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OPTIMAL BODY WEIGHT FOR PERFORMANCE C HAPTER 15
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Body Build, Size, and Composition Body size is determined by height and weight. Body build is the form or structure of the body. Muscularity Linearity Fatness Fat mass Fat-free mass Body composition refers to the chemical composition of the body.
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MODELS OF BODY COMPOSITION
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Did You Know…? Fat-free mass is composed of all of the body's nonfat tissue including bone, muscle, organs, and connective tissue. Lean body mass includes all fat-free mass along with essential fat. Lean body mass is difficult to measure so the fat mass/fat-free mass model is most often used.
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Did You Know…? Body composition is a better indicator of fitness than body size and weight. Being overfat (not necessarily overweight) has a negative impact on athletic performance. Standard height-weight tables do not provide accurate estimates of what an athlete should weigh because they do not take into account the composition of the weight. An athlete can be overweight according to these tables yet have very little body fat.
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Essential Fat All fat is not bad!! We need fat for padding of organs, insulation, energy source There is a minimum amount that we need to function daily = essential fat Gender specific –males ~ 3% –females ~ 7%
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Essential Fat Why the differences? –A male at 7% is like a female at 17% –Women are more complicated!! –Women have babies, menstrual cycles, etc… and need more fat for the survival of the species
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Assessing Body Composition Densitometry (hydrostatic weighing) Skinfold fat thickness Bioelectric impedance Infrared interactance
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Densitometry Body density = Body mass Body volume Body mass = measured on a regular scale Body volume = measured using hydrostatic (underwater) weighing accounting for water density and air trapped in lungs % body fat = (495 ÷ body density) – 450
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UWW Body Density = BW÷((BW-UWW)/H 2 0 Density) - RV-0.1
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Residual Volume Cannot blow all of the air out of your lungs (that would be bad!!) We need to account for the air that is left in the lungs (RV) + the air in the GI (~0.1L)
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Determining RV Prediction equations based on height and/or Vital Capacity –Male = 0.24 x VC –Female = 0.28 x VC –Male = 0.019(Ht cm)+0.0115(age)-2.24 –Female = 0.023(Ht cm)+0.021(age)-2.978 Nitrogen Analysis (rebreathing apparatus)
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Procedures 1. Wear light clothing (swimsuit) 2. Use bathroom prior to weighing 3. Calibrate scale 4. Weight the chair or seat and equipment 5. Measure water temp 6. Remove all air from clothing
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Procedures 7. Sit in seat 8. Submerge 9. Blow all air out of lungs and remain still 10. 3-10 trials; average of the highest three 11. Subtract weight of apparatus from average UWW
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UNDERWATER WEIGHING TECHNIQUE
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Did You Know…? Inaccuracies in densitometry are due to variation in the density of the fat-free mass from one individual to another. Age, sex, and race affect the density of fat-free mass.
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Skinfolds Measurement of subcutaneous adipose tissue at specific anatomical sites BD or %fat is obtained with the use of equations (either population specific or generalized)
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SF Procedures Take all measurements on the right side of the body Identify and mark site Grasp skin and fat between thumb and index finger 1cm above marked site Continue grasping at the site while taking the measurement
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SF Procedures Place the jaws of the caliper perpendicular to the fold and slowly release the pressure Take the measurement 4 seconds after pressure is released Read the dial of the nearest 0.1mm (Harpenden or Holtain), 0.5mm (Lange), or 1mm (plastic)
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SF Procedures Take at least 2 non-consecutive measurements - if values vary by +10% take additional measurements No measurements directly after exercise Reliability should be 0.95 or greater
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Sites Chest Subscapular Midaxillary Suprailiac Abdominal Triceps Biceps Thigh Calf
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Equations Jackson’s 3-site –Males - BD=1.10938- 0.0008267(sum3)+0.0000016(sum3) 2 - 0.0002574(age) –chest, abdomen, thigh –Females - BD=1.0994921- 0.0009929(sum3)+0.0000023(sum3) 2 - 0.0001392(age) –triceps, suprailiac, thigh
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BIA Based on the premise that fat-free tissue is a better conductor of an electrical current (contains water and electrolytes) than fat tissue The resistance to current flow is inversely related to FFM
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BIA Abstain from eating or drinking for 4 hours prior No exercise 12 hours prior No alcohol 48 hours prior No diuretics (caffeine) prior to assessment
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Equations Each machine has its own equation (developed by the manufacturer and is proprietary) %fat = 4.57 ÷ (1.1411 - ((BW * Resistance) ÷ Ht 2 )) - 4.142 * 100 –ht = length of the conductor
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BIA Reseach Equations Population-specific equations have been developed through research Used for children, different races, different ages etc… (p. 161) May have better accuracy than machine equations
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Advantages Non-invasive Safe Easy to administer Accurate on some populations Field technique
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Advantages More costly than SF calipers Many studies have begun to cross-validate (just because the equation worked on the researchers population doesn’t mean it will work on others) Beginning to develop specific equations –get resistance value from machine and enter into a specific equation
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Disadvantage The accuracy has been questioned: –Skinfolds2.4 % error –BIA5% error –Visual3.1% error Race cannot be entered into the machine Children distribute water differently than adults
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DEXA 3 component model –bone, fat, fat-free mass assesses total bone mineral content usually found in a clinical setting
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Advantages Accurate Measurement of bone content (osteoporosis) safe rapid minimal subject cooperation (just lay there)
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Disadvantage Costly Limited Access
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NIR Based on the premise that the degree of infrared light absorption is related to the composition of the substance through which light passes Fat and Fat-Free Mass absorb and reflect light differently
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NIR Emit infrared light at wavelengths of 940- 950 nm into a body part (ie., biceps) and measures the intensity of the re-emitted light More specific equations/machines are necessary
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Advantages Non-invasive Safe Easy to administer Field technique
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Disadvantages Cost? Is it worth it? Few Age/Gender Specific Equations Accurate? –Futrex 50003.1-4.2% –Futrex 5000A6.3% –Futrex 10004.8-6.3% –Sum 32.4-3.6 –BIA5.0-7.1%
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Body Mass Index (BMI) Ratio of a person’s weight (kg) to the height squared (m 2 ) Used to categorize people with respect to their degree of obesity Not used to determine % fat
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BMI 20-25 kg/m2 - desirable 25-29.9 kg/m2 - overweight >30.0 - obesity
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Waist to Hip Ratio Indication of the pattern of body fat distribution Indicator of the health risks of obesity –excess trunk fat - increased risk of hypertension, type 2 diabetes, high cholesterol, CAD, premature death
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Waist to Hip Ratio Risks increase with increasing ratios –very high risk >0.94 young men and 0.82 young women –very high risk >1.03 older (60-69 years) men and 0.90 for older women
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Measurements Made with a tape measure Waist - at the level of the umbilicus Hips - biggest part of the gluteals
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Body Composition and Performance Maximizing fat-free mass Desirable for strength, power, and muscular endurance Undesirable for endurance or jumping sports if result is a gain in weight Minimizing relative body fat Desirable, especially in sports in which the body weight is moved through space Improves speed, endurance, balance, agility, and jumping ability
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Risks With Severe Weight Loss Dehydration Chronic fatigue Disordered eating and eating disorders Menstrual dysfunction Bone mineral disorders
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Appropriate Weight Guidelines Maximize performance within the specific sport Are based on body composition Emphasize relative body fat rather than total body mass Use a range of relative fat values that are considered acceptable for the athlete’s age and sex
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Achieving Optimal Weight Combine proper diet with exercise. Lose no more than 0.5 to 1.0 kg (1 to 2 lb) per week. Reduce caloric intake to 200 to 500 kcal less than daily energy expenditure. Use moderate resistance and endurance training.
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Calculations for Optimal BW 1. Determine % fat 2. Calculate Fat Weight –BW * %fat ÷ 100 3. Calculate Fat-Free Weight –BW - FW 4. Calculate Desirable Weight –FFW ÷ (1- (desired %fat ÷ 100))
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Calculations 5. Calculate amount of weight that needs to be lost –BW - Desirable Weight 6. Calculate kcal deficit –3500 kcal per pound of weight needed to be lost 7. Assuming loss of 1 pound (3500 kcals) per week, calculate # weeks to reach goal
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