Fundamentals of Kinesiology
Apparel Technical Design
Introduction to the Study of Kinesiology
& Anatomical and
Physiological Fundamentals of Human Motion
The Musculoskeletal System: The Skeletal
System and its Movement
(Ch. 1 & 2)
What is Kinesiology? ! The study of human movement from the point of view of
the physical sciences.
! Mechanics: Biomechanics “Anatomy: Musculoskeletal anatomy “Physiology: Neuromuscular physiology
! Every structure that participates in movements of the body does so according to physical and physiological principles.
Why Study Kinesiology?
! Safety: structure movements to avoid doing harm to the body.
! Effectiveness: success or failure of meeting goals of performance.
! Efficiency: striving to achieve movement goal with least amount of effort.
Why Study Kinesiology? ! Help students gain
understanding of the nature & complexity of human motion.
! Learn what’s new: ! Advanced study: ! EMG, motion capture, force
transducers & computer analysis equipment.
! As technology advances, new abilities increase the depth of knowledge and understanding.
Why Are You Studying Kinesiology? ! For sound apparel design
one must understand the terminology, nature, & complexity of human motion.
! In groups come up with examples of where understanding motion is essential to design
Description of the motor skill performance Classification of the skill:
Classification provides clues to the nature of anatomical & mechanical requirements of a group of skills.
Simultaneous-sequential nature of motion ✕ Simultaneous – segments move as one ✕ Sequential – segments move in an orderly sequence
Fig 1.4
simultaneous sequential
Mechanical analysis Underlying mechanics objective(s)
✕ Balance: regain stability, attain mobility
✕ Locomotion: travel
✕ Projection: height, range & accuracy
✕ Manipulation: objects or resistance
✕ Maximum effort: speed, power, & force
In groups lets break down some activities to fit in these categories
Mechanical analysis
Underlying mechanics objective(s) ✕ Balance: regain stability, attain mobility
# Jump stop, track start ✕ Locomotion: travel
# Walking, running, skipping ✕ Projection: height, range & accuracy
# Pole vault, long jump, throwing ✕ Manipulation: objects or resistance
# Weightlifting, writing ✕ Maximum effort: speed, power, & force
# Sprinting, power lift, blocking
Musculoskeletal Framework ! An arrangement of:
! bones ! joints ! Muscles.
! The force is from a muscle attached to the bone or an external force (gravity or weight).
! Muscles can produce motion only by shortening.
Musculoskeletal Framework
! Acts as a lever system allowing for a great number of coordinated movements.
! An anatomical lever is a bone that engages in movement when force is applied to it.
Skeletal Framework ! Skeleton
! Provides:
! support
! muscle attachment
! protection Fig 2.1
Skeletal Framework !Axial:
!skull !spinal column !sternum ! ribs
!Appendicular:
!upper & lower extremities
Skeletal Framework ! Growth
“Osteogenesis
“Initial matrix
“Osteoblasts form bone on matrix.
“Bone forms in response to loading stress.
! Degeneration
! Osteoporosis
“Osteoclasts reabsorb bone in the absence of stress.
“Bones become more porous and brittle.
Skeletal Framework
Bone Growth and Degeneration
! Bone types
! Two types allow bone to be strong, yet light.
” Compact: dense outer bone
” Cancellous: open, spongy looking inner bone
Fig. 2.2
Classification of Bones
!Long
!Short
!Flat
!Irregular
Bone Growth and Degeneration
! Long: shaft or body with a medullary canal, and relatively broad, knobby ends “Femur, tibia, humerus,
ulna, radius, etc.
! Short: relatively small, chunky, solid “Carpals and tarsals
Bone Growth and Degeneration
!Flat: flat & plate like “Sternum, scapulae, ribs,
pelvis
! Irregular: bones of spinal column “Vertebrae, sacrum, &
coccyx
Joint Function ! Function of joints is to provide a means of moving or,
rather, of being moved.
! Secondary functions is to provide stability without interfering with the desired motions.
! All joints do not have the same degree of stability.
Joints
!Cartilaginous joint
!Fibrous joint
!Synovial (ligamentous joints)
Joints !Cartilaginous joint:
! United by fibrocartilage permits bending & twisting motions.
Joints
!Fibrous joint:
!Edges of bone are united by a thin layer of fibrous tissue, NO movement permitted.
Joints
!Synovial (ligamentous joints):
!Two bodies are tied together by ligaments, permits limited movement of no specific type.
Tendons Vs.
Ligaments
Joint Function ! Emerson’s law: “For everything
that is given, something is taken”. “Movement is gained at the
expense of stability.
! Resistance to displacement
! Factors responsible for stability “Bony structure “Ligamentous arrangement “Muscle tension “Fascia (connective tissue) “Atmospheric pressure
Joint Structure vs. Function
More stable, less mobile
More mobile, less stable
Ball and Socket Hip
Ball and Socket Shoulder
The Role of Muscles in Stability
! Muscles that span joints aid in stability.
! Especially when bony structure contributes little to stability.
Muscles acting to stabilize the shoulder
Ligaments ! Ligaments are strong, flexible, stress-resistant, somewhat elastic,
fibrous tissues that form bands or cords.
! Join bone to bone.
! Help maintain relationship of bones.
Ligaments and Movement
! Check movement at normal limits of joint.
! Resist movements for which joint is not constructed.
! Will stretch when subject to prolonged stress. ” Once stretched, their function is
affected.
Range of Motion (ROM) ! Factors affecting the stability of a
joint are also related to its ROM:
1. Shape of articular surfaces (musculoskeletal system contact).
2. Restraining effect of ligaments. 3. Muscles and tendons
! Flexibility should not exceed muscle’s ability to maintain integrity of joint.
! Additional factors include: injury or disease, gender, body build, heredity, occupation, exercise, and age.
Orientation of Body !Center of Gravity: imaginary point representing the weight
center of an object
!Line of Gravity: imaginary vertical line that passes through the center of gravity
Sagittal Frontal Transverse
Orientation of Body !Sagittal plane:
!Divides up: ! Left and right.
!Is perpendicular to the ground and divides the body into left and right.
Movements of Flexion and Extension around an axis of Coronal or Frontal and Lateral.
Sagittal
Orientation of Body !Frontal Plane:
! Divides up:
! Anterior or ventral = front
! Posterior or dorsal = back
Movements of Adbuction and Adduction around an axis of Sagittal or Anteroposterior
Frontal
Orientation of Body !Transverse:
! Divides up: ! top from bottom
! Superior and Inferior
! Axis passes horizontally from front to back; perpendicular to frontal plane.
Moments of rotational in the vertical axis
Transverse
! Flexion: reduction in joint angle.
! Extension: return movement from flexion.
Movement
Hyperflexion: arm is flexed beyond vertical.
Hyperextension: continuation of extension beyond starting position.
Reduction of Hyperextension: return movement from hyperextension.
Injury
Movement ! Abduction: movement away from the midline.
! Adduction: return movement from abduction.
Movement
! Alignment: optimum alignment should be based on efficiency, effectiveness, and safety.
! Range of Motion: ROM demands of an activity must be compatible to avoid injury.
! Flexibility: reduces internal resistance to motion.