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  1. 1. Prepared by Dr.hawre dlzarForensic doctor and anthropologist  
  2. 2.  Anatomy:The femur is the longest, heaviest, and strongest bone in thebody. It supports all of the body’s weight duringstanding, walking, and running. Because of its strength anddensity, it is frequently recovered in forensic, archaeological, andpaleontological contexts. The femur is a particularly valuablebone because of the information it can provide on the stature ofan individual
  3. 3.  The femur articulates with the acetabulum of the os coxae. Distally, it articulates with the patella and the proximal tibia. The leg’s actions at the hip include medial and lateral rotation, abduction, adduction, flexion, and extension. At the knee, motion is far more restricted, confined mostly to flexion and extension. Although the main knee action is that of a sliding hinge, this joint is one of the most complex in the body.
  4. 4. a. The femoral head is the rounded proximal part of the bonethat fits into the acetabulum.It constitutes more of a sphere than the hemispherical humeralhead.b. The fovea capitis is the small, nonarticular depression nearthe center of the head of the femur. It receives the ligamentumteres from the acetabular notch of the os coxae.c. The femoral neck connects the femoral head with the shaftand the greater trochanter.
  5. 5.  d. The greater trochanter is the large, blunt, nonarticular prominence on the lateral, proxi- mal part of the femur. It is the insertion site for the gluteus minimus (anterior aspect of the trochanter) and gluteus medius muscles (posterior aspect), both major abductors of the thigh and stabilizers of the hip. Their origins are on the broad, iliac blade of the os coxae. These muscles are crucial in stabilizing the trunk when one leg is lifted from the ground during bipedal locomotion.
  6. 6. The lesser trochanter is the blunt, prominent tubercle on theposterior femoral surfacejust inferior to the point where the neck joins the shaft. This isthe point of insertion ofthe iliopsoas tendon (the common tendon of the iliacusmuscle, originating in the iliac fossa,and the psoas major muscle, originating from the lumbarvertebrae and their disks). Thesemuscles are major flexors of the thigh at the hip.
  7. 7. spiral line, spiraling inferior to the lesser trochanter, connects theinferior end of the intertrochanteric line with the medial lip of the linea aspera. It is theorigin of the vastusmedialis muscle, a part of the quadriceps femoris muscle, a kneeextensor that inserts on the anterior tibia via the patella.The pectineal line is a short, curved line that passes inferolaterally fromthe base of the lesser trochanter, between the spiral line and glutealtuberosity. It is the insertion of the pectineus muscle, which originatesfrom the pubic part of the os coxae and acts to adduct,laterally rotate, and flex the thigh at the hip.femoral shaft is the long section between the expanded proximal anddistal ends of the bone.
  8. 8. medial condyle is the large, articular knob on the medial side ofthe distal femur. Its medial surface bulges away from the axis ofthe shaft. The medial condyle extends more distally than thelateral condyle.medial epicondyle is the convexity on the medial side of themedial condyle. It is a point of attachment for the medialcollateral ligament of the knee.
  9. 9.  Landmarks • head  • fovea capitis • shaft  • lesser trochanter • greater trochanter  • intertrochanteric crest • femoral tubercle  • quadrate tubercle • adductor tubercle  • lateral epicondyle • medial epicondyle  • lateral condyle • medial condyle  pectineal line • trochanteric fossa  • linea aspera • gluteal tuberosity  • intercondylar line • intercondylar fossa • neck
  10. 10. The femur ossifies from five centers: the shaft, the femoralhead, the distal end, the greater tro- chanter, and the lessertrochanter. The femoral head appears at about 6 months to a year.It begins to fuse to the diaphysis at 14 –19 years in males, and atabout 12–16 years in females. The greater trochanteric epiphysisappears between ages 2–5. It then begins to fuse at 16 –18 yearsin males, and at 14 –16 years in females. The lesser trochantericepiphysis appears between ages 7–12 and then begins to fuse at16 –17 years in both sexes. The distal epiphysis appears justbefore birth. It begins to fuse with the shaft at about 16 – 20 yearsin males, and at about 14 – 18 years in females (Scheuer andBlack, 2000).
  11. 11. Neither intact femora nor femoral fragments are easily confusedwith other bones.The femoral head has a fovea and is a more complete sphere thanthe humeral head.The femoral shaft is larger, has a thicker cortex, and is rounder incross section than any •other shaft. It has only one longitudinal feature with sharpedges, the linea aspera
  12. 12. • For intact femora or proximal ends, the head is proximal and faces medially. The lessertrochanter and linea aspera are posterior.• For isolated femoral heads, the fovea is medial and displaced posteriorly and inferiorly.The posterior inferior head–neck junction is more deeply excavated than the anterosuperiorjunction.• For proximal femoral shafts, the nutrient foramen opens distally, and the linea aspera isposterior and thins inferiorly. The gluteal tuberosity is superior and faces posterolaterally.• For femoral midshafts, the nutrient foramen opens distally, the bone widens distally, andthe lateral posterior surface is usually more concave than the medial posterior surface.• For distal femoral shafts, the shaft widens distally and the lateral supracondylar ridge ismore prominent than the medial. The medial condyle extends more distally than the lateral.• For femoral distal ends, the intercondylar notch is posterior and distal, and the lateral bor-der of the patellar notch is more elevated. The lateral condyle bears the popliteal groove, andthe medial condyle bulges away from the line of the shaft. Relative to the shaft axis, thelateral condyle extends more posteriorly than the medial. The medial condyle extends moredistally than the lateral because in anatomical position the femur angles beneath the body.
  13. 13. 1-Maximum femoral length (Martin, 1928: 1037, #1; Buikstraand Ubelaker, 1994: 82,#60): The maximum length that can be measured between the topof the femoral head and the bottom of the farthest condyle.Measured with an osteometric board.
  14. 14. 2-Femoral biomechanical length (Trinkaus et al., 1999: 757):Using a large sliding cali- per, place the stationary jaw on theinferiormost point of the superior femoral neck, and then measurethe distances to: 1) the distalmost point of the medial condyle;and 2) the distalmost point of the lateral condyle. Biomechanicallength is the average of these two distances.3. Femoral bicondylar (or physiological) length (Martin, 1928:1037–1037, #2; Buikstra and Ubelaker, 1994: 82, #61): Placeboth condyles firmly against the stationary end of an osteometricboard and, while keeping the shaft of the femur parallel to thesurface of the board, measure the distance to the furthest point onthe femoral head.
  15. 15. 4. Femoral midshaft circumference (Martin, 1928: 1040, #8; Buikstra and Ubelaker,1994: 83, #68): Determine the location of midshaft (preferably using 50% of femoralbiomechanical length) and use a flexible cloth tape to determine the minimum circum-ference at that location.5. Femoral epicondylar breadth (Martin, 1928: 1041, #21; Buikstra and Ubelaker, 1994:82, #62): With a sliding caliper or an osteometric board, measure the distance between themedialmost and lateralmost points on the epicondyles.6. Femoral torsion (Martin, 1928: 1043, #28): Place the femur posterior-side-down on a flattable so that it rests stably on three points: the posteriormost points of each condyle and theposteriormost point of the greater trochanter. Using a goniometer or protractor, measure theangle formed between the longitudinal axis of the femoral neck (and head) and the table.7. Femoral anteroposterior (or sagittal) midshaft diameter (Martin, 1928: 1039: #6;Buikstra and Ubelaker, 1994: 83, #66): Determine the location of midshaft (preferably50% of femoral biomechanical length) and use a sliding caliper to determine the antero-posterior dimension at that point (including the linea aspera).
  16. 16. NECROSIS OF THE FEMORAL HEADPathologySubcapital or transcervical fracture of the neck of thefemur frequently is complicated by aseptic necrosis of partor all of the femoral head .This is due to thepeculiarity of the blood supply to the femoral head, whichconsists of three groups of vessels: (1) the artery of the ligamentumteres, which supplies approximately the medialthird of the head surrounding the fovea (2)the inferiormetaphyseal vessels coursing beneath the synovium on theinferior aspect of the femoral neck, which supplies theinferior portion of the head; and (3)the lateral epiphysealvessels, which enter the head within 1 cm distal to themargin of the articular cartilage.
  17. 17. Pathology:Legg-Calvr-Perthes disease has a clear relationshipwith disrupted blood supply that is probably initiated bytrauma. It is associated with extensive aseptic necrosis ofthe epiphysis of the femoral head. It is an uncommondisease, occurring unilaterally in 90% of cases. It usuallybegins between 5 and 9 years of age, and is much morecommon in boys than girls (Jaffe 1972:566; Resnick1995g:3561).
  18. 18.  Human_Osteology__Third_Edition. human osteology and skeletal radiology. Human Anatomy2012.