Week2_Introduction to Anatomy_PT1-4_CUNANAN_Maria Ysabel Zhuri_compressed.pdf

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CRS101: HUMAN ANATOMY
Week 2 – Language of Anatomy & Introduction to Musculoskeletal System

INSTRUCTIONS
1. Complete the exercises below to demonstrate your comprehension. Scroll down to the last page to
ensure you don’t miss anything.
2. When answering, check these references in order. You can focus on books of Snell and Seeley.
3. Use the following format for saving your document in PDF format:
Name of the PDF document: Week 2 _Introduction to Anatomy_Section_Last Name, First Name
Example: Week 2_Introduction to Anatomy_2_Dela Cruz, Juan
4. When you finish the worksheet, submit it in the designated submission bin in the iLS Blackboard. The
submission deadline is on or before September 2, 2024.
5. If you encounter any issues uploading to the submission bin, please send your worksheet to
[email protected] and the faculty-in-charge. Additionally, notify the topic organizer and
faculty-in-charge via a private message on Microsoft Teams. Include your section in the message.
6. The grading rubric for your work is specified in the Student Guide.

EXERCISE 1: LANGUAGE OF ANATOMY & SKELETAL SYSTEM
1. What do you think the importance of studying anatomy is in your chosen course? (Maximum of 150 words)

As a Bachelor of Science in Physical Therapy (BSPT) student, I believe that the study of anatomy is extremely
relevant for anyone tackling the medical field. Understanding anatomy helps us handle our patients better and
address their concerns while explaining their medical situations clearly. A comprehensive grasp of anatomical
structures and their functions is essential for accurate assessment and diagnosis of musculoskeletal issues. This
knowledge enables us to develop effective, individualized treatment plans tailored to each patient’s specific needs.
Additionally, understanding anatomy enhances our ability to educate and communicate with patients about their
conditions and the importance of prescribed therapies. It also supports the safe application of therapeutic techniques,
reducing the risk of injury or further complications for our patients. It is our duty as medical personnel to be
professional and prepared therefore being able to grasp anatomy will help us further in those ordeals

2. Choose one of the movements described below. Take a picture of yourself performing it and attach to this
document.

1. Place the ventral part of either hand on the contralateral body part that is lateral to your axilla.

2. In supine position, place the most medial part of your hands on the anterior femoral areas.

3. Place the ventral part of your right hand inferior to your clavicle.

3. Consider one simple daily activity and explain or narrate it using at least three anatomical, directional, and
regional terms. Please adhere to the format outlined below.
Student before taking the first anatomy Student after taking the first anatomy class
class
Drinking water everyday is a simple but Drinking water every day involves several steps
important task I do everyday to maintain from the anatomical, directional, and regional
hydration. I simply start with grabbing a perspectives. I start by using my hand to retrieve
glass from the pantry, walking towards the the glass from the pantry, located in the anterior
water dispenser, then filling up my glass region relative to my initial position. I then move
with water. Afterwards while holding the towards the water dispenser, traveling in an
glass, I move it towards my mouth to have anterior direction to fill the glass with water.
a drink. After drinking I move towards the Holding the glass, I bring it towards my oral cavity,
sink to wash my glass then put it back to which involves a movement in a posterior direction
the pantry relative to my body. I tilt my head slightly in a
posterior direction and sip the water, which flows
from the glass into the oral cavity, passes through
the buccal (cheek) region, then into the pharynx
(throat), and travels down the esophagus (inferior
to the pharynx) to the stomach. After drinking, I
walk to the sink (anteriorly relative to my drinking
position) to clean the glass, and then return it to
the pantry, moving it in a posterior direction relative
to the sink.

For example:
Student before taking the first anatomy Student after taking the first anatomy class
class
Taking a bath is something I do every day. Taking a bath is something I do every day. When I
When I shower, I wash my head first; then shower, I usually start from the cephalic to the
all body parts down to my feet. I start by caudal region. I start by massaging my scalp with
massaging the back of my head right water and shampoo, focusing on the occipital
above the neck and move on to the rest of region, then moving on to the superior parts of my
my scalp, massaging upward… head…
4-6. Surface Markings, Bones, Types, and Locations: Complete the table.
Term/Feature/Surface Description Specific Examples Bones Type of Bone Classification
Markings according to
location
General
Body Main part Body of femur Femur Long Appendicular

Head Enlarged, often Head of femur
rounded end
Neck Constriction between Neck of femur Femur Long Appendicular
head and body
Margin, border Edge Lateral border of Scapula Appendicular
scapula

Angle Bend Mandibular angle Mandible Axial
Ramus Branch off the body Mandibular ramus Mandible Axial
beyond the angle
Condyle Smooth, rounded Lateral condyle
articular surface
Facet Small, flattened Superior articular facet Atlas Axial
articular surface of atlas
Ridges
Line, linea Low ridge Intertrochanteric line of Femur Long Appendicular
femur Superior nuchal line
of occipital bone Occipital
Crest, crista Prominent ridge Iliac crest Ilium Appendicular
Process Prominent projection Acromion process Scapula Appendicular
Axial
Tubercle Small, rounded Greater tubercle Humerus Long Appendicular
projection Appendicular
Tuberosity, tuber Rounded projection; Deltoid tuberosity Humerus Long Appendicular
larger than a tubercle
Trochanter Tuberosity on the Greater trochanter Femur Long Appendicular
proximal femur
Epicondyle Upon a condyle Lateral epicondyle Femur Long Appendicular
Lingula Flat, tongue-shaped Lingula of mandible Mandible
process
Hamulus Hook-shaped process Pterygoid hamulus of Sphenoid
sphenoid bone
Horn Horn-shaped process Greater horn of hyoid Hyoid
Openings
Foramen Hole Foramen magnum of Occipital bone
occipital bone
Canal, meatus Tunnel Hypoglossal canal of Occipital
sphenoid bone
Fissure Cleft Superior orbital fissure Sphenoid Axial
of sphenoid bone
Inferior orbital fissure Sphenoid Axial
Sinus, labyrinth Cavity Ethmoid labyrinth Ethmoid

Fossa General term for a Coronoid fossa Humerus Long Appendicular
depression Olecranon fossa
Mandibular fossa
Notch Depression in the Mandibular notch Axial
margin of a bone Intercondylar notch
Fovea Little pit of femur
Fovea capitis of femur Femur Long Appendicular
Groove, sulcus Deep, narrow Intertubercular groove Humerus Long Appendicular
depression of humerus
EXERCISE 2: JOINTS and MUSCULAR SYSTEM

DEFINITION OF TERMS
Let us begin our worksheet but defining important terms that you will come across during our synchronous discussion (:

Terms Definition
Connective tissue One of the 4 primary tissue types that primarily functions to connect structures together
Ligament Connective tissue bands that hold bones together
Tendon Connective tissue bands that attach muscles to bones
Firm, smooth, resilient, nonvascular connective tissue that functions to resist compressive forces,
Cartilage enhance bone resilience, and provide support on bony areas.
Range of motion Describes the amount of mobility that can be demonstrated in a given joint
Joint cavity A space between the articulating bones that contains a small amount of synovial fluid.
Articular cartilage Hyaline cartilage that covers the surfaces of the bones forming the joint.
Two layers that enclose the joint cavity. The tough external layer is the fibrous layer composed of
Articular capsule dense irregular connective tissue. The inner layer is the synovial membrane composed of loose
connective tissue.
A viscous fluid located in the joint cavity and the articular cartilage. This fluid acts as a lubricant,
Synovial capsule reducing friction.
Pads composed of fibrocartilage (menisci) may also be present to minimize wear and tear on the
Articular discs bone surfaces.
Sac filled with synovial fluid that reduces friction where ligaments, muscles, skin, tendons, and
Bursae bones rub together.
Tendon sheats Elongated sac with synovial fluid that wraps around a tendon.

Word Bank:
Articular Cartilage Bursa Joint Cavity Range of Motion Tendon
Articular Capsule Cartilage Ligament Synovial Fluid Tendon Sheath
Articular Discs Connective Tissue

A joint (or articulation) is defined as, “a place where two or more bones come together.” (Seeley, 2020). They perform 2 major
functions for the body, namely (read Marieb, p.185):

1. Allow our skeleton to freely function and move

2. To keep our bones intact

Joints are classified either functionally and structurally. The functional classification is based on the amount of movement the joint
allows (degree of motion). Meanwhile, the structural classification is based on whether which major connective tissue connects the
two bones and whether there is a presence of fluid-filled joint capsule. Fill-in the boxes below (read Seeley, p.247):
 Cartilaginous
Fibrous Joints Joints
Synorial Joints Synathsosis Amphiarthrosis Diarthrosis

Suture Synchondrasis Hinge

Syndesmosis Symphysis Saddle

Gomphosis Pivot

Condyloid

ball and socket

Plain joint

Ellipsoid

Summarize the structural and functional classification of joints by answering the table below.
Structural Class Structural Structural Types Examples Functional
Characteristics Classification

Synarthrosis
Fibrous Suture (joint fibers)
(Immovable)

Syndesmosis (long
fibers)

Fibrous
Gomphosis (periodontal
Tooth in a bony socket
ligament)
 Synchondrosis (hyaline
cartilage)
Adjoining bones united
Cartilaginous by cartilage; no joint
Symphysis
cavity
(fibrocartilage)
Structural Class Structural Structural Types Examples Functional
Characteristics Classification
Hinge

Saddle

Pivot
Diarthroses (freely
Synovial
Condyloid movable)
Wrist
Ball-and-socket
Shoulder and hip
Plane joint Intercarpal and
Intertarsal joints
Ellipsoid
Radiocarpal joint
Identify the parts of the synovial joints using the names indicated in the box on the right side (read p.244, Seeley):

Bursa

Word Bank
Synovial
1. Articular (Hyaline) Cartilage
membrane 2. Bursa
3. Fibrous Capsule (Outer Layer)
Fibrous 4. Joint Cavity
Capsule
5. Periosteum
6. Synovial Membrane (Inner Layer)
7. Tendon Sheath
8. Tendon
Joint cavity

Articual cartilage

Tendon
Sheath

Peristeum
Tendon
(fibrous)

Peristeum
(cellular)
Synovial joints are the most complex among the three structural classifications. Understand them better by answering the table below
(Reference: Snell R. (2012) Clinical Anatomy By Regions. 9th ed. Philadelphia: Lippincott Williams & Wilkins.

Synovial Joint Description of articulating surface Movement Examples
Hinge A rounded or cylindrical bone fits into a
concave surface on the other bone Flexion extension and
Monoaxial diarthrosis
Saddle Articulating surface are saddle-shaped; one Flexion, extension,
surface is concave, the other surface is Abduction, adduction, Carpometacarpal joint
convex Circumduction
Pivot Proximal radioulnar joint
Monoaxial diarthrosis Atlantoaxial joint

Condyloid Bi-axial: flexion, extension,
abduction, adduction Radiocarpal joint,
metacarpophalangeal joint
Ball-and-socket Flexion, extension, Shoulder joint Hip joint
Abduction, adduction,
Circumduction
Plane Non-axial: gliding
Intercarpal and intercarsal
Joint
Ellipsoid Elliptical convex articular surface fits into an
elliptical concave; Rotation is impossible
Bi-axial Radiocarpal joint

NAMING THE JOINTS
Now that you are familiar with what joints are and their structural and functional classifications, it is important for you to know how to
identify and name the joints. The joints are named according to:

1. Bones that join together
2. Greek or Latin Name

For the Greek/Latin names, the students need to be familiar with these. Meanwhile, let us apply your knowledge on the names of the
skeletal bones to be able to name the following joints:
Example 1 Example 2 Example 3
 1 Bone 1
ne Bone 1
Bo

Bone 2
Bone 2

Bone 2

Bone 1: Acromion Process of Scapula Bone 1: 5th Lumbar Vertebral Bone Bone 1: Metacarpal Bone

Bone 2: Clavicle Bone 2: Sacral Bone Bone 2: Proximal Phalanges

Name of Joint: Acromioclavicular Joint Name of Joint: Lumbosacral Joint Name of Joint: Metacarpophalangeal Joint
Name the following joints according to the bones that join them together:

Temporomandibular

Sternoclavicular
Atlanto-occupital

Atlantoaxial

Sternocostal

Sacroiliac

Shoulder or
glenohumeral

coxal

Elbow
Tibiofemoral

Proximal radioulnar
joint Femeropatellar

Superior Tibiofibular

Inferior Tibiofibular

Carpometacarpal of digit 1

Carpometacarpal Tarsometatarsal

Metacarpophalangeal Metatarsophalangeal

Interphalangeal
Interphalangeal
 Part II: Muscular System
Identify the functions of muscular system.

1. 2. 3. 4

5. 6. 7.

There are 3 types of muscles in the body, namely, skeletal muscle, smooth muscle, and cardiac muscle. Differentiate these three by filling-in the table
below (read p.267, Seeley):
Skeletal Muscle Smooth Muscle Cardiac Muscle
Location

Appearance

Cell-Shape Very long and cylindrical (1 mm–4 Spindle-shaped (15–200 μm in Cylindrical and branched (100–500
cm, or length, μm
as much as 30 cm, in length, 10 5–8 μm in diameter) in length, 12–20 μm in diameter)
μm–100 μm in diameter)
Nucleus
Striations
Control
Function

For the Prelims period, we are going to focus on the Musculoskeletal System. Hence, we will emphasize the skeletal muscle type in this topic. Watch this
short video on Skeletal Muscle Parts: https://www.youtube.com/watch?v=SCznFaTwTPE (2 mins, 10 seconds) before proceeding to the next part of the
worksheet. Label the parts of the skeletal muscle (read p.201, Marieb):
 Word Bank:
Endomysium
Epimysium
Muscle Fasciculus
Muscle fiber
Myofibril
Perimysium
Tendon

Watch the short video about the Structure of a Myofibril: https://www.youtube.com/watch?v=D0n3vnjGE6I (4 mins). Label the parts of the myofibril (read
p.212-213, Tortora):
Word Bank for
Labelling of parts
of Myofibril:
A-band
H-Zone
I-band Word Bank for Definition of Terms
M-Line
Z-Disc A-band Muscle Fiber
Endomysium Myofibril
Epimysium Myofilaments
H-band Perimysium
I-band Sarcomere
M-line Skeletal Muscle
Muscle Cell Z-discs
Muscle Fascicle
Definition of Terms (Skeletal Muscle Structure):
Terms Definition
Epimysium Connective tissue that forms the outer layer, encircling the entire muscle.
Connective tissue that surrounds groups of 10 to 100 or more muscle fibers, separating them into
Perimysium bundles called muscle fascicles.
Connective tissue that penetrates the interior of each muscle fascicle and separates individual
Endomysium muscle fibers from one another.
Long cylindrical cell covered by endomysium and sarcolemma; contains sarcoplasm, myofibrils,
Muscle cell many peripherally located nuclei, mitochondria, T tubules, sarcoplasmic reticulum, and terminal
cisterns.
Muscle Fascicle Bundle of muscle fibers.
Skeletal muscle Organ made up of muscle fascicles that contain muscle fibers, blood vessels, and nerves.
Threadlike contractile elements within sarcoplasm of muscle fiber that extend entire length of fiber;
Myofibril composed of filaments
Contractile proteins within myofibrils that are of two types: thick filaments composed of myosin and
Sacromere thin filaments composed of actin, tropomyosin, and troponin; sliding of thin filaments past thick
filaments produces muscle shortening
 The filaments inside a myofibril do not extend the entire length of a muscle fiber. Instead, they are
Muscle fiber
arranged in these compartments. Basic functional unit of a myofibril
Z-disc Narrow, plate-shaped regions of dense material that separate one sarcomere from the next.
Dark, middle part of sarcomere that extends entire length of thick filaments and includes those parts
A-band
of thin filaments that overlap thick filaments.
Lighter, less dense area of sarcomere that contains remainder of thin filaments but no thick
I-band filaments. A Z-disc passes through center of each I band.
H-band Narrow region in center of each A band that contains thick filaments but no thin filaments.
Region in center of H zone that contains proteins that hold thick filaments together at center of
M-line sarcomere.

Definition of Terms (General Principles of Skeletal Muscle Anatomy) (read p.209, Seeley):
Terms Definition
Origin Also called the fixed end; is usually the most stationary, proximal end of the muscle.
Also called the mobile end, is usually the distal end of the muscle attached to the bone undergoing
Insertion the greatest movement.
Tendon At the attachment point, each muscle is connected to bone by this connective tissue.
Belly The part of the muscle between the origin and the insertion.
Action Movement accomplished by the muscle when it contracts.
Agonist A muscle that accomplishes a certain movement.
Antagonist A muscle acting in opposition to an agonist.
Synergist Members of a group of muscles working together to produce a movement
Prime mover This muscle plays the major role in accomplishing the movement.
Fixators Muscles that hold one bone in place relative to the body while a usually more distal bone is moved.
Head Some muscles have multiple origins. Each origin is also called a.

Word Bank for General Principles of Skeletal Muscle Anatomy:
Action Belly Head Origin Tendon
Agonist Fixators Insertion Prime mover Synergists
Antagonist

The shape of the muscle determines the type of movement it has. There are 5 classes of muscle shapes as determined by the
arrangement of its fascicles, namely, circular, convergent, fusiform, parallel, and pennate (Unipennate, bipennate, multipennate).
Complete the table below (read p.311, Seeley):

Pattern Description Shape of Muscle Examples
Circular Fascicles arranged in a circle around an Orbicularis Oris
opening; act as sphincters to close the
opening Orbicularis Oculi

Convergent Broadly distributed fascicles converge at a 1. Pectoralis major
single tendon
2. Pectoralis minor
 Pattern Description Shape of Muscle Examples
Parallel (One for each shape)
3. Trapezium
4. Rhomboideus
5. Rectus abdominis

Pennate (One for each shape)
6. Unipennate

7. Bipennate muscle
8. Multipennate muscle

Fusiform 9. Biceps branchii
10. Sartorius

NAMING OF MUSCLES
Fill-in the table for the characteristics used to name muscles (read, p.352, Tortora)
Name Meaning Example
DIRECTION: Orientation of muscle fascicles relative to the body’s midline
Rectus Parallel to midline Rectus abdominis
Transverse Perpendicular to midline Transversus abdominis
Oblique Diagonal to midline External abdominal oblique
SIZE: Relative size of the muscle
Maximus Largest
Minimus Smallest
Longus
Brevis
Latissimus
Longissimus
Magnus
Major
Minor
Vastus
SHAPE: Relative shape of the muscle
Deltoid
Trapezius
Serratus
Rhomboid
Orbicularis
Pectinate
Piriformis
Platys
Quadratus
 Gracilis
ACTION: Principal Action of Muscle
Flexor
Extensor
Abductor
Adductor
Levator
Depressor
Supinator
Pronator
Sphincter
Tensor
Rotator
NUMBER OF ORIGINS: Number of tendons of origins
Biceps
Triceps
Quadriceps
LOCATION: Structure near which a muscle is found; Example: Temporalis, muscle near temporal bone
ORIGIN AND INSERTION: Sites where muscle originates and inserts; Example: sternocleidomastoid, originating on sternum and clavicle and inserting on mastoid
process of temporal bone

Accomplished by:

I hereby state that I completed the worksheet independently and did not engage in any form of cheating or collusion with my classmates. My
work is a true reflection of my individual effort and understanding of the material.

Maria Ysabel Zhuri F. Cunanan /PT1-4/ September 5, 2024
Name and Signature of Student / Section / Date Accomplished

References
Snell R. (2012) Clinical Anatomy By Regions. 9th ed. Philadelphia: Lippincott Williams & Wilkins.
VanPutte, C. L., Regan, J. L., Russo, A. F., Seeley, R. R., Stephens, T., & Tate, P. (2020). Seeley's anatomy & physiology. McGraw-Hill.
Marieb, M., Keller, S. (2019). Essentials of human anatomy & physiology. 13th edition. San Francisco, CA: Pearson Benjamin Cummings.
Marieb, M. & Smith, L. (2023). Human Anatomy and Physiology Laboratory Manual. 12th Edition. United Kingdom: Pearson Education Limited
Tortora, G. J., & Derrickson, B. (2017). Principles of anatomy & physiology. 15th edition. Danvers, MA, Wiley.

Topic Organizer:

Myzelle Anne J. Infantado, PTRP

https://theawkwardyeti.com/