Part 1 Course Contents
(Covered material that will be included in the exam
are marked in Red color - other parts are not included)
Mechanics 1
Distances and Sizes 1
Forces and Translational Equilibrium 3
Rotational Equilibrium 4
Vector Product 5
Force in the Achilles Tendon 6
Forces on the Hip 7
The Use of a Cane 9
Work 10
Stress and Strain 12
Shear 13
Hydrostatics 13
Buoyancy 14
Compressibility 15
Viscosity 15
Viscous Flow in a Tube 15
(only laminar flow phenomenon)
Pressure-Volume Work 18
The Human Circulatory System 19
Turbulent Flow and the Reynolds Number 21
Exponential Growth and Decay 31
Exponential Growth 31
Exponential Decay 33
Semilog Paper 34
Variable Rates 35
Clearance 36
Multiple Decay Paths 37
Decay Plus Input at a Constant Rate 38
Decay with Multiple Half-Lives and Fitting Exponentials 38
The Logistic Equation 39
Log-log Plots, Power Laws, and Scaling 39
Log-log Plots and Power Laws 39
Food Consumption, Basal Metabolic Rate, and Scaling 40
Systems of Many Particles 49
Gas Molecules in a Box 50
Microstates and Macrostates 51
The Energy of a System: The First Law of Thermodynamics 53
Ensembles and the Basic Postulates 54
Thermal Equilibrium 56
Entropy 58
The Boltzmann Factor 58
The Nernst Equation 59
The Pressure Variation in the Atmosphere 60
Equipartition of Energy and Brownian Motion 60
Heat Capacity 61
Equilibrium When Particles Can Be Exchanged: The Chemical Potential 61
Concentration Dependence of the Chemical Potential 62
Systems That Can Exchange Volume 63
Extensive Variables and Generalized Forces 64
The General Thermodynamic Relationship 64
The Gibbs Free Energy 65
Gibbs Free Energy 65
An Example: Chemical Reactions 66
The Chemical Potential of a Solution 67
Transformation of Randomness to Order 69
Transport in an Infinite Medium 81
Flux, Fluence, and Continuity 81
Definitions 81
The Continuity Equation in One Dimension 82
The Continuity Equation in Three Dimensions 82
The Integral Form of the Continuity Equation 83
The Differential Form of the Continuity Equation 84
The Continuity Equation with a Chemical Reaction 85
Drift or Solvent Drag 85
Brownian Motion 85
Motion in a Gas: Mean Free Path and Collision Time 85
Motion in a Liquid 86
Diffusion: Fick's First Law 87
The Einstein Relationship Between Diffusion and Viscosity 89
Fick's Second Law of Diffusion 91
Time-Independent Solutions 92
Example: Steady-State Diffusion to a Spherical Cell and End Effects 94
Diffusion Through a Collection of Pores, Corrected 95
Diffusion from a Sphere, Corrected 95
How Many Pores Are Needed? 96
Other Applications of the Model 96
Example: A Spherical Cell Producing a Substance 96
Drift and Diffusion in One Dimension 98
A General Solution for the Particle Concentration as a Function of Time 99
Diffusion as a Random Walk 100
Transport Through Neutral Membranes 111
Membranes 111
Osmotic Pressure in an Ideal Gas 112
Osmotic Pressure in a Liquid 114
Some Clinical Examples 115
Edema Due to Heart Failure 116
Nephrotic Syndrome, Liver Disease, and Ascites 116
Edema of Inflammatory Reaction 116
Headaches in Renal Dialysis 116
Osmotic Diuresis 116
Osmotic Fragility of Red Cells 117
Volume Transport Through a Membrane 117
Solute Transport Through a Membrane 119
Example: The Artificial Kidney 120
Countercurrent Transport 121
A Continuum Model for Volume and Solute Transport in a Pore 122
Volume Transport 123
Solute Transport 124
Summary 127
Reflection Coefficient 127
The Effect of Pore Walls on Diffusion 128
Net Force on the Membrane 128
Atoms and Light 359
The Nature of Light: Waves versus Photons 359
Atomic Energy Levels and Atomic Spectra 361
Molecular Energy Levels 362
Scattering and Absorption of Radiation; Cross Section 364
The Diffusion Approximation to Photon Transport 367
General Theory 367
Continuous Measurements 368
Pulsed Measurements 368
Refinements to the Model 369
Biological Applications of Infrared Scattering 369
Near Infrared (NIR) 369
Optical Coherence Tomography (OCT) 370
Raman Spectroscopy 371
Far Infrared or Terahertz Radiation 372
Thermal Radiation 372
Infrared Radiation from the Body 375
Atherosclerotic Coronary Heart Disease 376
Blue and Ultraviolet Radiation 377
Treatment of Neonatal Jaundice 377
The Ultraviolet Spectrum 377
Response of the Skin to Ultraviolet Light 378
Ultraviolet Light Causes Skin Cancer 380
Protection from Ultraviolet Light 380
Ultraviolet Light Damages the Eye 381
Ultraviolet Light Synthesizes Vitamin D 381
Ultraviolet Light Therapy 381
Heating Tissue with Light 381
Radiometry and Photometry 383
Radiometric Definitions 383
Photometric Definitions 387
Actinometric Definitions 388
The Eye 388
Quantum Effects in Dark-Adapted Vision 390
Symbols Used 392
Problems 393
References 397
Interaction of Photons and Charged Particles with Matter 401
Atomic Energy Levels and X-ray Absorption 401
Photon Interactions 403
Photoelectric Effect 403
Compton and Incoherent Scattering 403
Coherent Scattering 403
Inelastic Scattering 403
Pair Production 403
Energy Dependence 404
The Photoelectric Effect 404
Compton Scattering 405
Kinematics 405
Cross Section: Klein-Nishina Formula 406
Incoherent Scattering 406
Energy Transferred to the Electron 407
Coherent Scattering 407
Pair Production 407
The Photon Attenuation Coefficient 408
Compounds and Mixtures 410
Deexcitation of Atoms 410
Energy Transfer from Photons to Electrons 412
Charged-Particle Stopping Power 414
Interaction with Target Electrons 418
Scattering from the Nucleus 421
Stopping of Electrons 422
Compounds 422
Linear Energy Transfer and Restricted Collision Stopping Power 422
Range, Straggling, and Radiation Yield 423
Track Structure 424
Energy Transferred and Energy Imparted; Kerma and Absorbed Dose 425
An Example 425
Energy Transferred and Kerma 427
Energy Imparted and Absorbed Dose 427
Net Energy Transferred, Collision Kerma, and Radiative Kerma 428
Charged-Particle Equilibrium 428
Radiation Equilibrium 428
Charged-particle Equilibrium 428
Buildup 429
Symbols Used 430
Problems 431
References 434
Medical Use of X Rays 437
Production of X Rays 437
Characteristic X Rays 437
Bremsstrahlung 438
Quantities to Describe Radiation Interactions 439
Radiation Chemical Yield 439
Mean Energy per Ion Pair 439
Exposure 440
Detectors 440
Film and Screens 440
Scintillation Detectors 442
Gas Detectors 444
Semiconductor Detectors 445
Thermoluminescent Dosimeters 445
Chemical Dosimetry 445
Digital Detectors 446
The Diagnostic Radiograph 446
X-ray Tube and Filter 446
Collimation 447
Attenuation in the Patient: Contrast Material 447
Antiscatter Grid 450
Film-Screen Combination 450
Computed and Direct Radiography 450
Image Quality 450
Angiography and Digital Subtraction Angiography 453
Mammography 453
Fluoroscopy 454
Computed Tomography 454
Biological Effects of Radiation 457
Cell-Culture Experiments 458
Chromosome Damage 458
The Linear-quadratic Model 460
The Bystander Effect 460
Tissue Irradiation 461
A Model for Tumor Eradication 463
Radiation Therapy 463
Classical Radiation Therapy 464
Modern X-ray Therapy 465
Charged Particles and Neutrons 465
Dose Measurement 467
The Risk of Radiation 468
Equivalent and Effective Dose 468
Comparison with Natural Background 469
Calculating Risk 470
Radon 472
Symbols Used 473
Problems 474
References 477
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