Tag Archives: LECTURE NOTES

IMAGE PROCESSING LECTURE NOTES

Introduction

Lecture 1. Imaging devices

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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 LECTURE NOTES ON TOPICS OF BIOMATERIALS (CONTINUED………….)

  • Lecture 1: Molecular Design and Synthesis of Biomaterials I: Biodegradable Solid Polymeric Materials (PDF – 1.6 MB) Polyanhydride Deg Rates (XLS)
  • Lecture 2: Molecular Design and Synthesis of Biomaterials I: Biodegradable Materials (PDF)
  • Molecular Design and Synthesis of Biomaterials I: Biodegradable Solid Polymeric Materials (continued) (PDF)
  • Lecture 3: Degradable Materials with Biological Recognition (PDF – 1.5 MB)
  • Lecture 4: Degradable Materials with Biological Recognition (part II) (PDF)
  • Lecture 5: Controlled Release Devices (PDF)
  • Lecture 6: Programmed / Pulsed Drug Delivery and Drug Delivery in Tissue Engineering (PDF – 1.3 MB)

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POWERPOINT LECTURE NOTES ON BIOMEMS

BioMEMS – Class 0 – CMEMS

BioMEMS – Class 1 – Intro

BioMEMS – Class 2 – Electrochemistry I

BioMEMS – Class 3 – Electrochemistry II

BioMEMS – Class 4 – Optics

BioMEMS – Class 5 – Ion Selective Electrodes

BioMEMS – Class 6 – PCR

BioMEMS – Class 7 – DNA Arrays

BioMEMS – Class 8 – Microfluidics Compared

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UNIVERSITY LECTURE NOTES ON ALL THE TOPICS OF BIOMATERIALS

Overview

Classes of Materials Used in Medicine

Polymeric Materials – Part I

Polymeric Materials – Part II

Acute Wound Healing

Blood Clotting

Chronic Wound Healing and Foreign Body Response

Surface Properties of Biomaterials

Surface Characterization

Surface & Protein Interactions

Inflammation: Part I

Inflammation: Part II-Degradation of Implanted Materials

Device Regulation

Device Development

Biomaterials and Related Infections

Prevention and Sterilization

Surface Coatings

Anti-Infective Coatings

Wound Dressings and Sutures

Elastomers

Applications in Cardiology

Hollow Fiber Membranes

Applications in Nephrology

Hydrogels

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