Body Composition Techniques - PowerPoint PPT Presentation

1 / 59
About This Presentation
Title:

Body Composition Techniques

Description:

Dual-Energy X-ray Absorptiometry DEXA, DXA Dual Energy X-ray Absorptiometry Two different energy level X-rays Lean, fat, and bone mass each reduce (attenuate) ... – PowerPoint PPT presentation

Number of Views:361
Avg rating:3.0/5.0
Slides: 60
Provided by: Dr938
Category:

less

Transcript and Presenter's Notes

Title: Body Composition Techniques


1
Body Composition Techniques
2
DIRECT ASSESSMENT
  • The only direct methods for body composition
    assessment are dissection or chemical analysis
  • Brussels Cadavre Study
  • 13 female and 12 male cadavers, age range 5594
    years, 12 embalmed and 13 unembalmed
  • After comprehensive anthropometry, each cadaver
    was dissected into skin, adipose tissue, muscle,
    bones, organs and viscera.
  • Volumes and densities of all tissues were
    determined by weighing the tissues underwater.
  • A complete dissection lasted from 10 to 15 h and
    required a team of about 12 people.

3
Indirect or Doubly Indirect estimation of Body
Fat
  • All the techniques used routinely for Body Fat
    estimation are either
  • Indirect
  • body fat is estimated using one or more
    assumptions e.g. Underwater Weighing
  • Doubly Indirect
  • body fat is estimated by predicting the results
    of an Indirect methodology from a related measure
    by regression analysis e.g. Skinfold prediction
    equations

4
Indirect Methods for the Estimation of Body Fat
5
DENSITOMETRY
BODY DENSITY MASS / VOLUME Units gm/ml Any
method that determines the volume of the body is
a densitometric method
6
GOLD STANDARD
  • Densitometry via underwater weighing was the
    gold standard for determination of body fat
    since the 1940s. Since the late 1990s a 4
    compartment method is regarded as the best
    reference method.
  • Body Density can be determined accurately
  • Unfortunately, Body Fat can not because of
    assumptions made in transforming density to Fat

7
DENSITOMETRY
Volumetry by Water Underwater (Hydrostatic)
Weighing Helium Dilution BodPod Whole Body
Plethysmography
8
Predicting Fat from Density
ASSUMPTIONS Body can be divided into two
components Fat Non-Fat (Fat Free) Masses Each
has different, known and constant densities
9
Fat is not Adipose Tissue
  • FAT is ether extractable lipid molecules
  • ADIPOSE TISSUE is a tissue designed to store FAT
    (lipid) in adipocytes. Contains all the
    components of a tissue cellular structures,
    extracellular matrix, water etc. as well as FAT
    (lipid) in the adipocytes. Adipose tissue is
    found subcutaneously and internally

10
SIRI EQUATION
Assumed Densities FAT MASS 0.9 gm/ml NON-FAT
(FAT FREE) MASS 1.1 gm/ml Equation Body Fat
(4.95/Density) - 4.5) x 100
11
Siri Equation Fat (4.95/Density)-4.5) x 100
12
BROZEK EQUATION
Assumptions FAT MASS 0.9 gm/ml LEAN BODY MASS
1.095 gm/ml (some essential lipids in Lean Body
Mass) Equation Fat (4.57/Density)-4.142) x
100
13
DENSITOMETRYVolumetry by Water
Determine body volume by displacing water and
directly measuring the change in water volume
14
DENSITOMETRYVolumetry by Water
 
Where Wa Body Weight in Air Vwater displaced
Measured Volume of water displaced by the Body RV
Residual Volume C Estimate of volume of
entrapped intestinal gas
15
Archimedes (287-212 BC)
King Heiro of Syracuse summoned him to test the
composition of a supposedly gold wreath If
assumed to be an alloy of only Gold and Silver he
could use the laws of bouyancy to determine the
fractional composition Pure Gold and Silver have
constant and different densities
16
DENSITOMETRYUnderwater Weighing
  • use Archimedes principle to determine body
    volume by calculating weight of water displaced

Small Tank or Open Swimming Pool
17
DENSITOMETRYUnderwater Weighing
  • use Archimedes principle to determine body
    volume by calculating weight of water displaced

 
Where Wa Body Weight in Air Ww Body Weight
freely submerged in water Dw Density of water
RV Residual Volume C Estimate of
volume of entrapped intestinal gas
18
DENSITOMETRYHelium Dilution
  • Densitometry
  • Volume determined using a sealed chamber into
    which a known volume of Helium is introduced.
  • Volume of air in chamber determined from dilution
    of Helium.
  • Volume without subject determined (V1)
  • Volume with subject determined (V2)
  • Body Volume of Subject V1 V2
  • Density Mass / Body Volume
  • Fat from Siri or Brozek equation
  • Does not require Residual Volume calculation

19
DENSITOMETRYBODPOD - Whole Body Plethysmography
20
DENSITOMETRYBODPOD - Whole Body Plethysmography
  • Measures body volume by air displacement
  • actually measures pressure changes with injection
    of known volume of air into closed chamber. Large
    body volume displaces air volume in chamber which
    results in bigger increase in pressure with
    injection of known volume of air
  • Advantages over hydrodensitometry
  • subject acceptability
  • precision (reliability not accuracy)
  • Limitations
  • costs 25-30K
  • still assumes constant density of FFM and fat for
    prediction of Body Fat from whole body density

21
DENSITOMETRYBODPOD - Whole Body Plethysmography
22
TOTAL BODY WATER (isotope dilution)
  • Determined by introducing a marker fluid that
    moves freely in body water and is not
    metabolized.
  • Isotopes of water - Deuterium Oxide, tritiated
    water
  • Marker introduced.
  • Following equilibriation period (eg 2 hrs) sample
    body fluid
  • apply conversion formulae to estimate TBW,
  • FAT predicted from TBW
  • Assume a constant for the fraction of water in
    the Fat Free Mass or at least FFM (73.8, 72,3
    etc.)
  • Even if no technical error in Body Water, there
    would still be S.E.E. 3.6 Body Fat associated
    with biological variability

23
K40 - Whole Body Counting
  • K40 emits gamma radiation
  • Using whole body counters the amount of radiation
    emitted can be determined
  • Fat Free Mass (Non-fat Mass) estimated
    Assumptions
  • Constant fraction of K40 in potassium
  • Constant fraction of potassium in non-fat mass

24
Doubly Indirect Methods for the Estimation of
Body Fat
25
Doubly Indirect Methodsfor Estimating Body Fat
  • Skinfold predictions
  • Ultrasound
  • Radiography
  • Bioelectrical Impedance Analysis (BIA)
  • Near-infrared Spectrophotometry (NIR)
  • DEXA

26
General Research Approachfor Doubly Indirect
Methodologies
  • Selected subject sample
  • Determine body density or fat using an accepted
    methodology often underwater weighing
  • Measure subjects with other technique
  • Produce regression equations to best predict
    density or fat from new technique

27
Regression Equationsto Predict Body Fat
Y mX c Y Body Fat X Anthropometric
measure (Skinfolds etc) Correlation Coefficient
(r) Standard Error of Estimate (SEE)
28
Anthropometric (skinfolds)prediction of Fat
Adipose Tissue
  • Adipose Tissue not Fat
  • Equations predict Fat (Lipid)
  • Over 100 equations available for the prediction
    of percentage body fat or body density
  • All are sample specific
  • Specific for age, gender, activity level,
    nutrition etc.

29
Assumptions inherent in prediction of Fat from
Skinfolds
  • Based upon densitometry

Which is better UW Weighing or Skinfold
predictions? fat from skinfolds is predicted
using equations developed from UW Weighing of
subjects. UW Weighing S.E.E. 2.77 Fat
Skinfolds S.E.E. 3.7 Fat
30
Assumptions inherent in prediction of Fat from
Skinfolds
  • Constant Skinfold Patterning
  • The pattern of deposition of skinfolds around the
    body is known to differ from individual to
    individual.
  • Females have characteristic deposition of
    secondary sexual adipose tissue on the upper
    arms, hips and thighs.
  • With ageing in both sexes there is a shift in
    dominance from limb to trunk deposition of
    adipose tissue

31
Assumptions inherent in prediction of Fat from
Skinfolds
  • Constant Skinfold Compressibility
  • Skinfold compressibility varies from site to site
    due to differences in skin thickness, skin
    tension and adipose tissue composition.
  • Skinfolds in females are more compressible than
    in males.
  • Skinfold compressibility decreases with age due
    to dehydration and changes in elastic proprties
    of tissues

32
Assumptions inherent in prediction of Fat from
Skinfolds
  • Constant Tissue Densities
  • Tissue densities vary greatly particularly that
    of bone.
  • 6 weeks of bed rest can cause a 2 loss in bone
    mineral.

33
Assumptions inherent in prediction of Fat from
Skinfolds
  • Constant Ratio of external/internal adipose
    tissue
  • The ratio of external/internal adipose tissue
    varies with level of obesity
  • The ratio of external/internal adipose tissue
    declines with ageing.

34
Assumptions inherent in prediction of Fat from
Skinfolds
  • Constant Fat (lipid) content of adipose tissue
  • Lipid content of adipose tissue varies from
    individual to individual due to variations in
    adipocyte size and number.

35
YUHASZ
Male Fat 0.1051(Sum 6 SF)
2.585 Female Fat 0.1548(Sum 6 SF)
3.580 Canadian University Students Can never
give a negative answer. What if weight alone
changes or is different?
36
Durnin Womersley
  • Density a (log10Sum 4 SF) c
  • Overpredicts by 3 - 5 Fat
  • British (left side)
  • Age and gender specific equations
  • Upper body sites
  • Electronic Skinfold Caliper

37
Ultrasound
High Frequency Sound (6 MHz) Some sound reflected
at tissue interfaces Time taken for return of
sound used to estimate distance based upon
assumed speed of sound in that tissue
38
Fat prediction from Ultrasound
  • Regression equations predicting densitometrically
    determined Fat
  • S.E.E.s comparable to skinfold predictions
  • Beware of predict anything from anything once
    it is in a computer

39
RADIOGRAPHY
  • Measurements from radiographs
  • uncompressed tissue thicknesses
  • Regression equations predicting densitometrically
    determined Fat

40
BIOELECTRICAL IMPEDANCE ANALYSIS (BIA)
  • BIA measured by passing a microcurrent through
    the body
  • Fat predicted from sex, age, height, weight
    activity level BIA
  • Influenced by hydration level
  • Claims that you can guess fat more accurately

41
Bioelectrical Impedance Analysis
  • BIA measures impedance by body tissues to the
    flow of a small (lt1mA) alternating electrical
    current (50kHz)
  • Impedance is a function of
  • electrical resistance of tissue
  • electrical capacitance (storage) of tissue
    (reactance)

42
BIA basic theory
  • The body can be considered to be a series of
    cylinders.
  • Resistance is proportional to the length of the
    cylinder
  • Resistance is inversely proportional to the
    cross-sectional area

43
Typical BIA Equations
  • Males
  • FFM -10.68 0.65H2/R 0.26W 0.02R
  • Females
  • FFM -9.53 0.69H2/R 0.17W 0.02R
  • Where
  • FFM fat free mass (kg)
  • H height (cm)
  • W body weight (kg)
  • R resistance (ohms)
  • BF 100 x (BW-FFM)/BW

44
BIA Advantages and Limitations
  • Advantages
  • costs (500-2000)
  • portable
  • non-invasive
  • fast
  • Limitations
  • accuracy and precision
  • no better, usually worse than hydrodensitometry

45
Major types of BIA analyzers
46
(No Transcript)
47
Client Friendly
48
Site Specific?
49
BIA Protocol
  • Very sensitive to changes in body water
  • normal hydration
  • caffeine, dehydration, exercise, edema,
    fed/fasted
  • Sensitive to body temperature
  • Avoid exercise
  • Sensitive to placement of electrodes
  • conductor length vs. height

50
Near Infra-Red Spectrophotometry (NIR)FUTREX
  • Near Infra-Red light emitted from probe
  • Reflected light monitored
  • Changes due to differing optical densities
  • Influenced by hydration
  • Relative fat may be useful

51
Infrared InteractanceConway et al. 1984
Reflected light has modified frequency
spectrum. SEE 3.0 bodyfat. The correlation
coefficients between body fat as predicted by
the IRI method and as estimated by the D20
dilution technique were 0.84,0.95, and 0.94 for
males, females, and males plus females, respective
ly (p lt 0.01 for all three values).
52
Dual-Energy X-ray Absorptiometry
53
DEXA, DXADual Energy X-ray Absorptiometry
  • Two different energy level X-rays
  • Lean, fat, and bone mass each reduce (attenuate)
    the X-ray signal in unique ways
  • Whole body
  • Regional
  • Osteoporosis

54
X-Ray Measurement System
  • Dual energy attenuation values are measured for
    each point in the image
  • Calibration standards (acrylic, aluminum, delrin)
    are measured
  • The fat and lean mass of each point in the image
    is calculated by direct comparison to the
    standards

55
(No Transcript)
56
BMI 12.6 Fat 3.2
BMI 23.7 Fat 48.1
BMI 18.1 Fat 23.1
57
What DEXA Measures
  • Fat and fat-free mass (based upon the standards)
  • Bone Mineral Mass
  • Regional results for the above

58
DEXA Cannot Measure...
  • Protein Mass
  • 3-D Fat Distribution
  • Hydration Status
  • Tissue inside bone (brain, marrow, blood)

59
Next generation of Body Composition Models
  • Two compartment plus
  • Water
  • Bone mineral
  • Protein
  • 3 or 4 compartment models now regarded as the
    reference standard rather than underwater weighing
Write a Comment
User Comments (0)
About PowerShow.com