the aorta
3 semilunar cusps
Mechanism of action similar to pulmonary valve
Small openings for left and right coronary arteries; Supply of oxygenated blood for the heart itself.

Cardiac skeleton and valve - Valves are attached to heart via cardiac skeleton; 4 fibrous rings

Systole - State of ventricular contraction
Pulmonary and aortic valves are open allowing blood flow from ventricles out
Tricuspid and Mitral valves are closed, blood stays in atrium

Diastole - State of ventricular relaxation
Pulmonary and aortic valves are closed, blood stays in ventricle.
Tricuspid and mitral valves are open, allowing blood flow from atrium to ventricle

Cardiac conduction system
Initiates and coordinates contraction of atria and ventricles to pump blood
- Sinu-atrial node (SA node) - junction of SVC & RA
- Atrioventricular node (AV node) - interatrial septum
- Atrioventricular bundle (Bundle of His) Gives off left and right branches
- Subendocardial plexus (Purkinje fibres – left & right)
SA and AV nodes
Impulses begin at SA node (cardiac pacemaker), spread across atria, atria contract
Activity in SA node stims AV node (near coronary sinus), ventricles
AV bundle direct continuation of AV node – right and left bundles
AV bundle and Subendocardial plexus
Left AV bundle gives off branches that become continuous with subendocardial plexus; Allows for electrical impulses to
spread through ventricles and muscles, causing contraction.

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 Coronary and Great vessels

Pulmonary - blood flowing through the heart and lungs
Systemic - Distribution of blood to the body

1. Deoxygenated blood enters RA
2. Blood passes the tricuspid valve into RV
3. RV pumps blood through the pulmonary valve into
the pulmonary trunk to the left and right
pulmonary arteries
4. Blood proceeds to the lungs and becomes
oxygenated, losing CO2
5. Oxygenated blood enters LA via pulmonary veins
6. Blood passes the mitral valve into LV
7. LV pumps blood through the aortic valve into the
aorta
8. The aorta delivers blood to the systemic circulation
through a series of arteries
9. Capillaries within tissues supply blood to the body
10. Once blood reaches capil