Workbook questions 7 & 8

Question 1

On a diagram -
Point out the ilium, pubis, and ischium.

Label the Head of femur
greater trochanter
lesser trochanter
patella
lateral epicondyle
lateral condyle
medial epicondyle
medial condyle
tibial tuberosity
medial malleolus
head of fibula
lateral malleolus
calcaneum
talus
navicular
cuboid
cuniform

Answer 1

See notes

Question 2

In the standing position, which are the main weight bearing bones in the lower limb?

Answer 2

Femur, tibia and calcaneum

Question 3

Hence, should an individual fall from a height and land on their feet, what parts of the skeleton should you x-ray and why?

Answer 3

X-rays of the whole of the lower limb and the vertebral column. The direction of the force passes up from the feet, through the lower limb to the pelvis and vertebra. Hence any weight bearing bones and joints can be affected, e.g. calcaneal fracture, acetabular fracture and lumbar vertebral fracture.

Question 4

What is the function of the femoral canal?

Answer 4

The canal contains no discrete structures other than a lymph node or two. The canal acts as a “dead space” to allow for the distension of the femoral vein, particularly during heavy exercise, to accommodate venous return from the limb.

Question 5

Which structures does the femoral sheath enclose?

Answer 5

Femoral artery, femoral vein and femoral canal, but not the femoral nerve

Question 6

What are the actions of the quadriceps femoris muscle (2 X ½ marks) and the purpose of the smooth fascial covering of the rectus femoris muscle (1 mark)?

Answer 6

The quadriceps acts to extend the knee joint. Since one of its components, the rectus femoris takes origin above the hip joint, acting on its own assists in the flexion of the hip; the smooth fascial covering of the muscle helps its to move smoothly over the adjacent muscles.

Question 7

Explain why the vastus medialis muscle has horizontal fibres to the patella?
(Hint: consider patella dislocation).

Answer 7

During movements of the knee, there is a tendency for the patella to be displaced laterally. In order to overcome this, the horizontal fibres of vastus medialis help to prevent this displacement. Moreover, the lateral condyle of the femur is at a slightly higher elevation compared to the medial condyle. This also assists in patellar stability.

Question 8

Where and how would you locate the femoral vein to obtain venous blood in a collapsed patient?

Answer 8

The femoral vein lies within the femoral triangle. It is medial to the femoral artery. To locate the femoral vein, one needs to establish the position of the femoral artery whose pulsations can be felt easily 2 to 3 inches below the inguinal ligament. The artery enters the thigh passing underneath the inguinal ligament at the mid-inguinal point.

Question 9

Why might a patient complain of pain and paraesthesia on the medial side of the lower leg following stripping of the long saphenous vein for varicosities? (Hint: consider cutaneous nerve supply to that area)

Answer 9

The long saphenous vein in the leg is accompanied by a cutaneous (sensory)
branch (saphenous nerve) of the femoral nerve. Stripping of the vein may lead to trauma or injury to this nerve which innervates the medial side of the lower leg.

Question 10

Look at the route of the femoral nerve on its way through the pelvis (but remember the nerve lies on the iliacus and psoas muscles) and explain how the nerve could be damaged.

Answer 10

The femoral nerve arises from L2, L3 and L4 lumbar nerves in the substance of the psoas muscle and enters the thigh deep to the inguinal ligament. The psoas muscle lies anterior to the sacro-iliac joint. The nerve passes underneath the inguinal ligament which stretches between the pubic tubercle on the superior pubic ramus and the anterior superior iliac spine.

Question 11

How would you test (i) the power of flexion of the hip, (ii) the power of knee extension?

Answer 11

i. Ask the patient to lie on their back and acutely flex the hip on the abdomen to flatten the lumbar spine.
ii. Ask the patient to sit on a chair and extend the knee against resistance.

Question 12

Explain why sensation over the lateral side of the thigh was preserved.

Answer 12

The lateral side of the thigh is supplied by the lateral (femoral) cutaneous nerve of the thigh from the lumbar plexus; the front and intermediate aspects of the thigh are innervated by the anterior and medial cutaneous nerves which are branches of the femoral nerve.

Question 13

The x-rays showed that the previously disrupted right sacro-iliac joint was now well aligned and the fractures in the ischial and pubic rami were healing.

What other nerve supplying the thigh passes close to the sacro-iliac joint and might have been injured by this fracture?

Answer 13

The obturator nerve.

Question 14

Which hip movement would you examine to test the integrity of this other nerve?

Answer 14

Adduction – the adductors of the hip (adductor longus, brevis, magnus, gracilis, pectineus and obturator externus) are all supplied by the obturator nerve.

Question 15

If the femoral nerve was divided (in this case it was stretched and partially damaged), why would there be sensory loss in part of the foot and state where?

Answer 15

A sensory branch of the femoral nerve called the saphenous nerve (running alongside the great saphenous vein) innervates the medial aspect of the foot.

Question 16

Name the three main extracapsular ligaments of the hip joint and state their function.

Answer 16

Iliofemoral ligament: prevents hyperextension of the hip during standing (screwing the head of the femur into acetabulum)
Pubofemoral ligament: prevent excessive abduction
Ischiofemoral ligament: prevent hyperextension (screwing the head of femur into acetabulum)

Question 17

Why is hip extension limited to only about 15°? Hint: consider functions of ligaments above.

Answer 17

Because of the anteriorly placed strong iliofemoral ligament which prevents hyperextension; the ligament becomes very taut in extension of the hip joint.

Question 18

What is the structural basis for classifying the hip fracture as being intracapsular or extracapsular?

Answer 18

The capsule of the hip joint attaches proximally to the acetabulum and distally to the neck of the femur – anteriorly to the intertrochanteric line and the root of the greater trochanter and posteriorly to the intertrochanteric crest. Fractures of the femoral neck that involve the bone within the margins of the capsule are classified as intracapsular; those that occur beyond the trochanters are classified as extracapsular.

Question 19

Why should a subcapital fracture in the elderly often lead to avascular necrosis of the femoral head while a pertrochanteric fracture usually heals well with a pin and plate procedure?

Answer 19

A subcapital fracture may tear and damage the joint capsule thereby disrupting the blood supply to the femoral head; branches from the medial circumflex artery & to a lesser extent the lateral circumflex artery run in the capsule retinacula. Disruption of blood supply to the head would ultimately result in femoral head undergoing necrosis (avascular necrosis). Pertrochanteric fracture being outside the joint capsule, leave the retinacula undisturbed and thus does not disrupt blood supply.

Question 20

Look up shortening and mensuration of the lower limb. Why, on examination of a patient with fractured neck of the femur, would you often find shortening of the limb and lateral (external) rotation of the foot?

Answer 20

Mensuration of Lower Limb
Whole limb: ASIS to med malleolus
Hip: ASIS to Grt Trochanter
Femur: (ASIS or) Grt Troch to knee joint line
Tibia: Knee joint line to med malleolus
Compare sides
Shortening of the limb:
This occurs because the strong muscles of the thigh (flexors, adductors and extensors) pull the distal fragment of the femur upwards; thus the leg is shortened.
Lateral (external) rotation of the foot:
Fractured neck of the femur allows the shaft of the femur to move independently of the hip joint; axis of rotation of the femur normally passing through the head shifts to pass through the greater trochanter and along the long axis of the femoral shaft. Iliopsoas muscle which in normal situation also acts as a medial rotator, now acts as a lateral rotator of the femur because of the fractured neck.

Question 21

Why, on examination of a patient with a dislocation of the hip, would you often find shortening of the limb and medial (internal) rotation of the foot?

Answer 21

Shortening of the limb:
During hip dislocation the head of the femur is pulled upwards by the strong flexor muscles (iliacus & psoas major), extensors (gluteus maximus and hamstrings) and adductors causing limb shortening. In posterior hip dislocation (which occurs in motor car accidents when the flexed knee hits against the car dashboard) the femoral head is pushed backwards over the posterior margin of the acetabulum and comes to lie on the lateral surface of the ilium.
Medial(internal) rotation of the foot:
The anterior parts of the gluteus medius and minimus pull on the greater trochanter and cause the thigh to rotate medially.

Question 22

What bony landmarks are used to determine the course of the sciatic nerve. Hence, which injury to the hip joint may damage the sciatic nerve?

Answer 22

the posterior superior iliac spine and the ischial tuberosity. It then descends into the thigh vertically at the mid point between the ischial tuberosity and the greater trochanter. Hence, posterior dislocation of the femoral head from the acetabulum would stretch or severely damage the sciatic nerve (e.g. consider dashboard impact of front seat occupants in RTA).

Question 23

What is the principal function of the gluteus maximus muscle and the iliotibial tract?

Answer 23

Gluteus maximus extends the thigh from the flexed position and causes lateral rotation of the thigh; also helps rising from a sitting position. It is important in running when a powerful thrust off the trailing foot is required. Fibres from the gluteus maximus insert into the iliotibial tract (specialised condensation of the deep fascia – fascia lata – of the thigh) which crosses the knee joint to be attached to the tibia. It helps to steady the femur on the tibia during standing by supporting and keeping the knee joint in extension.

Question 24

Explain the significance of the “safe area” for intramuscular injection into the buttock?

Answer 24

Intramuscular injection into the buttock is aimed at the upper outer quadrant (“safe area”) to avoid injuring the sciatic nerve and other neurovascular structures in the medial and inferior parts of the gluteal region.

Using bony landmarks, it can be found under an outstretched hand when the tip of the thumb on the ASIS and the thumb/thenar eminence are along side the iliac crest.

Question 25

Which ligaments convert the greater and lesser sciatic notches into foramina? What is the role of these ligaments in the erect posture?

Answer 25

Sacrospinous & sacrotuberous ligaments. The ligaments limit rotation (upward movement) of the inferior part of the sacrum during transmission of weight of the body down the vertebral column in erect posture.

Question 26

How would you perform the Trendelenberg test in an adult? Consider Patient Safety: When might it be unsafe to do this test?

Answer 26

Ask the patient to stand on his/her “good” leg. The pelvis on the opposite side should elevate demonstrating that the gluteus medius and minimus are working efficiently. Now ask the patient to stand on the “bad” leg. The pelvis on the opposite side will sag/fall indicating that the gluteal muscles are not working properly. This is termed as a positive Trendelenberg sign.
If the patient is likely to lose balance or fall when standing on one leg (support may be needed) e.g. if a lower limb is unlikely to support their weight or if they have neurological problems affecting balance.

Question 27

Why would damage to the superior gluteal nerve cause a positive Trendelenberg sign?

Answer 27

Superior gluteal nerve supplies gluteus medius and minimus. Both these muscles are involved in stabilising the pelvis during walking.

Question 28

Why would damage to the inferior gluteal nerve not cause a positive Trendelenberg sign?

Answer 28

Inferior gluteal nerve supplies gluteus maximus which acts on the hip joint - the muscle is a powerful extensor of the hip joint during activities such as brisk walking or running

Question 29

Where do the gluteal nerves originate from?

Answer 29

The gluteal nerves (superior & inferior) originate from the lumbo-sacral plexus;

Their root values are L4 and S1.

Question 30

What course do the gluteal nerves follow to reach the muscles they innervate?

Answer 30

They leave the pelvis via the greater sciatic foramen. Superior gluteal nerve passes superior to the piriformis muscle while the inferior gluteal nerve passes inferior to the piriformis muscle

Question 31

Between which bony points would you measure to confirm his right lower limb was shorter than the left? Distinguish between apparent and true limb shortening.

Answer 31

Greater trochanter of femur & the medial malleolus – indication of true length of leg; the distance between the two points would be greater on the left side. Apparent limb shortening s caused by e.g. fixed joint deformity or pelvic tilt. True limb shortening involves actual loss of bone length.

Question 32

What would you measure to show the shortening was in the hip?

Answer 32

Distance between the anterior superior iliac spine & greater trochanter of the femur; the distance between the two points would be greater on the unaffected side.