Preface | |
Body Composition Comes of Age: A Modest Proposal for the Next Generation. The New Reference Man | p. 1 |
Magnetic Resonance Imaging in Human Body Composition Research: From Quantitative to Qualitative Tissue Measurement | p. 12 |
Composition of Skeletal Muscle Evaluated with Computed Tomography | p. 18 |
Observation of Intramyocellular Lipids by [superscript 1]H-Magnetic Resonance Spectroscopy | p. 25 |
In Vivo Determination of Body Composition of Rats Using Magnetic Resonance Imaging | p. 32 |
Study of the Isolated Perfused Rat Heart Exposed to Ischemia Using [superscript 31]P NMR Surface Coil | p. 42 |
Assessing Body Composition and Changes in Body Composition: Another Look at Dual-Energy X-ray Absorptiometry | p. 45 |
Total Body Dual X-ray Absorptiometry Is a Good Measure of Both Fat Mass and Fat-free Mass in Liver Cirrhosis Compared to "Gold-Standard" Techniques | p. 55 |
Comparisons between Hologic QDR 1000W, QDR 4500A, and Lunar Expert Dual-Energy X-ray Absorptiometry Scanners used for Measuring Total Body Bone and Soft Tissue | p. 63 |
Comparison of Air-Displacement Plethysmography, Hydrodensitometry, and Dual X-ray Absorptiometry for Assessing Body Composition of Children 10 to 18 Years of Age | p. 72 |
Measurements of Body Composition by Dual-Energy X-ray Absorptiometry Improve Prediction of Energy Expenditure | p. 79 |
Dual-Energy X-ray Absorptiometry Measurements of the Body Composition of Pigs of 90- to 130-Kilograms Body Weight | p. 85 |
Measurement of Changes in Soft Tissue Mass and Fat Mass with Weight Change: Pencil- versus Fan-Beam Dual-Energy X-ray Absorptiometry | p. 94 |
Accuracy of Dual-Energy X-ray Absorptiometry in Infant Scans: An Assessment Using Anthropomorphic Phantoms | p. 98 |
Validation of Estimates of Body Composition by Dual-Energy X-ray Absorptiometry in Fluid Overload Conditions | p. 101 |
Validation of Estimates of Lean Tissue Mass Made by Dual-Energy X-ray Absorptiometry | p. 104 |
Comparison of Two Phantoms for Body Composition with Dual-Energy X-ray Absorptiometry | p. 107 |
K-40 and Dual-Energy X-ray Absorptiometry Estimates of Lean Weight Compared: Normals and Patients with Neuromuscular Disease | p. 111 |
A New Measuring Device for Quantifying the Amount of Mineral in the Heel Bone | p. 115 |
Evaluation of a New DXA Fan-Beam Instrument for Measuring Body Composition | p. 118 |
Underestimation of Fat-free Mass in Women, but Not Men, by Dual-Energy X-ray Absorptiometry: Comparison with Total Body Potassium and Bio-electrical Impedance Analysis | p. 126 |
Of Mermaids and Mountains: Three Decades of Prompt Activation in Vivo | p. 128 |
Assessment of Background Hydrogen by the Monte Carlo Computer Code MCNP-4A during Measurements of Total Body Nitrogen | p. 134 |
In Vivo Elemental Partition Analysis Using Fast Neutrons: A Tool for Testing the Efficacy of New Clinical Interventions | p. 140 |
Calibration of the Brookhaven National Laboratory Delayed Gamma Neutron Activation Facility to Measure Total Body Calcium | p. 148 |
Estimation of Extracellular Water by Instrumental Neutron Activation Analysis of Bromine | p. 152 |
Assessing Regional Muscle Mass with Segmental Measurements of Bioelectrical Impedance in Obese Women during Weight Loss | p. 154 |
Bioelectrical Impedance Analysis: What Does It Measure? | p. 159 |
Hydrational Status Assessed by Bioelectrical Impedance Spectroscopy and Dilution Methods in Patients with Classical Dengue Fever | p. 163 |
Using Localized Impedance Measurements to Study Muscle Changes in Injury and Disease | p. 171 |
Comparison of Whole Body and Segmental Bioimpedance Methodologes for Estimating Total Body Water | p. 181 |
Relationships between Bioelectric Resistance and Somatotype in 9- to 11-Year-Old Children | p. 187 |
Use of Bioimpedance Spectroscopy to Assess Effects of Perioperative Treatment with Growth Hormone on Fluid Changes in Patients Undergoing Major Surgery | p. 190 |
A Solution with an Elemental Composition of Reference Man for Calibrating in Vivo Neutron-Activation Analysis Scanners | p. 193 |
Is There Advantage in Using Multiple Frequency Bioelectrical Impedance Analysis to Predict Gentamicin Distribution Volume in Neonates? | p. 196 |
Association between Ethnicity, Body Mass Index, and Bioelectrical Impedance: Implications for the Population Specificity of Prediction Equations | p. 199 |
Estimation of Body Composition by Multifrequency Bioimpedance Measurement in Children | p. 203 |
Bioelectrical Impedance Spectroscopy in Health and Disease: Correspondence between Whole Body and Segmental Bioelectrical Impedance Spectroscopy Indices in Patients with Classical Dengue Fever | p. 205 |
Bioelectrical Impedance Spectroscopy and Body Composition | p. 210 |
Low-Impedance Localized Measurements Using Standard Bioelectrical Impedance Analysis Instruments | p. 214 |
Appendicular Lean Body Mass: Prediction by Bioelectrical Impedance Analysis | p. 218 |
The Effect of Electrode Placement in Measuring Ipsilateral/Contralateral Segmental Bioelectrical Impedance | p. 221 |
Bioelectrical Impedance Analysis Prediction Equations differ between African Americans and Caucasians, but It Is Not Clear Why | p. 225 |
A New Theoretical Model for Predicting Bioelectrical Impedance Analysis | p. 227 |
Gamma Resonance Absorption: New Approach in Human Body Composition Studies | p. 229 |
Gamma Ray Nuclear Resonance Absorption: An Alternative Method for in Vivo Body Composition Studies | p. 236 |
Assessment of Body Volume Using Three-Dimensional Photonic Scanning | p. 247 |
Feasibility of a Fluorescent X-ray Source for in Vivo X-ray Fluorescence Measurements of Kidney and Liver Cadmium | p. 255 |
Total Body Capacitance Correlates with Total Body Potassium | p. 259 |
In Vivo Measurement of Platinum in the Kidneys Using X-ray Fluorescence | p. 263 |
Perquisite Spin-off from Twenty-Two Years of Measuring Background in the Whole Body Counter Steel Room | p. 267 |
Response Function of the BGO and Nal(T1) Detectors Using Monte Carlo Simulations | p. 271 |
The Assessment of Stature Using an Infrared Technique | p. 276 |
Lead Accumulation in Highly Exposed Smelter Workers | p. 280 |
Bone Hydroxyapatite/Collagen Ratio: In Vivo Measurements by X-ray Absorptiometry | p. 284 |
Plasma Sample Preparation by Ultrafiltration for Total Body Water Determination | p. 287 |
Body Composition Modeling: Application to Exploration of the Resting Energy Expenditure Fat-free Mass Relationship | p. 290 |
Modeling Leg Sections by Bioelectrical Impedance Analysis, Dual-Energy X-ray Absorptiometry, and Anthropometry: Assessing Segmental Muscle Volume Using Magnetic Resonance Imaging as a Reference | p. 298 |
Cellular-Level Body Composition Model: A New Approach to Studying Fat-free Mass Hydration | p. 306 |
Epidemiological Applications of Body Composition: The Effects and Adjustment of Measurement Errors | p. 312 |
Anthropometry in Body Composition: An Overview | p. 317 |
Using Simple Anthropometric Parameters to Develop Formulas for Estimating Weight and Height in Chinese Adults | p. 327 |
The Best Predictive Model for Estimating Fat-free Mass | p. 333 |
A Comparison of Body Composition Techniques | p. 335 |
Skinfolds versus Bioimpedance Analysis for Predicting Fat-free Mass | p. 339 |
The "B" in the Selinger Four-Compartment Body Composition Formula Should Be Body Mineral Instead of Bone Mineral | p. 342 |
Total Body Protein in Chronic Diseases and in Aging | p. 345 |
Changes in Body Fluids during Endurance Rowing Training | p. 353 |
Body Fat Content Influences the Body Composition Response to Nutrition and Exercise | p. 359 |
Total Body Potassium in Healthy Italians and Americans: A Cross-Calibration Study | p. 366 |
Effects of Exercise and Dietary Fat upon Body Composition: A Study in a Rat Model | p. 369 |
Analysis of Variance/Covariance of Effect of Working Posture on Body Composition | p. 372 |
The Reference Child and Adolescent Models of Body Composition: A Contemporary Comparison | p. 374 |
Body Composition Measurements during Infancy | p. 383 |
Factors Influencing Body Composition of Premature Infants at Term-Adjusted Age | p. 393 |
Value of Total Body Potassium in Assessing the Nutritional Status of Children with End-Stage Liver Disease | p. 400 |
A Prospective Study of Body Composition Changes in Children with Cystic Fibrosis | p. 406 |
Body Composition Changes during Tanner Stage 5 | p. 410 |
Blood Pressure, Blood Insulin, and Anthropometry in Obese Children: A Preliminary Report | p. 416 |
Change of Body Composition in Adolescents with Anorexia Nervosa: Comparison of Bioelectrical Impedance Analysis and Total Body Potassium | p. 418 |
Annual Changes in Total Body Fat and Fat-free Mass in Children from 8 to 18 Years in Relation to Changes in Body Mass Index: The Fels Longitudinal Study | p. 420 |
Body Composition of Children in a Depressed Economy | p. 424 |
Prediction Models for Bone Mineral Content in School-Aged Children | p. 428 |
Lean Mass of Children in Various Nutritional States: Comparison between Dual-Energy X-ray Absorptiometry and Anthropometry | p. 433 |
Body Composition in Healthy Aging | p. 437 |
Smaller Organ Tissue Mass in the Elderly Fails to Explain Lower Resting Metabolic Rate | p. 449 |
Reexamining the Sarcopenia Hypothesis: Muscle Mass versus Muscle Strength | p. 456 |
Waist Circumference and Sagittal Diameter Reflect Total Body Fat Better Than Visceral Fat in Older Men and Women: The Health, Aging and Body Composition Study | p. 462 |
Body Water Spaces and Cellular Hydration during Healthy Aging | p. 474 |
Body Composition by Air Displacement Plethysmography in Middle-Aged and Elderly Japanese: Comparison with Dual-Energy X-ray Absorptiometry | p. 484 |
Influence of Body Composition on Bone Mineral Content in Elderly Women: A Preliminary Report | p. 489 |
Fat Distribution and Health in Obesity | p. 491 |
Menopause-Related Changes in Body Fat Distribution | p. 502 |
Total Body Calcium in Obese Women: Validation of Dual-Energy X-ray Absorptiometry against in Vivo Neutron Activation Analysis | p. 507 |
Relative Overhydration of Fat-free Mass in Postobese versus Never-Obese Subjects | p. 514 |
Longitudinal Assessment of Intra-abdominal Fat in Postmenopausal Women | p. 520 |
Effect of a Weight-Reduction Program on Total and Regional Body Composition in Obese Postmenopausal Women | p. 526 |
Reproducibility of Body Measurements in Very Obese Postmenopausal Women | p. 536 |
Measurement of Percent Body Fat during Weight Loss in Obese Women: Comparison of Four Methods | p. 539 |
Association between Leptin, Insulin, and Body Fat Distribution in 2-Diabetes Mellitus | p. 542 |
Body Composition Studies in HIV-Infected Individuals | p. 546 |
Sarcopenic Obesity: Does Muscle Loss Cause Fat Gain? Lessons from Rheumatoid Arthritis and Osteoarthritis | p. 553 |
Body Composition Assessed by Neutron Activation Analysis in Dialysis Patients | p. 558 |
Bone Mass and Gastrointestinal Disease | p. 564 |
Early Diagnosis of Lymphedema in Postsurgery Breast Cancer Patients | p. 571 |
Effect of Recombinant Human Growth Hormone on Regional Tissue Distribution in Growth Hormone-Deficient Males | p. 576 |
The Prognostic Value of Body Protein in Patients with Lung Cancer | p. 584 |
Similarity of Changes in Body Composition in Intensive Care Patients following Severe Sepsis or Major Blunt Injury | p. 592 |
Positive Impact of Protease Inhibitors on Body Composition and Energy Expenditure in HIV-Infected and AIDS Patients | p. 603 |
Effects of Whey Protein and Resistance Exercise on Body Composition and Muscle Strength in Women with HIV Infection | p. 607 |
The Usefulness of Walking for Preventing Sarcopenia in Dieting Postmenopausal Women Complaining of Knee Pain | p. 610 |
Longitudinal Study of Patients with Anorexia Nervosa 6 to 10 Years after Treatment: Impact of Adequate Weight Restoration on Outcome | p. 614 |
Changes in Body Composition and Resting Energy Expenditure in Anorectic Patients after a Weight Gain of Fifteen Percent | p. 617 |
Body Composition in Homozygous [beta]-Thalassemia | p. 621 |
Bone Density and Body Composition in Young Women with Chronic Fatigue Syndrome | p. 625 |
In Vivo Body Composition Studies of Young Adult Males Participating in the Cleanup of the Chernobyl Nucler Power Plant | p. 628 |
Relevance of, and Potentiality for, in Vivo Intrathyroidal Iodine Determination | p. 630 |
Index of Contributors | p. 633 |
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