Long Bone Anatomy
Diaphysis: Shaft of the bone– Made of compact bone
Epiphysis: Ends of the bone– Made mostly of spongy bone– There is a little compact bone on the outer surface
Articular Cartilage: cap of hyaline cartilage on each epiphysis which articulates with the next bone
Medullary canal: contains fat Periosteum: thin layer like an onion-skin that wraps around the bone. It is
anchored to the bone by fibers called Sharpie’s fibers. Nutrient foramen is in the shaft to allow passage for nutrient artery to the
bone.
Long Bones Contain Spongy and Compact Bone.
Compact Bone Anatomy
Compact bone is organized into cylinders called osteons.
The functional unit of compact bone is the osteon. It is the functional unit because all of the osteon’s functions occur within the osteon.
Compact Bone
Osteon (cylinders)
Osteon Anatomy
Osteoblasts are immature bone cells. They first arrive through the nutrient artery in the embryo
bone when it is still made out of cartilage. Osteoblast cells are shaped like stars. They align
themselves in concentric circles, as though they are holding hands. One ring of osteoblasts form a large circle, then the next ring inside is smaller, with a smaller ring inside that, and so on. The rings they form are called lamellae (from the word “laminate”, which means to lay on top of something. The rings lay on top of each other).
Compact Bone Lamella (rings)
Osteoblasts mature into osteocytes
The osteoblasts start to secrete hydroxyapatite (calcium and phosphate, which is bone) outside of themselves.
When they do this, they become trapped in the cave that they have made out of bone.
They are now called osteocytes (mature bone cell).
They cave they are trapped in is called a lacunae.
Compact Bone
Osteocytes (mature bone cells) trapped
in their lacunae (caves)
Osteon Anatomy
Each osteocyte is star shaped, so they seem to have arms and legs. These appendages also are trapped in the bone cave, so they form little canals.
These canals that hold their arms and legs are called canaliculi (little canals).
Canaliculi are needed to allow for diffusion of nutrients and wastes between the osteoblasts.
Canaliculi (little canals) hold the arms and legs of the osteocytes
Osteon Blood Supply
The nutrient artery, which entered the shaft of the bone, branches out and one branch runs through the center of each osteon.
The canal in the center of each osteon which contains the artery is called the Haversian canal, or central canal.
The blood supply needs to connect to the adjacent osteons, so there is a transverse canal, called Volkmann’s canal, or the perforating canal.
Haversian (central) canal
Volkmann’s (perforating) canal
Spongy Bone: Epiphysis
Instead of osteons, spongy bone has trabeculae (open spongy network which allows blood vessels to pass)
Bone Cells
Osteoblast (makes bone) Osteocyte (mature bone cell) Osteoclast (reabsorbs bone)
Tendons and Ligaments
Tendons attach muscle to bone. Tendons are not muscle tissue; they are connective tissue.
Ligaments attach bone to bone. Tendons and ligaments are both made from dense
regular connective tissue. An aponeurosis is a modified tendon that flares out
and attaches into connective tissue instead of bone. There is one that attaches the frontalis muscle (raises eyebrows) to the skull. Another one is in the palm of the hand.
Tendon: dense reg. CT
Terms to Know
Osteon: functional unit of compact bone. hydroxyapatite The crystalline structure of calcium and phosphate
that make up bone matrix lamellae The circular and concentric layers of collagen fibers lacunae The pockets or cavities in which the cells are trapped Haversian (or central) canal The large channels containing a blood
vessel which run longitudinally down the center of each unit canaliculi The “tiny channels” which run transversely through the
layers of bone and allow for diffusion of nutrients and wastes to the cells
perforating canal: connects one Haversian canal to another osteocytes The mature bone cells which are trapped in the matrix and
help to maintain it Osteoblasts: bone cells that lay down new bone Osteoclasts: bone cells that reabsorb bone
Terms to Know
Periosteum (secured to the bone by Sharpey’s fibers) Sharpey’s fibers (anchor the outer wrapping to the bony
matrix below it) Articular Cartilage (cap around long bone) Epiphysis (ends of long bones) Diaphysis (shaft of long bone) Medullary Cavity (hollow area inside long bone) Spongy Bone (contains trabeculae instead of osteons and
lamellae) Trabeculae (web-like formation, like a sponge) Tendon (attaches muscle to bone) Ligament (attaches bone-to-bone) Aponeurosis (modified tendon)
Cartilage and Bone
Structure and Function
Bone Characteristics
Vascular (has own blood supply) Regenerates well (because it is vascular) Contains hydroxyapatite (calcium and
phosphate) Forms mostly after birth Is not flexible
Formation of Endochondral (Embryonic) Bone
In the embryo, hyaline cartilage develops in the general shape of the future bone.
Periosteum forms on the outside of the developing bone.
Osteoblasts enter through the nutrient artery and deposit bony tissue in place of disintegrating cartilage.
Two Centers of Ossification
Primary Ossification– Starts in diaphysis; turns cartilage into bone.– Then the medullary canal hollows out
Secondary Ossification– Starts in epiphysis; turns cartilage into bone– It leaves behind a growth plate (epiphyseal line)
to allow the child’s bone to grow
Types of Bones
Long Bones– Arms and legs
Sesamoid Bones– Develop inside tendons and near joints
Flat Bones– Skull bones and scapula
Irregular Bones– Vertebrae
Cartilage
What are the three types of cartilage and where in the body can each of these three types of cartilage be found?– Hyaline cartilage (most of the joints)– Fibrocartilage (vertebral discs, pubic symphysis)– Elastic cartilage (ears)
What type of cartilage does an embryonic skeleton have?– Hyaline
Cartilage Characteristics
Avascular (no blood supply) Does not regenerate well (because it is
avascular) Contains no calcium Begins conversion to bone before birth Is flexible
Joint Disorders and Joint Injuries
Structure of joints makes them prone to traumatic stress Function of joints makes them subject to friction and wear Affected by inflammatory and degenerative processes Sprains – ligaments reinforcing a joint are stretched or torn Dislocation – occurs when the bones of a joint are forced
out of alignment Torn cartilage – common injury to meniscus of knee joint
Inflammatory and Degenerative Conditions
Bursitis – inflammation of a bursa due to injury or friction Tendonitis – inflammation of a tendon sheath Arthritis – describes over 100 kinds of joint-damaging
diseases– Osteoarthritis – most common type – “wear and tear” arthritis– Rheumatoid arthritis – a chronic inflammatory disorder – Gouty arthritis (gout) – uric acid build-up causes pain in joints
Lyme disease – inflammatory disease often resulting in joint pain; Lyme disease is caused by a bacterium and is transmitted to humans by the bite of infected blacklegged ticks. Typical symptoms include fever, headache, fatigue, and skin rash. If left untreated, infection can spread to joints, the heart, and the nervous system.
Osteoporosis: loss of minerals
Figure 6.15
Normal Bone
Osteoporosis
Stages of Healing a Fracture
Figure 6.14
Blood escapes
Fibrous callous
Spongy Bone callous
Osteoclasts remove excess bone
Four Stages of Fracture Repair
Fractures
CLASSIFICATION OF FRACTURES
CLOSED– Skin is not broken– Requires cast
OPEN– Bone has broken through the skin– Increased chance of infections, which can be life-
threatening.– Requires surgery, hospitalization and IV
antibiotics
CLASSIFICATION OF FRACTURES
INCOMPLETE– Only one side of the bone is broken
Examples– Hairline (stress) fracture– Greenstick fracture
COMPLETE– Both sides of bone is broken
CLASSIFICATION OF FRACTURES
Once you have described if the fracture is open or closed, and complete or incomplete, then you describe the fracture shape:
• Stress (hairline) fracture
• Greenstick fracture
• Epiphyseal fracture
• Transverse fracture
• Oblique fracture
• Spiral fracture
• Comminuted fracture
• Avulsion fracture
• Impacted fracture
• Compression fracture
• Depression fracture
Types of Fractures
http://video.about.com/orthopedics/Fractures-1.htm
http://video.about.com/orthopedics/Fractures-2.htm
STRESS FRACTURE
STRESS FRACTURE: least serious, get tiny, almost invisible breaks. Usually from overexertion. Muscle builds up faster than bone. Six weeks into military basic training camp, see lots of stress fractures from too much new running.
Can’t see it on x-ray for three weeks. Diagnose it by placing a tuning fork on the bone, but not at the area of tenderness…the vibration travels down the shaft of the bone until it reaches the fracture site. This will be very painful if it is a stress fracture.
Stress Fracture, 3 weeks later
GREENSTICK FRACTURE
GREENSTICK FRACTURE: most common in children; like breaking a green twig, it’s not completely broken. It breaks on one side but bends on the other. Bones in children are not fully mineralized.
Table 6.1
Epiphyseal Fracture
EPIPHYSEAL FRACTURE The growth plate in the bone of a child is called the
epiphyseal growth plate. That area is weaker than bone, so the whole thing can be broken through during an injury.
It is very serious because the bone may grow crooked thereafter. May need repeated surgeries to straighten the bone as it grows.
TRANSVERSE FRACTURE•Bone breaks completely through, right to left, in the transverse plane
OBLIQUE FRACTURE•Bone breaks completely through, from upper to lower, in an oblique plane
SPIRAL FRACTURE: Bone was twisted, such as in skiing or rollerblading.
COMMINUTED: The most serious; bone shatters into many small pieces. Bone graft might be needed.
AVULSION FRACTURE
– A piece of bone is broken off by the sudden, strong contraction of muscle.
– Common sports injury– Often seen with “groin muscle injury”
Avulsion Fracture
The person twisted their ankle and a tendon pulled off a piece of the bone.
IMPACTED FRACTURE
IMPACTED FRACTURE:
Pressure was exerted on both ends of the SAME bone.
The bone is crushed
Often seen in femur after falling from a height.
Impacted fracture of the
femur• The person fell
from a height, and the head of the femur jammed into the neck of the femur.
COMPRESSION FRACTURE
COMPRESSION FRACTURE
TWO bones are forced together
Bone is crushed.
Example would be two vertebrae being crushed together from a fall from a height.
People with osteoporosis (loss of bone minerals) often get this type of fracture spontaneously.
Table 6.1
DEPRESSION FRACTURE
DEPRESSION FRACTURE
Bone is pressed inward
Often seen in skull fracture from blunt object
Depression Fracture
PATHOLOGICAL FRACTURES
PATHOLOGICAL FRACTURE:
When the bone breaks first, then the patient falls. This is especially common in the hip bone of someone with osteoporosis.
ARTHRITIS
OSTEOARTHRITIS RHEUMATOID ARTHRITIS GOUTY ARTHRITIS (GOUT)
OSTEOARTHRITIS
• OSTEOARTHRITIS: more common the older you get.
• The articular cartilage begins to break down, and bone spurs start to grow. The surface is no longer smooth, and movement now causes pain.
• It is also known as “wear and tear” arthritis. • This is the most common disorder of joints. • Can be mild to severe, needing joint replacement.
These people can actually predict the weather, since the synovial fluid is under pressure. As air pressure changes, fluid expands and hurts more.
Artificial Hip Joint
RHEUMATOID ARTHRITIS
RHEUMATOID ARTHRITIS: not a disease of old age. It’s an autoimmune disease where body attacks and destroys the cartilage in synovial joints. It is not known for spur formation, unlike osteoarthritis.
They swell and become unusable, causing knarled hands and feet. Usually need joint replacements, but that will only last about 15 years. First replacement in 60 years old is ok, but in a 30 year old, eventually bone degrades and can no longer take the stem of the implant.
It does NOT make many bone spurs; it is degenerative in nature.
Rheumatoid Arthritis
GOUTY ARTHRITIS (GOUT)
Gout is caused by a genetic error in the metabolism of uric acid. An gouty episode is triggered by eating too much red meat or protein.
The breakdown product of proteins is urea, which leads to uric acid crystals in the cooler areas of the body, especially the MPJ’s (metatarsal-phalangeal joints) of the base of the big toes. The crystals poke the cartilage like needles.
Gout is not known for spur formation, unlike osteoarthritisWas more common years ago when people ate nothing but
meat. The crystals cause the joint to swell up.
OTHER BONE DISORDERS
• Osteomalacia (“malformed bones”) is a genetic malformation of the bones. The epiphyseal plates are particularly affected.
• Rickets is a type of osteomalacia that is NOT genetic; it is caused by lack of vitamin D. Like all types of osteomalacia, rickets also particularly affect the epiphyseal plates.
OTHER BONE DISORDERS
Osteomalacia (genetic) Rickets (not genetic)
OTHER BONE DISORDERS
Osteomyelitis is an infection of bone.
OTHER BONE DISORDERS
•Achondroplasia is a genetic condition where the bones don’t develop properly, especially in the epiphyseal plates, and causes a type of dwarfism.
CHONDROMALACIA
•Means a problem with the shape of a cartilage joint.•Chondromalacia patella is a condition in which the patella rubs on the femur in the knee joint, becomes scratched or deformed, causing pain. Don’t get this confused with achondroplasia, which is dwarfism!
OTHER BONE DISORDERS
Paget’s disease is more common in older persons, and may be related to a viral infection. It is characterized by excessive bone deposition.
Paget’s disease
OTHER BONE DISORDERS•ANKYLOSING SPONDYLITIS: is a disorder in which vertebrae bind strongly together to limit the flexibility of the spine.
OTHER JOINT DISORDERS
Synovitis is inflammation of the synovial tissues. May need cortisone injections.
Arthroplasty is a surgical procedure to repair or remodel a damaged joint.
Lyme disease is an inflammatory arthritis of the knee joint, caused from a bacterial infection after a tic bite.
Polydactyly (Many digits)
• The extra digit is usually a small piece of soft tissue; occasionally it contains bone without joints; rarely it may be a complete, functioning digit.
• The extra digit is most common on the ulnar (little finger) side of the hand, less common on the radial (thumb) side, and very rarely within the middle three digits.
• These are respectively known as postaxial (little finger), preaxial (thumb), and central (ring, middle, index fingers) polydactyly.
• Polydactyly can occur by itself as an autosomal dominant mutation in a single gene.
• But, it usually is one feature of a syndrome of congenital anomalies.
• 1 in every 500 live births
Polydactyly (Many digits)
Polydactyly (Many digits)
Born with two thumbs!
Syndactyly (Fused digits)
In fetal development, syndactyly is normal. At about 16 weeks of gestation, an enzyme dissolves
the tissue between the fingers and toes, and the webbing disappears.
In some fetuses, this process does not occur completely between all fingers or toes and some residual webbing remains.
Simple syndactyly can be full or partial, and is present at birth (congenital).
Syndactyly (Fused digits)
Due to an abnormal gene.
Syndactyly can be simple or complex.– In simple syndactyly, adjacent fingers or toes are joined by soft
tissue.– In complex syndactyly, the bones are fused.
Syndactyly can be complete or incomplete.– In complete syndactyly, the skin is joined all the way to the tip of
the finger– In incomplete syndactyly, the skin is only joined part of the
distance to the fingertip.
Syndactyly (Fused digits)
Syndactyly (Fused digits)
• Complex syndactyly occurs as part of a syndrome (such as Apert's syndrome) and typically involves more digits.
• Apert Syndrome is syndactyly with malformations of the skull.
Apert syndrome
Syndactyly (Fused digits)
Fenestrated syndactyly means the skin is joined for most of the digit but in a proximal area there is gap in the syndactyly with normal skin.
This type of syndactyly is found in amniotic band syndrome.
Amniotic band syndrome Congenital disorder caused by entrapment of
fetal parts (usually a limb or digits) in fibrous amniotic bands while in utero.
Polysyndactyly
End of Lecture
The rest of this PPT is not on the exam
There is a disc between each bone in the spine.The nerves exit the bone to supply
all the parts of the body.
If you choke off a nerve by twisting the bone around it, the bone starts to crush the nerve.
Just like a light with a dimmer switch; if you turn the electrical current down,
the light won’t shine as brightly. If you cut off some of the nerve supply to an organ,
the organ isn’t going to function as well.
The discs are made out of something like jelly. As long as your spine is aligned, the jelly will stay in the center.
But if the spine becomes twisted, the jelly will get pushed in the opposite direction, and the shock absorption will be lost.
If you lift a box while you are standing and twisting,
that’s when you get tears in the disc.
TEARS IN THE DISC
The fluid in the disc begins to leak out the side of the disc.
OsteoarthritisAlso Known As:
“Wear and Tear” ArthritisOr Degenerative Arthritis
Occurs when cartilage wears away, leaving raw bone to rub against raw bone.
PROPER DESK WORK STATION
Phone headset for hands-free use
Keyboard pad under your wrists
Computer at eye leveland 18-25” away from your face
The front of the chair should drop off
Adjustable seat: Feet flat to the floorOr a foot rest under the feet
Chair with good lumbar support or$10 lumbar pillow