Principles Anatomy Flashcards
What are the 3 planes of the body.
- Sagittal (Median or parasagittal)
- Coronal/ frontal
- Axial/Transverse/ Horizontal
** Sagittal & coronal are longitudinal planes
Anatomical term for front and back
Anterior and Posterior
Coronal plane
Anatomical term for top and bottom
Superior and Inferior
Or
Cranial/ Rostral/ Vertex and Caudal
(Horizontal plane)
Anatomical term in relation to Median plane
Medial and lateral
Anatomical term describing relationship site of attachment of limbs to body
Proximal and Distal
Anatomical term to describe relationship of distance to centre of organ or cavity
External and Internal
Anatomical term to describe relationship to surface
Superficial and deep
Anatomical terms for parts of body that protrudes anteriorly
Dorsal (superior or posterior) and Ventral (inferior or anterior)
E.g. Top of tongue is the dorsal surface
Ventral terms for palm, foot, wrist
Palm - Palmar
Foot - Plantar
Wrist - Volar
Term to describe an intermediate anatomical position
Middle
Anatomical term in relation to size of structure
Major and Minor
Term describing structures found only on 1 side of the body
Give examples
Unilateral
E.g. Spleen, Appendix
Term describing structures found on both sides of body
Give examples
Bilateral
E.g. Upper and lower limbs, eyes, ears, lungs, kidney
Term describing structures found along median plane
Midline
E.g. vertebral column, skull, thyroid
Term describing structures found on same side of body from the other that it is being compared to
Ipsilateral
Term describing structures found on opposite side of body from the other that it is being compared to
Contralateral
Notes:
Combined anatomical terms
Antero- , Postero - always prefix
Lateral, medial - always suffix
Term for a diagonal section
Oblique
What is the anatomical position
Upright/ supine state
Feet, head, palms facing anteriorly
Arms fully extended, perpendicular to the ground
Eyes looking forward
**Note: downward action of gravity on viscera when upright compared to lying supine
Note:
Anterior movement of structures superior to knee is flexion
Posterior movement of structures inferior to knee is flexion
-
Movement towards and away from median plane
Toward: adduction
Away: abduction
Careful with eyes: if one side adducts, the other abducts (Midline: Nose)
For digits: Midline goes across middle finger
Waving movement: lateral and medial abduction
Movements for rotation
Internal/ medial and External/ lateral
Sequence for circumduction of joint
Flexion, Abduction, Extension then Adduction
Movement of sole of foot in and outwards
Inversion and Eversion
Movement of forearm (palm facing up and down)
Supination and Pronation
Normally rested at a semi-prone position
Movement of thumb
Opposition (touching digits)
And
Reposition (back to anatomical position)
Movement of shoulders/ upper eyelid up and down
Elevation and Depression
Movement of scapula front and back
Protraction and Retraction
Forward/backward movement jaw and tongue
Protrusion and Retrusion
Sideways bending
Lateral flexion of vertebral column
Movement for tipping toe and pointing toe downwards
Dorsiflexion and Plantarflexion
Describe abduction, extension and flexion of thumb
Abduction: thumb anterior from palm
Extension: thumb moves laterally away from palm
Flexion: thumb crosses palm
Difference between occurring IN and AROUND a plane
In - movement won’t change the plane
Around - changes description
E.g. abduction/ adduction occurs IN coronal plane but AROUND parasagittal plane
Function of the circulatory system (6)
- Gaseous exchange for growth and repair
- Waste removal
- Nutrition transport
- Chemical signalling (hormone)
- Thermoregulation (core body temperature)
- Mediate inflammation and host defence response
Components of the CVS
Arterial system
Heart
Venous system
What is the circulation route?
Deoxygenated blood: SVC/ IVC to Right Atrium to Triscuspid valve to Right Ventricle to Pulmonary valve to Pulmonary trunk
Bifurcated to right and left pulmonary artery
Oxygenated blood: Lungs to pulmonary veins (2 left, 2 right) to Left Atrium to Bicuspid/ Mitral valve to Left Ventricle to Aortic valve to Aorta
Orientation of chambers of heart (anterior/ posterior surfaces)
Right ventricle - most anterior
Left atrium - most posterior
Right atrium & Left ventricle - borders
Function of valves
Prevent backflow of blood
Ensure unidirectional flow
Note: Heart is a double muscular pump
-
Layers of the heart (3)
- Epicardium (Visceral serous pericardium)
- Myocardium (Smooth muscle)
- Endocardium (continuous with blood vessels connecting with heart; of epithelial origin)
Electrical conduction route of the heart
Concept of auto-rhythmicity SA node (upper right atrium) spontaneously fires -> atria contracts -> AV node at Atria-ventricular septum -> Right & Left bundle of His in inter-ventricular septum -> spreads through conducting Purkinje fibers throughout myocardium -> ventricles contract
Layers of blood vessels (5)
- Tunica Intima (Endothelium, single layer of squamous epithelial cells supported by a basal layer and a thin layer of connective tissue)
- Internal Elastic Membrane
- Tunica Media (Predominantly smooth muscle and elastic fibers; most variable thickness) Circumferential arrangement
- Outer Elastic Membrane
- Tunica Adventitia (Supporting connective tissue - with unmyelinated nerve fibers, blood vessels, fibroblasts, collagen fibrils, elastic fibers)
*Elastic tissue stained black with Verhoeff’s/ Masson Trichrome stain
Characteristics of Arteries (6)
Part of Neurovascular bundle High Pressure (>120/80) Rounded elastic lumen Pulsatile Carries oxygenated blood Located deeper than veins (in protected areas)
Characteristic of Arterioles (6)
- Decrease in size compared to larger vessels
- Only 1 - 2 layers of smooth muscle left in tunica media -> dilates/contract lumen -> regulates blood flow to tissues
- No adventitia
- Sympathetic tone gives low level of contraction of smooth muscle innervated by SNS at background (tonic/ continuous conduction of action potential)
- Contraction (Spasm) can help to reduce blood loss after injury
- Important in controlling blood flow in tissue
Properties of elastic fibers in Aorta
Contains sheets of elastic fiber replacing smooth muscles that provides elastic recoil during diastole (Maintains peripheral flow) (More energy efficient)
Expands under high pressure during systole while receiving blood
Naming of arteries that will definitely divide
Common or Trunk
Define anastomoses and its caveat
Also known as collateral circulation
Arteries connect with each other WITHOUT intervening capillary network –> gives alternative route for blood flow to supply cells distal to an arterial occlusion
Caveat: Can bleed from both sides of a cut (route of less pressure) –> worse hemorrhage
Define end arteries/ infarction
The only arterial blood supply to given area of body
Thus, untreated occlusion –> infarction of end territory –> irreversible cell death from hypoxia from low arterial blood supply
Coronary arteries are functional end arteries. Why?
Anastomoses occur but not enough to compensate occlusion –> MI
Examples of end arteries (2)
- Digital artery branch (Finger tip infarction)
2. Central artery of retina (Monocular blindness)
Example of collateral circulation (1)
- Circle of Willis (prevents CVA/ stroke)
What is the term for ‘Blood vessel of blood vessels’
Vasa vasorum.
In large arteries, only the inner par of wall obtain nutrients from lumen –> thus vessels need to have own vascular supply
Segment and route of aorta and its branches
Ascending - Right and Left coronary artery
Arch - Brachiocephalic trunk, Left common carotid, Left subclavian
Thoracic - multiple
Abdominal - 3 unpaired midline branches & 3 paired bilateral branches
Route of arterial supply at upper limb from subclavian
Subclavian –> Axillary –> Brachial –> Bifurcates to radial and ulnar
Route of abdominal aorta
Abdominal aorta –> common iliac artery –> bifurcates to external iliac (to LL) and internal iliac (to pelvis and perineum)
Location of Peripheral Pulses (6)
- Carotid (at bifurcation of common carotid artery)
- Brachial (anteromedial to elbow joint)
- Radial (volar aspect of wrist)
- Popliteal (posterior to knee joint)
- Femoral (continuation of external iliac artery at midpoint of groin)
- Dorsalis Pedis (Lowest point; indicative of arterial integrity)
What consists of the circulatory system
CVS + Lymphatic system (no central pump)
Characteristic of veins (11)
- In neurovascular bundle
- Carries de-oxygenated blood
- Low pressure
- Non-pulsatile
- Drains blood away from territory
- Venules and veins merge like tributary
- Thin walled, thus collapses when empty
- Valve cusps in small-medium sized veins as inward extension of tunica intima (Dysfunction –> develop varicosities)
- Thin but continuous tunica media (few layers of smooth muscles) (thinner than that found in a muscular artery)
- Thick tunica adventitia (thicker in larger veins (IVC/ HPV) and incorporates bundles of longitudinally oriented SM)
- Oblong lumen
- Flexible - can accommodate expansion and contain most blood in the body
Factors influencing venous return (3)
- Venous valves (flowback to heart against gravity)
- Skeletal muscle pump
- Accompanying veins (small veins run in pairs or more with an artery in a sheath –> pulsation pushes venous blood away) aka Venae comitantes
2 sets of veins
- Superficial (smaller, run within superficial fascia and drains into deeper veins)
- Deep (larger, run deep to deep fascia and cavities, usually in NVB)
2 venous systems
- Hepatic portal venous system: Drains venous blood from absorptive parts of GI tract and associated organs to liver for cleansing
- Systemic venous system: Drains venous blood from all other organs and tissue into SVC and IVC
Characteristic of capillaries
- Forms extensive vascular networks
- Lined with single layer of endothelium (diffusion distance) and a basal layer
- No smooth muscle, some connective tissue
- narrow lumen (1 RBC wide)
- Exchange of gases, metabolites and waste products with ECF
Types of capillaries (3)
- Continuous: Muscle, nerve, lung, skin, connective tisuse
- Fenestrated (Small pores ~50nm): Gut mucosa, endocrine glands, glomeruli of kidneys
- Discontinuous/ Sinusoidal (Large gaps for macromolecules & cells; Basal lamina is discontinuous or absent): Liver, Spleen, Bone Marrow
Route of microvasculature from small arterioles
Small arterioles –> Meta-arteriole –> Pre capillary sphincter (smooth muscle; controls flow through network) –> branches into capillaries –> merges into post capillary venules –> joins back to collecting venule (larger diameter)
Small arterioles –> Meta-arteriole –> thoroughfare channel –> collecting venule
What is interstitial fluid known as?
Lymph
Lymphatic circulation from capillaries
Waste products leaked out into ECF from blood not picked up by capillaries –> enters lymphatic circulation -> Lymph nodes –> Central large veins at root of neck
Superficial lymphatics drain to deep lymphatics
Drainage of lymph back to venous system
- 3/4 of lymph drains through thoracic duct into Left venous angle (Only lymphatic vessel visible grossly)
- 1/4 of lymph drains through right lymphatic duct into Right venous angle (Right head, UL, neck & thorax)
- Venous angle: junction of internal jugular and subclavian veins)
Function of lymph node and palpability during infection
Contains WBC to filter out foreign particles and fight cancer/ infection (Immunological surveillance)
Usually non-palpable but enlarged & palpable in those fighting infection or taken over by spreading cancer (seen on CT)
Characteristic of lymph vessels
Thin-walled vessels that drains excess tissue fluid into blood (recycling)
Factors aiding flow in lymphatic vessels
- Smooth muscles in walls
- Hydrostatic pressure in tissue
- Compression of vessels by voluntary muscles
- Valves
What comprises of the axial skeleton?
Bones at the midline:
Skull, Neck (C-vertebrae, Hyoid Bone), Trunk (Chest, Abdomen, Back)
What comprises of the appendicular skeleton?
- Bones of pectoral girdle (Attaches bone of upper limb to axial skeleton)
- Bones of UL
- Bones of pelvic girdle (Attaches bone of lower lim to axial skeleton)
- Bones of LL
Bones of the UL
1 long bone in arm (Humerus), 2 long bones in forearm (Radius, Ulna), Wrist (Carpal bones), Palm (Metacarpals), phalanges
Bones of the LL
1 long bone in thigh (femur), 2 long bones in leg (Tibia, Fibula), Hind/midfoot (Tarsal bones), Forefoot (Metatarsals), Phalanges
When do bony features develop and its purpose?
During bone growth
For functionality, to give the best shape for the job
What kind of bony features are there and how are they developed? (2)
- Adjacent structure (E.g. tendon, blood vessel, nerve, another bone) applies force (tensive or compressive) to developing bone –> moulds shape accordingly
- Adjacent structure developing at same time as bone –> bone has to grow around other structure –> foramen (hole)
Bony features of UL
Greater tubercle (tuberosity) of humerus Styloid process of radius
Bony features of LL & Pelvis
Ischial tuberosity Lesser trochanter Femoral condyle Tibial tuberosity Medial malleolus
What comprises the skeleton?
Bones and cartilage
Where are the articular cartilages?
Places that allows for movement
Eg. IV disc, shoulder joint, elbow joint, knee joint, hip joint
Characteristic (1) of bone and function (4)
Hard, connective tissue
- Support & protect body organs
- Calcium metabolism
- RBC formation
- Attachment for skeletal muscles
Describe the shaft and ends of the bone
Shaft: Diaphysis
- Outer shell of cortical bone
Ends: Epiphyses
- aka cancellous/ trabecular bone
- has fine meshwork and lines that follow force to support weight
What are the canals in bone tissue called and what resides in them?
Haversian canals.
Blood vessels and nerves are inside.
Canal surrounded by living osteocytes
Bone undergoes constant remodeling throughout life
True
Characteristic of cartilage (6) and where is it required at?
Less rigid than bone, Avascular (nutrients diffuse from adjacent tissue via ECF), Strong, Flexible, Compressible, Semi-rigid (due to hydrated glycosaminoglycans and proteoglycans)
Found where mobility is required (articular and costal cartilage)
Where does movement of skeleton occur?
Occurs at joints via the contraction of skeletal muscle to move the bones.
What are the 3 types of cartilage?
- Hyaline (Articular surfaces, tracheal rings, coastal cartilage, epiphyseal growth plates)
- Elastic (Ear; goes back to original shape)
- Fibrocartilage (pubic symphysis, IV disc)
What are the 2 types of hard CT?
Bone and cartilage
What are the 3 types of joints and their compromise profile?
- Synovial (Most flexible)
- Cartilaginous
- Fibrous (Least move-able)
Increased mobility –> Decreased stability
How is the sensory nerve supply to joints?
Excellent thus a lot of pain when dislocated or affected by pathology (Arthritis)
What are the sensations detected by sensory receptors of joint nerves? (4)
- Pain
- Touch
- Temperature
- Proprioception (Joint position sense)
How is the arterial supply at the joints?
Arterial branches that supply joints are from larger named arteries.
Periarticular arterial anastomoses are common.
Can be damaged by dislocations –> compromise blood flow distal to the joint
Characteristic of skeletal muscles (3)?
- Voluntary, Striated (but not all)
- Multinucleated, cylindrical cell of considerable length
- Nuclei are elongated and located at cell periphery just internal to cell membrane/ sarcolemma
Function(3) and location of skeletal muscles?
Produces movement, generates heat, provides structure and form
Found deep to deep fascia (except face)
What covers skeletal muscles?
Tough fibrous connective tissue
Types of skeletal muscle (6) and examples
- Circular (surrounds opening/ orifice) - orbicularis oculi and sphincters
- Convergent (Arise from broad areas then converges to a single tendon) - Pectoralis Major
- Fusiform (Thick belly with tapered ends) - biceps brachii
- Quadrate (4 sides of equal length) - rectus abdominus
- Pennate (feather-like arrangement) - deltoid
- Flat (Parallel fibers with flat broad tendon; aponeurosis - a/w flat muscles and attaches muscle to soft tissue rather than bone) - external oblique
