Category Archives: LECTURE NOTES

LECTURE NOTES ON HUMAN ANATOMY & PHYSIOLOGY

Presentation of course, cell physiology

Nerve cell and the central nervous system structure and function

Somatosensor senses,

Spinal cord and peripheral nervous system

Visual, gustatory, olfactory sensory

Hearing, sense of balance and movement control

Bone and muscle

Sleep

Higher brain functions, consciousness, unconsciousness

Clinical neurophysiologic measurements

Cardiac electrical properties

Mechanical properties of the heart, heart studies

Circulatory system and its regulation

Capillary and lymphatic circulation

Respiratory physiology

Digestive activity of the body A structure

Digestive activity of the body B: Anatomy

Renal function

The body’s defense mechanisms, blood clotting

Thermoregulation

The body’s hormonal regulation

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BIOMEDICAL ENGINEERING TOPICS

Introduction to Biomedical Engineering
Origin of Biopotentials
Circuits, Systems & Signals
Signals and Filters
Hudgkin-HuxleyModel
H&H Model (cont.)
Biopotential Electrodes
Electrocardiography ECG Lab
Drug Delivery (Dr. Farrell)
Cardiovascular Dynamics
Hemodynamics
Measuring Blood Pressure
Biopotential Amplifiers
Blood Flow Meas.
Blood Volume Measurement
Clinical Systems
Pulmonary System I
Pulmonary System II
Pulmonary Measurements
DSP (Full lecture)
Pulmonary Lab Electrical Safety

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IMAGE PROCESSING LECTURE NOTES

Introduction

Lecture 1. Imaging devices

Lecture 2. Elements of the theory of 2D signal processing

Lecture 3. Signal transformations and mathematical models of imaging systems

Lecture 4. Principles of signal digitization. Signal sampling

Lecture 5. Image quantization

Lecture 6. Principles of image coding

Lecture 7. Digital representation of signal transformations

Properties of DFT

Lecture 8. Orthogonal Transforms in Digital Image Processing

Lecture 9. Statistical Image and Noise Models

Lecture 10. Principles of Image Restoration

Lecture 11. Image enhancement

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LECTURE NOTES EXPLANATION OF ALL IMAGING MODALITY

Lecture 1: Principles of X-ray imaging (940 kB)

Lecture 2 : Technology and applications for planar X-ray imaging (1.2 MB)

Lecture 3 : Principles of X-ray Computed Tomography (660 kB)

Lecture 4 : X-ray CT applications (1 MB)

Lecture 5 : Nuclear Medicine (356 kB)

Lecture 6 : Emission Tomographies (1.5 MB)

Lecture 7 : Principles of Ultrasound imaging (576 kB)

Lecture 8 : Applications of Ultrasound imaging (884 kB)

Lecture 9 : Nuclear Magnetic Resonance (776 kB)

Lecture 10 : Magnetic Resonance Imaging (1.8 MB)

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UNIVERSITY LECTURE NOTES ON BIOMEDICAL IMAGE PROCESSING & BIOMEDICAL SIGNAL PROCESSING

Lecture 1. Signals and mathematical models

Lecture 2 Digital representation of signals

Lecture 3 Signal discretization by sampling

Lecture 4 Element-wise quantization

Lecture 5 Principles of signal and image coding

Lecture 6 Signal transformations and their discrete representation. Digital filters

Lecture 7 Discrete representations of Fourier Transform

Lecture 8 Applications of DFT and SDFTs

Lecture 9 Principles of signal parameter estimation

Lecture 10 Signal reconstruction and enhancement: linear filters

Lecture 11Signal/image restoration: nonlinear filters

Lecture 12 Correlational averaging as a method for signal restoration

Lecture 13 Ultrasound image processing for quantitative analysis of fetal movement
Test signals and images for exercises

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UNIVERSITY EXAMS TOPIC WISE NOTES ON BIOMATERIALS

Biomaterials: General

Biomaterials: Implant Response

Biomaterials: Metals

Biomaterials: Ceramics

Biomaterials: Polymers

Regenerative Medicine: Cell and Gene Therapy

Regenerative Medicine: Tissue Engineering

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