Analysis of Skeletal Remains - Worksheet



Analysis of Skeletal Remains - Worksheet

In this activity, skeletons will be examined for how they vary according to the following:

• Gender      (based on the pelvis & skull)

• Race          (based on the maxilla, and other characteristics of the skull)

• Age            (based on general characteristics)

• Height        (calculated based on the length of individual bones)

    Students will be evaluated as to whether or not they correctly identified the gender, age, and race of the individual.

    Being able to determine Left and Right is also crucial to the practice of forensic anthropology, not only for skeletal reconstruction, but also to determine the number of casualties.  Reference to a complete skeleton is helpful, but one is never around when you need one (as would happen if you are investigating a skeleton in the woods.  That will not be a part of this activity, but it easily could be.

GENDER

    One of the issues of concern to the forensic anthropologist is the gender of the human remains.  There are several things than may, on the surface, be useful to gender determination, but, upon closer examination, are not very useful.  For example, females are, on average, shorter than males, but a short skeleton can easily be male.  This is due very simply to the fact that each gender follows a Gaussian distribution (a.k.a. a Bell Curve).

[pic]

    As such, it is easily possible to have a female at the tall end of the height curve, and a male at the short end of the height curve.  The curves for gender overlap, for the most part, with the peak of each curve slightly off-set.  It is easy to say that the average height is shorter for females than it is for males, but that information is useless when we examine two individual skeletons.

    There are several ways to more accurately determine the gender of a skeleton.  One of them is by examining the pelvis, which can be identified accurately 95% of the time.

[pic]

|[pic] |[pic] |

|Original images from |

|Circle the Appropriate Answer |

|Angle > 90 degrees   or   < 90 degrees |Angle > 90 degrees   or   < 90 degrees |

|Sacrum Forward   or   Backward |Sacrum Forward   or   Backward |

|Pelvic Outlet Small   or   Large |Pelvic Outlet Small   or   Large |

|Ilia Close   or   Spread |Ilia Close   or   Spread |

|Female   or   Male |Female   or   Male |

 

Another way is to examine the skull.  This is still fairly accurate, but not as accurate as the pelvis.  Forensic anthropologists can accurately identify the skull somewhere between 85 and 90% of the times.  This can be complicated by several factors.  If a skull is incomplete, then, of course, there is less to work from.  Some of the distinguishing characteristics, such as larger bone landmarks for muscle attachments in males, can be easily confused with the landmarks of more athletic females.  To put it simply, since the landmarks are often for the attachment of muscles, the larger the muscles, or the more one uses the muscles, the larger the landmarks.

|Landmarks |Female |Male |

|Chin |Rounded |Square |

|Mastoid Process |Small |Large |

|(Behind Ear) | | |

|External Occipital Protuberance |Small |Large |

|(Back of Skull) |(Not Prominent) |(Prominent) |

|General Anatomy |Gracile (i.e., Graceful) |Robust |

|Forehead |Vertical |Receding |

| | |(Careful with the comments . .) |

|Brow Ridges |Slightly Developed |Prominent |

|(Location of Eyebrows) | | |

|Muscle Lines |Slightly Developed |Prominent |

|Orbital Margins |Sharp |Rounded |

|(Edge of Eye Socket) | | |

|Angle of Ascending Ramus |Obtuse |Close to 90 degrees |

|(Back Corner of the Jaw) | | |

Now try to identify the skulls below by gender:

|[pic] |[pic] |

|Original images from |

|Circle the Appropriate Answer |

|Chin Rounded   or   Square |Chin Rounded   or   Square |

|Mastoid Process Small   or   Large |Mastoid Process Small   or   Large |

|Occipital Protuberance Small   or   Large |Occipital Protuberance Small   or   Large |

|General Anatomy Gracile   or   Robust |General Anatomy Gracile   or   Robust |

|Forehead Vertical   or   Receding |Forehead Vertical   or   Receding |

|Brow Ridges Slight   or   Prominent |Brow Ridges Slight   or   Prominent |

|Muscle Lines Slight   or   Prominent |Muscle Lines Slight   or   Prominent |

|Orbital Margins Sharp   or   Rounded |Orbital Margins Sharp   or   Rounded |

|Angle of Ramus 90 degrees   or   Obtuse |Angle of Ramus 90 degrees   or   Obtuse |

|Gender Female   or   Male |Gender Female   or   Male |

Now that you have had some practice, what about this lone skull?

|[pic] |Circle the Appropriate Answer |

| | |

| |Chin Rounded   or   Square |

| | |

| |Mastoid Process Small   or   Large |

| | |

| |Occipital Protuberance Small   or   Large |

| | |

| |General Anatomy Gracile   or   Robust |

| | |

| |Forehead Vertical   or   Receding |

| | |

| |Brow Ridges Slight   or   Prominent |

| | |

| |Muscle Lines Slight   or   Prominent |

| | |

| |Orbital Margins Sharp   or   Rounded |

| | |

| |Angle of Ramus 90 degrees   or   Obtuse |

| | |

| | |

| | |

| |Gender Female   or   Male |

| | |

| | |

| | |

|Original image from |

RACE

    There are several features that can be used to determine the race of an individual.  In terms of the skull, a great place to start is the maxillary bone.  The left and right maxillary bones form the roof of the mouth, contain the upper 16 teeth in the adult (the upper 10 teeth in the child), and form the outline of the nasal cavity (the nasal cavity itself involves several other bones: ethmoid, inferior nasal conchae, lacrimal, nasal, sphenoid, and vomer).

    The arch of the maxilla can be found in three basic shapes: hyperbolic, parabolic, and rounded.  Each of the the following three races have their own shape: (1) African = hyperbolic, (2) European = parabolic, and (3) Asian = rounded.

|[pic] |[pic] |

|Hyperbola |Parabola |

| | |

    The incisors, as well, differ in their basic shape.  The incisors (click HERE to refresh your memory) fall into two basic categories, based on the shape of the lingual (tongue) surface of the tooth.  These two categories are: (1) shovel-shaped, and (2) spatulate, or spatula-shaped.  As there is more than one race with spatulate incisors, other indicators are necessary to positively identify race, although this single feature can be used to eliminate one of the possibilities.  Each of the the following three races have their own shape: (1) African = spatulate , (2) European = spatulate , and (3) Asian = shovel-shaped.

Based upon both criteria, label the following maxilla according to race:

|[pic] |

|Original image from |

|Circle the Appropriate Answer |

|Arch Shape |Arch Shape |Arch Shape |

|Hyperbola,   Parabola,   or  Rounded |Hyperbola,   Parabola,   or  Rounded |Hyperbola,   Parabola,   or  Rounded |

|Incisor Spatulate  or Shovel-shaped |Incisor Spatulate  or Shovel-shaped |Incisor Spatulate  or Shovel-shaped |

|RACE African  Asian  Caucasian |RACE African  Asian  Caucasian |RACE African  Asian  Caucasian |

    In addition to determining gender, there are characteristics of the skull that can be used to determine the race of an individual.  Many of these features are quite subtle, and require detailed examination of the skull.  A couple of features, however, are more easily seen.  For example, in people of African ancestry, the nasal opening is more flared.  Another example is that of the zygomatic arch (or cheek bone), which is angled more forward in people of Asian ancestry, thus giving the person a slightly more flattened face..  Unfortunately, a true examination of racial characteristics is not possible on a worksheet.

|[pic] |[pic] |

|Original images from |

|African Male Nose |Asian Male Cheek |

|(Note Flaring) |(Note how it is angled forward) |

|Now Compare Examples of Skulls from these three Races |

|Asian |African |European |

AGE

    The idea of age being represented by the skeleton was introduced in the Skeletons as Forensic Evidence website we looked at earlier.  One way we could tell was by looking at the condition of the bones themselves, with the older bones being more likely to be arthritic.  Examine the bones below, and label which is arthritic (and therefore older), and which is the younger:

|[pic] |

|Original image from |

|Circle the Appropriate Answer |

|Arthritic Yes   or   No |Arthritic Yes   or   No |

|Younger   or   Older |Younger   or   Older |

Another way to determine age is by looking at the development of the sutures:

[pic]

Images from , and adapted by Mr. Lazaroff

Note, for example, that the adult skull has no remaining suture (called the frontal suture) in the middle of the Frontal bone.  Remember, also, that all the sutures ultimately become more filled-in ("closed") as we age.  Compare the two skulls below to determine which skull is from an adult, and which is from an adolescent:

|[pic] |[pic] |

|Original images from |

|Circle the Appropriate Answer |

|Frontal Suture Present   or   Absent |Frontal Suture Present   or   Absent |

|Other Sutures "Open"   or   "Closed" |Other Sutures "Open"   or   "Closed" |

|Adolescent   or   Adult |Adolescent   or   Adult |

    Can you see the fontanels in the image below?  Note how many places in the infant skeleton are still made of cartilage, which appears blue.  The indicates how much of the skeleton is still developing.

[pic]       

Please note that the pelvis is still divided into the three parts: ilium, ischium, and pubis; these will ultimately fuse into a single pelvic bone (a.k.a., Os coxa, or Innominate).  Note the many bones in the sternum, which will ultimately fuse into one.  Remember that the total number of bones in the skeleton, 206, is based on an adult skeleton.  The actual number in an infant is much higher!

    Please also note that there is a great deal of cartilage at the end of each of the long bones, an area called the epiphysis (see the image below).  (If each end is called the epiphysis, how do we show one end of the humerus from the other end in the name?  Easy: Proximal epiphysis& Distal epiphysis!)  The cartilage at all the epiphyses (pl.) indicates that a great deal of growth in long bones is actually happening at the ends (thus making the bones longer.  Another way to determine age is to look at the epiphysis (end) of a long bone (the shape of which should be self-explanatory).

[pic]

    First of all, an x-ray is actually a film negative.  When light (Don't forget that x-rays are a form of light!) hits photographic film, it turns the film black; in making a print (i.e., making a negative of the negative, which is therefore a positive), the image printed will look white.  The more light, the darker the negative, and the brighter the developed image.  X-rays pass easily through muscle and most organs, but not through bone; this will make the bones appear lighter in the negative (which works well for us, as bones are already white!).  An x-ray image (radiograph) of a child will reveal a dark area where the growth plates are still made of cartilage (more x-rays can pass through cartilage, which is less dense, thus making a dark area); these areas are the epiphyseal plates.  An x-ray radiograph of an adult will reveal a white area where the growth plates have been turned into bone (fewer x-rays can pass through bone, which is more dense, thus making a white line); these areas are the epiphyseal lines.  Examine the radiographs below, and determine whether they are from adults or children:

|[pic] |[pic] |

|Images are from |

|Circle the Appropriate Answer |

|Epiphyseal Plate   or   Line |Epiphyseal Plate   or   Line |

|Adult   or   Child |Adult   or   Child |

HEIGHT

    Lastly, often a skeleton is incomplete.  Despite this, it is still possible to calculate, with a certain amount of accuracy, the height of a skeleton, even if the calculation is based upon a single bone!  Apart from height, average weight can be calculated based on not only the general size of the bones, but also by evidence of the weight borne by the bones.  These weight calculations, however, are too complex to demonstrate without detailed examination of the bones, which obviously cannot be done on a paper worksheet. 

    Any of the major bones of the arm or leg can be used to determine height.  The major bones of the arm are the humerus, ulna, and radius.  The major bones of the leg are the femur, tibia, and fibula.  The Given that not everyone's arm to leg ratio is exact, height is usually estimated by using more than one bone, if possible.  Granted, a complete skeleton does not require calculation, but skeletons are not always complete, especially ancient skeletons.  The calculations we will be looking at will be of the femur, humerus, and radius.

[pic]

SmartDraw Image adapted by Mr. Lazaroff

    In order to calculate the height, in inches, follow the formulas below for each of the bones.  Be sure to indicate height not only in the total number of inches, but in terms of feet and inches (i.e., a person who is 62 inches is also described as being 5 feet, 2 inches tall, or 5' 2").  NOTE: The calculations, of course, are different when measurements are in centimeters.

|Bone |Formula for calculating Body Height (in inches) |

|(See Image) | |

| |Female |Male |

|Femur |Height equals (length of femur x 1.94)  +  28.7 |Height equals (length of femur x 1.88)  +  32 |

|Humerus |Height equals (length of humerus x 2.8)  +  28.1 |Height equals (length of humerus x 2.9)  +  27.8 |

|Radius |Height equals (length of radius x 3.3)  +  32 |Height equals (length of radius x 3.3)  +  34 |

    In order to calculate the height, in cm, as most of the world does, follow the slightly different formulas below for each of the bones.

|Bone |Formula for calculating Body Height (in cm) . . . EVERYONE! |

|(See Image) | |

| |Female |Male |

|Femur |Height equals (length of femur x 1.94)  +  72.9 |Height equals (length of femur x 1.88)  +  81.3 |

|Humerus |Height equals (length of humerus x 2.8)  +  71.4 |Height equals (length of humerus x 2.9)  +  70.6 |

|Radius |Height equals (length of radius x 3.3)  +  81.3 |Height equals (length of radius x 3.3)  +  86.4 |

    Now plug in the following numbers into the formula to determine the height to the nearest 1/2 inch (expressed both as inches -- x" -- and as feet and inches -- x' + y") of the deceased:

|Gender |Bone |Length |Calculations |Height |Height |Multiply by 2.54 |

| | | |SHOW YOUR WORK! |x" |x' + y" |to get the Height |

| | | | |in Inches |(Feet + Inches) |in cm |

|Female |Femur |17.9" |  | | | |

| | | |  | | | |

| | | |  | | | |

|Male |Femur |17.9" |  | | | |

| | | |  | | | |

| | | |  | | | |

|NOTE: The same length is shown to illustrate the different calculations |

|required for the same measurements, depending on the gender of the deceased. |

|Female |Humerus |11.5" |  |  |  |  |

|Male |Humerus |11.5" |  | | |  |

| | | |  | | | |

| | | |  | | | |

|Female |Radius |9.3" |  | | |  |

| | | |  | | | |

| | | |  | | | |

|Male |Radius |9.3" |  |  |  |  |

Check Your Work using our Bone Length to Body Height Calculator

|Gender |Bone |Length |Calculations |Height |Multiply by |Height in Feet & |

| | | |SHOW YOUR WORK! |in cm |0.3937 to get the|Inches |

| | | | | |Height | |

| | | | | |in inches | |

|Female |Femur |45.5 cm |  | | | |

| | | |  | | | |

| | | |  | | | |

|Male |Femur |45.5 cm |  | | | |

| | | |  | | | |

| | | |  | | | |

|NOTE: The same length is shown to illustrate the different calculations |

|required for the same measurements, depending on the gender of the deceased. |

|Female |Humerus |29.2 cm |  |  |  |  |

|Male |Humerus |29.2 cm |  | | |  |

| | | |  | | | |

| | | |  | | | |

|Female |Radius |23.6 cm |  | | |  |

| | | |  | | | |

| | | |  | | | |

|Male |Radius |23.6 cm |  |  |  |  |

QUESTIONS:

1. What is the easiest way to determine the gender (using the skeleton) of an individual, and why?

2. What is the easiest way to tell (using the skeleton) whether a teenager is lying about her/his age, and why?

3. Why can determining gender from a skull be difficult?

4. Why should a forensic anthropologist use more than one bone (if possible) to determine the height of an individual?

5. What other issue is important to question four, especially if there is only one bone from which to work?

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