Principles of Radiographic Imaging 2

Analyze image quality; utilize procedures for minimizing patient exposure; and adapt technical variables to changing conditions.

At the completion of this course, the student will be able to demonstrate understanding of the following material:

1. Factors affecting x-ray beam quality and quantity and their relationships.
2. Differences in the production of the various x-ray interactions with matter.            
3. The relationship between differential absorption and mass density.
4. Factors that affect the production of scatter radiation.
5. The function of grids as it relates to scatter radiation.
6. The components associated with the production of the latent image.
7. Construction and characteristics digital imaging receptors.
8. Individual parts digital image reader.
9. Factors affecting geometric quality on the image.

MINIMUM PERFORMANCE/LEARNING OBJECTIVES

SCANS OBJECTIVES: C 5-7, 15-20   F 4, 8-13, 17

Following the completion of the required material in this course of study, the student will be able to:

1. Discuss, draw and/or label the construction, characteristics, appropriate use, radiographic quality effects, storage, handling and care, and patient dosage regarding:
   1. Radiographic CR/digital imaging plates/devices
   2.  Beam restricting devices
   3.  Grids
   4.  Filters
   5. Generator types
2. Describe how each of the items listed in number 1 above can effect contrast resolution, gray scale (contrast), brightness (density), spatial resolution, (recorded detail), and patient dosage.
3. Manipulate and calculate mA, time, kVp, mAs, distance, generator factor, focal spot and filtration and explain how and why each relates to radiographic contrast, density and recorded detail.
4. Apply conversion factors for changes in the following areas: distance, grid, image receptors, reciprocity law and the 15 percent rule.
5. Compare and construct fixed kVp, variable kVp and high kVp technique charts.
6. Explain how automatic exposure control the exposure time and how these times are related to patient factors and positioning.

Cognitive Performance Objectives: Students will demonstrate their understanding of the material presented in lecture by successfully* performing the following tasks on section examinations:

A.  Identify the factors related to beam formation.

(C - I A,B,D, II B,C,D,F; F - 3A,B, 4A)

1. Describe the electromagnetic spectrum.
2. Explain the relationship of energy, wavelength and frequency.
3. Identify the properties of x-rays.
4. Describe radioactivity and radioactive decay in terms of alpha, beta and gamma emission.
5. Compare the production of bremsstrahlung and characteristic radiations.
6. Describe the conditions necessary to produce x-radiation.
7. Compare generators in terms of radiation produced and efficiency.
8. Describe the components and function of diagnostic x-ray tubes.
9. Explain methods used to extend x-ray tube life.

B.  Evaluate the factors affecting x-ray beam quality and quantity and discuss their relationships.

(C - IA, B, C, D; II B, C, D, E, F; F - 3A, B, 4A)

1. 1. Graphically demonstrate the relationships between mA, time, kVp, distance, and exposure by placing either an "up" or "down" arrow next to a word equation.
   2. Interpret into words what specific formulas are expressing.
   3. Explain how beam filtration affects x-ray beam intensity, beam quality and patient exposure.
   4. Describe the change in the half-value layer (HVL) when filtration is added or removed.
   5. Apply the reciprocity law to clinical situations.

C.   Discuss the differences in the production of the various x-ray interactions with matter.

(C - I A,B,D, II B,C,D,F; F - 3A,B, 4A)

1. Explain the processes of ionization and excitation.
2. Discuss the clinical significance of the photoelectric and modified scattering (Compton) interactions in diagnostic imaging.
3. Discuss various photon interactions with matter.
4. Analyze the relationships of factors that control and affect image exposure as they relate to various tissue types.
5. Illustrate the 5 types of x-ray interactions.

D.  Evaluate the relationship between differential absorption and mass/tissue density.

               (C - IA,B,D, II B,C,D,F; F - 3A,B, 4A)

1. Assess radiographic exposure and contrast on radiographic images and relate it to atomic number and mass density.
2. Identify statements that are not congruent with the principles stated in the lecture.
3. Rank various body tissues and elements according to their properties of differential absorption.
4. State the composition of exit radiation.
5. Explain the processes leading to the formation of various shades of gray on an image.

E.  Describe the factors that affect the production of scatter radiation.

              (C - IA,B,D, II B,C,D,F; F - 3A,B, 4A)

1. Successfully answer multiple choice questions on the production of scatter radiation as it applies to kVp, field size, and patient thickness.
2. Identify devices/items that are used to minimize the production of scatter radiation.
3. Give examples of radiographic procedures of which we use special means of scatter control and explain the purpose of each.
4. Summarize the relationship of factors affecting scattered radiation.

E.  Discuss the function of grids as it relates to scatter radiation.

              (C - IA,B,C,D, II B,C,D,E,F; F - 3A,B, 4A)

1. Identify the different parts of a grid on a diagram and give the function of each part.
2. Calculate grid ratio, grid frequency, altered techniques and GCF from certain knowns.
3. Interpret grid efficiency in terms of grid ratio and frequency.
4. Analyze images and identify common grid errors.
5. Summarize the factors that influence grid cutoff.
6. Evaluate grid artifacts.

F.  Relate the function of digital image production to the formation of the latent image.

              (C - IA,B,C,D, II B,C,D,E,F; F - 3A,B, 4A)

1. Outline the process of CR and DR latent image formation.
2. Define terminology associated with digital imaging systems.
3. Describe the various types of digital receptors (CR/DR).
4. List the steps in all types of digital image formulation.
5. Describe the response of digital detectors to exposure variations.
6. Recognize the relationship between spatial resolution, DQE, and image formation.
7. Define PACS and DICOM and discuss their importance in the imaging department.

G.  Understand the construction and characteristics of radiographic digital imaging receptors.

              (C - IA,B,D, II B,C,D,F; F - 3A,B, 4A)

1. Identify the different layers of image receptors from diagrams and discuss the function of each layer.
2. Illustrate and explain the process for digital image receptor exposure.
3. Graphically demonstrate the relationships of CR/DR latitude, exposure, and spatial resolution by placing either an "up" or "down" arrow next to a word equation.
4. Explain the special requirements for digital imaging receptors to ensure accurate processing.
5. Define terms related to digital imaging receptors and processing.
6. Discuss the relationship between spatial frequency and spatial resolution.

H.  Recognize the qualities related to digital image production.

              (C - I A, B, D; II B,C,D,F; F - 3A,B, 4A)

1. Identify the individual parts of the digital image CR reader.
2. Compare and contrast the processes of CR and DR image processing.
3. Differentiate between ‘direct’ and ‘indirect’ in digital imaging.
4. Analyze and identify digital and analog processing errors and artifacts.
5. Discuss the importance of histogram selection to image quality.
6. Define terms related to digital imaging.
7. Describe modulation transfer function (MTF) as it relates to digital radiography detectors.
8. Compare monitor types (e.g. acquisition, display).
9. Describe the components of the various types of display monitors.

 I.  Discuss the factors affecting geometric quality on the image.

                           (C - I A, B, D, II B,C,D,F;  F - 3A,B, 4A)

1. Describe the factors that affect recorded detail (photographic properties and geometric quality /recognizability).
2. Identify images that are foreshortened or elongated.
3. Calculate penumbra or unsharpness and magnification with given knowns.
4. Give examples of radiographic procedures for which magnification/distortion is desirable.
5. Differentiate between size and shape distortion.
6. Perform calculations to determine image magnification and percent magnification.
7. Summarize the relationship of factors that control and affect distortion.