Medical Physics

"MATHEMATICAL BASES - The physical laws and the relationships between physical quantities for solving numerical problems: units of measurement, dimensions and orders of magnitude.
- Scalar quantities, vector quantities and introduction to trigonometry.

MECHANICS
- The hourly laws of uniform and uniformly accelerated motion.
- The periodic motions and the quantities that characterize them.
- Concept of force and the principle of inertia.
- The concept of mass and the second principle of dynamics.
- Interaction between bodies, forces and the third principle of dynamics
- Types of forces: gravitational force, weight force, elastic force, contact forces, friction forces, tension force. Notes on muscle force.
- Moment of a force, levers and conditions of balance. Applications to the human body.
- Elasticity and deformations.
- The work of a force: meaning of kinetic energy and of the kinetic energy theorem.
- Force field: when it is conservative and definition of potential energy.
- Principle of conservation of mechanical energy and examples of application.
- Conservation of energy in walking, running and jumping.
- Collisions between bodies

STATIC AND DYNAMIC OF FLUIDS
- The characteristics of fluids. The concept of pressure in a fluid.
- Principles of hydrostatics: Pascal, Stevin and Archimedes principles.
- Surface phenomena: cohesion forces, surface tension and adhesion forces.
- The motion of a liquid: stationary motion and considerations on the flow rate and speed of the liquid.
- Bernoulli's theorem: hypothesis and meaning of the conservation of mechanical energy for liquids.
- Pressure trend in the presence of reduction or increase in the section of the duct and examples of stenosis and aneurysm.
- Effect of the presence of internal friction in real liquids: viscosity, Hagen-Poiseuille law and turbulent flow. Example of blood circulation.

TRANSPORT PHENOMENA
- Viscous transport: sedimentation, electrophoresis and centrifugation
- Free diffusion and diffusion through a membrane due to concentration gradients.
- Filtration and osmosis.

THERMODYNAMICS
- Thermal expansion in solids, liquids and gases.
- Equation of state of the ideal gas.
- The concept of quantity of heat and calorie.
- The thermal capacity of a body, the specific heat of a substance and the latent heat of fusion and evaporation.
- The mechanisms of heat transport.
- I and II principle of thermodynamics: internal energy and entropy.
- Thermodynamic potentials: enthalpy and free energy.

WAVE PHENOMENA
- Propagation of a wave. Interference, diffraction and the Huygens principle.
- Non-sinusoidal waves and Fourier analysis.
- Doppler effect.
- Propagation of sound waves. Sound intensity and sound perception.

ELECTRIC PHENOMENA
- Coulomb's law.
- The electric field: intensity, direction and representation through the force lines.
- Electric potential.
- Dielectric and conductive materials.
- Induction phenomena and capacitance of a capacitor.
- Electric current, electric resistance, Ohm's law and resistive circuits.
- Joule's law to calculate the power dissipated by a resistance.
- RC circuit response and elementary frequency filtering schemes.

MAGNETIC PHENOMENA
- Natural magnets and magnetic forces.
- Magnetic field generated by electrical current.
- Lorentz force.
- Magnetic induction, transients in alternating current circuits and circuits.

OPTICAL
- Phenomenological relationships between electric and magnetic fields.
- Propagation of electromagnetic waves and ways of interacting with matter.
- Geometric optics.
- Index of refraction, laws of reflection, refraction and diffraction of light.
- Image formation in thin lens systems.
- Optical defects of the eye corrective lenses.
- Optical aberrations.

IONIZING RADIATIONS
- X-ray characteristics and their generation.
- The interactions between X radiation and matter and the formation of the image on a radiographic plate.
- Radioactivity: isotopes, types of radiation, law of radioactive decay, measures of radioactivity and effects on biological systems."

"Description of the diagnostic moment, analyzing the presence diagnosis, the diagnosis of nature, the staging and the follow up. Digital diagnostic images: matrix, spatial resolution, contrast resolution, archive and distribution.
Processing of digital images.
Mechanical waves and ultrasound image formation.
Doppler phenomenon.
Ultrasound contrast media and harmonic imaging.
Computerized tomography: technological evolution of the equipment, reconstruction through sinograms and back projection. Hounsfield unit and window concept.
Magnetic Resonance: signal genesis, relaxation time T1 and T2, spatial coding
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