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Marriage and Family Therapy |
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MFT 599 - Internship
(F,W,S)
Credit Hours: 8
Supervised practical experience across 3 terms for a total of 700 hours in preparation for supervised practice, 280 of direct client contact and the remaining hours in supervisory and training activities and administrative duties related to the profession. Prerequisite: Approval of internship coordinator.
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Respiratory Care Program |
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RCP 100 - Matriculation
(F)
Lecture Hours: 2
Lab Hours: 0
Credit Hours: 2
A study into the evidence-based and political pressures driving new developments in respiratory care. Considerations and planning for the students emerging role in health care. Online version tailored to degree completion students.
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RCP 107 - Seminar
Credit Hours: (Hours to be arranged each term.)
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RCP 120 - Interventions in Gas Exchange
(F,W,S)
Lecture Hours: 4
Lab Hours: 0
Credit Hours: 4
An introduction to the effects of ineffective breathing on carbon dioxide removal and oxygen delivery. Basic pulmonary mechanics are described. The vascular effects of hypoxemia are fully explored. Oxygen therapy and Continuous Positive Airway Pressure are introduced.
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RCP 207 - Seminar
Credit Hours: (Hours to be arranged each term.)
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RCP 221 - Introduction to Patient Assessment
(S)
Lecture Hours: 0
Lab Hours: 3
Credit Hours: 1
Acquisition and interpretation of the patient history, physical examination, auscultation, vital signs, laboratory data including arterial blood gases and dysrhythmia recognition. Collaborative activities include the acquisition, analysis and communication of findings.
Prerequisite: RCP 236
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RCP 223 - Emergent Chest Radiographic Interpretation
(S)
Lecture Hours: 2
Lab Hours: 0
Credit Hours: 2
The evaluation of the chest radiograph in the intensive care setting. Students learn to identify structures and fissures as well as the significance of silhouette sign, blunted costophrenic angles, air bronchograms and hyperlucency. The identification of pneumothorax, infiltrates, and the correct placement of tubes is required.
Prerequisite: RCP 236
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RCP 231 - Pulmonary Physiology
(F)
Lecture Hours: 3
Lab Hours: 3
Credit Hours: 4
Pulmonary physiology including mechanics of ventilation, gas diffusion, acid-base regulation, oxygenation, and the physiologic advantage of structure. Gas laws and surface tension as applied to the understanding of clinical problems.
Prerequisite: BIO 233
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RCP 235 - Arterial Blood Gases
(F)
Lecture Hours: 3
Lab Hours: 0
Credit Hours: 3
Chemistry and classification of acid-base balance including determination of compensation and pathophysiologic causes. Assessment of partial pressures of oxygen, saturation and total oxygen delivery.
Prerequisite: Admission to the Respiratory Care program or instructor consent
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RCP 236 - Cardiopulmonary Dynamics
(W)
Lecture Hours: 2
Lab Hours: 3
Credit Hours: 3
Exploration of pulmonary mechanics as measured by spirometry. Cardiovascular hemodynamics including cardiac electrophysiology, rhythm recognition and the measurement and interpretation of Systemic Vascular Resistance and Pulmonary Vascular Resistance, Central Venous Pressures, Pulmonary Artery and Pulmonary Capillary Wedge Pressures.
Prerequisite: Admission to the Respiratory Care program or instructor consent
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RCP 241 - Respiratory Gas Therapeutics
(W)
Lecture Hours: 3
Lab Hours: 3
Credit Hours: 4
Physical and chemical applications of medical gases and humidity therapy to patient care. The transportation, regulation and dissemination of compressed gases. Clinical decision making strategies for Oxygen titration.
Prerequisite: Admission to the Respiratory Care program
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RCP 252 - Cardiopulmonary Pharmacology
(S)
Lecture Hours: 4
Lab Hours: 0
Credit Hours: 4
A study of the administration, pharmacokinetics, administration and actions of medications. Emphasis is placed on bronchodilators, steroids, mucolytics and antileukotriene agents. Vasoactive, antiarrhythmics, diuretics, sedatives, antimicrobials and neuromuscular blocking agents are introduced.
Prerequisite: CHE 360
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RCP 307 - Seminar
Credit Hours: (Hours to be arranged each term.)
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RCP 326 - Disaster Preparedness
(F,W,S)
Lecture Hours: 2
Lab Hours: 0
Credit Hours: 2
Preparation for unusual biological disasters. Case-based study of Ebola, anthrax, SARS, influenza, bird flu, tuberculosis, emergency room violence and unrest, evacuation and loss of services caused by earthquakes, hurricanes, floods and fire.
Prerequisite: RCP 235
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RCP 335 - Exercise Physiology and Education
(F)
Lecture Hours: 2
Lab Hours: 0
Credit Hours: 2
Introduction to the physiology of exercise, exercise in disease and health and stress testing. Concepts of age appropriate pulmonary rehabilitation and asthma education are described.
Prerequisite: RCP 235
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RCP 336 - Hyperinflation Therapies
(F,S)
Lecture Hours: 1
Lab Hours: 3
Credit Hours: 2
Study and evidence-based application of PEEP, CPAP, bi-level ventilation, IPPB, and incentive spirometry. Flutter valve, PEP, high frequency chest wall oscillation and other methods of improving bronchial hygiene and lung volume.
Prerequisite: RCP 241
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RCP 337 - Pulmonary Pathology
(F)
Lecture Hours: 4
Lab Hours: 0
Credit Hours: 4
Case-based approach to the understanding, evaluation and treatment of pulmonary disease. Recognition of obstructive and restrictive disease patterns as well as the classification of acid-base and oxygenation disorders. Classification, application and pharmacodynamics of common pulmonary medications are discussed.
Prerequisite: RCP 235
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RCP 345 - Cardiopulmonary Diagnosis and Monitoring
(W)
Lecture Hours: 2
Lab Hours: 3
Credit Hours: 3
Collaborative investigation, practice, calibration and interpretation of spirometry, body plethysmography, diffusion capacity, helium dilution, seven minute nitrogen washout, cardiopulmonary stress testing, 12 lead ECG acquisition, dysrhythmia recognition, arterial blood gas instrumentation.
Prerequisite: RCP 337
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RCP 350 - Introduction to Clinical
(S)
Lecture Hours: 1
Lab Hours: 24
Credit Hours: 9
Orientation to clinical practice in hospitals. Requires successful criminal background check, drug screening, completion of training in computer charting and compliance with Health Insurance Portability and Accounting Act (HIPAA). Competence developed in the area of basic patient assessment, oxygen therapy, aerosol therapy and mechanical ventilation.
Prerequisite: RCP 241
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RCP 351 - Mechanical Ventilation I
(F)
Lecture Hours: 3
Lab Hours: 3
Credit Hours: 4
Study of an array of artificial airways. Includes laboratory practice in intubation, endotracheal suctioning and bag-mask-valve ventilation. Study and practice of mechanical ventilation circuits, classes of mechanical ventilators and modes.
Prerequisite: RCP 235
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RCP 352 - Mechanical Ventilation II
(W,S)
Lecture Hours: 3
Lab Hours: 3
Credit Hours: 4
Description and analysis of the adult patient mechanical ventilator system including the initiation, assessment, management and discontinuance.
Prerequisite: RCP 351
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RCP 353 - Mechanical Ventilation III
(S)
Lecture Hours: 3
Lab Hours: 3
Credit Hours: 4
Advanced topics in mechanical ventilation including transport, dual modes, neonatal and pediatric mechanical ventilation.
Prerequisite: RCP 352
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RCP 366 - Clinical Simulation
(S)
Lecture Hours: 3
Lab Hours: 0
Credit Hours: 3
The practice and measurement of critical thinking in the context of computer branching logic simulations. Students use organized sequential topical examinations to review and measure retention of respiratory care content. Passage of secure national review examination required.
Prerequisite: RCP 337
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RCP 386 - Critical Care I
(S)
Lecture Hours: 4
Lab Hours: 0
Credit Hours: 4
Analysis and application of critical care techniques with an emphasis in cardiovascular management and assessment. Cardiovascular catheters and hemodynamics, advanced rhythm recognition, and the essentials of advanced cardiac life support.
Prerequisite: RCP 337
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RCP 387 - Critical Care II
(F,W)
Lecture Hours: 2
Lab Hours: 0
Credit Hours: 2
Advanced techniques during intubation. Assessment of the difficult airway including Mallampatti classification and thyromental distance. Continued practice and an extension of hemodynamic, pharmacology and imaging knowledge. Students practice anticipating care based on nutritional status.
Prerequisite: RCP 241
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RCP 388 - Advanced Neonatal Respiratory Care
(F)
Lecture Hours: 3
Lab Hours: 3
Credit Hours: 4
Survey of perinatal physiology with an emphasis on mechanical ventilation, the application of oxygen, medications, positive pressure, resuscitative efforts and evaluations as applied to the neonatal and pediatric patients. Instruction in neonatal resuscitation meets the standards established by the American Academy of Pediatrics.
Prerequisite: RCP 241
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RCP 389 - International Neonatology
Lecture Hours: 3
Lab Hours: 3
Credit Hours: 4
Advanced topics in neonatal and pediatric respiratory care including transport, stabilization and care in resource limited international settings.
Prerequisite: RCP 241
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RCP 407 - Seminar
Credit Hours: (Hours to be arranged each term.)
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RCP 440 - Case Management I
(F,W,S)
Lecture Hours: 3
Lab Hours: 0
Credit Hours: 3
Current clinical cases used as the basis for scholarly research and discussion. Students design a research-based senior project in the field of respiratory care, including interviews, research, literature review and formal presentation.
Prerequisite: Completion of all academic coursework in the Respiratory Care Program prior to the Senior year
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RCP 441 - Case Management II
(F,W,S)
Lecture Hours: 3
Lab Hours: 0
Credit Hours: 3
Current clinical cases used as the basis for scholarly research and discussion. Students continue work on senior project in the field of respiratory care, including interviews, research, literature review and formal presentation.
Prerequisite: RCP 440
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RCP 442 - Case Management III
(F,W,S)
Lecture Hours: 3
Lab Hours: 0
Credit Hours: 3
Current clinical cases used as the basis for scholarly research and discussion. Students complete work on senior project in the fields of respiratory care, including formal presentation of the project.
Prerequisite: RCP 441
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RCP 450 - Clinical Care I
(Su)
Lecture Hours: 1
Lab Hours: 24
Credit Hours: 9
Continued development of respiratory care skills, mechanical ventilation and neonatal intensive care, expanded functions and observations in specialty areas.
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RCP 451 - Clinical Care II
(F,W)
Lecture Hours: 1
Lab Hours: 24
Credit Hours: 9
Continued development of respiratory care skills, mechanical ventilation and neonatal intensive care, expanded functions and observations in specialty areas.
Prerequisite: RCP 450
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RCP 452 - Clinical Care III
(W)
Lecture Hours: 0
Lab Hours: 36
Credit Hours: 12
Continued development of respiratory care skills, mechanical ventilation and neonatal intensive care, expanded functions and observations in specialty areas.
Prerequisite: RCP 451
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RCP 460 - Advanced Life Support
(S)
Lecture Hours: 0
Lab Hours: 6
Credit Hours: 2
Students become certified or re-certified in professional life support classes such as Basic Life Support, Advanced Cardiac Life Support, Neonatal Life Support, Pediatric Life Support. Clinical simulations and other credentialing exam preparation included.
Prerequisite: RCP 252
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RCP 486 - Extreme Physiology
(F,W)
Lecture Hours: 2
Lab Hours: 0
Credit Hours: 2
Physiologic adaptations to gas exchange and transport which occurs during the challenges of neonatal transition, exercise, high altitude and high-pressure environments.
Prerequisites: RRT credential and admission to the degree completion program
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RCP 487 - Expert Mechanical Ventilation
(F,W,S)
Lecture Hours: 2
Lab Hours: 0
Credit Hours: 2
Recognition of levels of quality in mechanical ventilation. Practicing clinicians balance experience with current evidence-based recommendations for mechanical ventilation in order to develop a hierarchy of quality care. Includes selection of new modes, patient-ventilator synchrony, the reduction of medical errors and ventilator associated pneumonia.
Prerequisites: RRT credential and admission to the degree completion program
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RCP 488 - Respiratory Care Innovations
(F,S)
Lecture Hours: 2
Lab Hours: 0
Credit Hours: 2
Exploration of new opportunities to improve access to respiratory care. Reduction of disease through the expansion of respiratory care. Student projects focused on networking among students and faculty and across institutional, professional and nonprofit lines to implement improvements in health and education.
Prerequisites: RRT credential and admission to the degree completion program
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RCP 561 - Individual Development Plan
Lecture Hours: 3
Lab Hours: 0
Credit Hours: 3
Collaboration, negotiation and the development of priorities for program planning. Systematic planning required for the development and documentation of four professional competencies.
Prerequisites: State license, current respiratory care employment and the National Board for Respiratory Care (RRT) credential
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RCP 565 - Clinical Preceptorship
Lecture Hours: 3
Lab Hours: 0
Credit Hours: 3
Clinical practice beyond that of an advanced graduate as described in the OIT approved IDP. Areas for development of advanced clinical practice include the intensive care units, pulmonary rehabilitation, research, home care, education and management. Course completion is required for the fulfillment of the IDP.
Prerequisite: RCP 561
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RCP 575 - Accreditation Practicum
Lecture Hours: 3
Lab Hours: 0
Credit Hours: 3
Respiratory Care leaders are proactive in the validation of their programs through accreditation. This practicum provides the emerging leader with a practical familiarity with program data collection and the assessment of that data in comparison to accreditation standards. Methods of improving the outcomes of individual programs are studied. Course completion requires fulfillment of IDP.
Prerequisite: RCP 561
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Radiologic Science |
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RDSC 105 - Radiation Protection and Radiographic Quality Control
(S)
Lecture Hours: 3
Lab Hours: 0
Credit Hours: 3
Principles of radiation protection and radiographic quality control for veterinary x-ray operators in accordance with Oregon Administrative Rules. Students majoring in Radiologic Science are not eligible.
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RDSC 107 - Seminar
Credit Hours: (Hours to be arranged each term.)
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RDSC 201 - Imaging Techniques I
(F)
Lecture Hours: 3
Lab Hours: 3
Credit Hours: 4
Demonstration and practice with the phenomena and causes of image formation and visualization. The context includes studies of effects of technique-factor changes, effects of the use of various accessories and effects of chemicals in film processing. Causes of radiographic artifacts are discussed and explored. Includes the study of interactions of radiation and matter.
Prerequisite: MIT 103 with grade “C” or better
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RDSC 202 - Imaging Techniques II
(W)
Lecture Hours: 3
Lab Hours: 3
Credit Hours: 4
Radiographic principles and principles of radiographic quality. Study of theory and practice in methods of protection against ionizing radiation.
Prerequisite: RDSC 201 with grade “C” or better
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RDSC 205 - Patient Care
(W)
Lecture Hours: 3
Lab Hours: 3
Credit Hours: 4
Basic concepts of patient care, including consideration of physical and psychological needs of the patient and family. Routine and emergency patient care procedures. Infection control procedures utilizing Universal Precautions. Role of the radiographer in patient education.
Prerequisite: MIT 103
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RDSC 207 - Seminar
Credit Hours: (Hours to be arranged each term.)
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RDSC 210 - Radiographic Positioning I
(W)
Lecture Hours: 3
Lab Hours: 3
Credit Hours: 4
Demonstration and practice of the routine and special radiographic positions of bones of the upper and lower extremities excluding the shoulder and pelvic girdles.
Prerequisites: RDSC 201 and RDSC 235 , both with grade “C” or better
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RDSC 211 - Radiographic Positioning II
(S)
Lecture Hours: 3
Lab Hours: 3
Credit Hours: 4
Demonstration and practice of routine and special radiographic positions of the axial skeleton, shoulder, and pelvic girdles.
Prerequisites: RDSC 202 , RDSC 210 , and RDSC 235 , all with grade “C” or better
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RDSC 233 - Contrast Media Procedures
(S)
Lecture Hours: 3
Lab Hours: 3
Credit Hours: 4
Routine radiographic examinations of the urinary system, gastrointestinal biliary system, respiratory system, and nervous system, using various contrast medias and filming techniques. All radiographically significant anatomy, physiology, pathology, terminology, and topography, including all contrast studies of these systems.
Prerequisites: RDSC 202 , RDSC 210 , RDSC 235 , all with grade “C” or better
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RDSC 235 - Equipment Operation and Maintenance
(F)
Lecture Hours: 3
Lab Hours: 0
Credit Hours: 3
Basic components and operation of radiographic, fluoroscopic, and mobile units. Evaluation, calibration, and maintenance of radiographic equipment and accessories.
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RDSC 272 - Radiation Protection
(S)
Lecture Hours: 3
Lab Hours: 0
Credit Hours: 3
Basic properties, sources, units of measurement, dosimetry, and biological effects of radiation. Methods of personnel protection and minimizing patient exposure. NCRP recommendations for protective devices and personnel monitoring.
Prerequisites: RDSC 201 and RDSC 235 , both with grade “C” or better
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RDSC 301 - Radiographic Positioning III
(F)
Lecture Hours: 3
Lab Hours: 3
Credit Hours: 4
Demonstration and practice of routine and special radiographic positions of the skull, facial bones, and paranasal sinuses.
Prerequisites: RDSC 211 and RDSC 233 , both with grade “C” or better
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RDSC 307 - Seminar
Credit Hours: (Hours to be arranged each term.)
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RDSC 320 - Surgical, Trauma and Mobile Radiography
(F)
Lecture Hours: 3
Lab Hours: 3
Credit Hours: 4
Routine radiographic examinations of the reproductive, muscular, nervous, skeletal and circulatory systems. Also including emergency and surgical procedures, using various contrast media and filming techniques. The comprehensive study of all radiographically significant anatomy, physiology, pathology, terminology, and topography including all contrast studies of these systems. Control of microorganism by physical and chemical means is incorporated as necessary.
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RDSC 326 - Cardiovascular/Interventional Technology
(S)
Lecture Hours: 3
Lab Hours: 3
Credit Hours: 4
Demonstration and practice of special radiographic examinations of nervous and vascular systems including use of serial film changers and pressure injectors, and other necessary equipment. Also includes related nursing procedures.
Prerequisites: RDSC 211 , RDSC 233 , and RDSC 320 , all with grade “C” or better
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RDSC 350 - Bones: The Interactive Anatomy and Position Course
(F,W)
Lecture Hours: 2
Lab Hours: 0
Credit Hours: 2
A sequential review of osteology and positioning designed for the medical imaging student who has completed the positioning sequence, or the graduate seeking continuing education credit.
Prerequisites: RDSC 210 , RDSC 211 , and RDSC 301 , or Registered Radiologic Technologist
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RDSC 354 - Mammography
(S)
Lecture Hours: 3
Lab Hours: 3
Credit Hours: 4
An in-depth analysis of mammographic positioning, exposure techniques, quality control, film critiquing, and radiation safety. Includes mock registry exam.
Prerequisite: RDSC 301
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RDSC 355 - Computed Tomography
(F)
Lecture Hours: 3
Lab Hours: 3
Credit Hours: 4
X-ray physics, scanner components, and data acquisition of computed tomography. Image reconstruction, manipulation, and artifacts. CT patient care and imaging procedures of the head, neck, spine, chest, abdomen, pelvis, and musculoskeletal system. Laboratory simulation is included.
Prerequisite: BIO 335
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RDSC 365 - Advanced Quality Assurance/Quality Control
(S)
Lecture Hours: 3
Lab Hours: 3
Credit Hours: 4
Principles of diagnostic radiographic quality assurance systems including: quality control testing, equipment calibration, preventive maintenance, and government regulations. Laboratory experiments involve QC tests and measurements.
Prerequisites: RDSC 202 and RDSC 272
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RDSC 366 - Radiographic Pathology
(W)
Lecture Hours: 3
Lab Hours: 0
Credit Hours: 3
An overview of common pathological conditions encountered in the clinical setting, for RDSC students. Pathology is categorized by body systems. The students will learn the pathology as they relate to: signs and symptoms, etiology, imaging diagnosis and prognosis and treatment.
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RDSC 388 - Externship Preparation
(S)
Lecture Hours: 2
Lab Hours: 0
Credit Hours: 2
Presentation of key concepts related to Radiologic Science externship and required in-services. Focus is on patient care and interpersonal scenarios the externship student will likely face while in the clinical environment. Review and discussion of the RDSC Externship Handbook. This course is a mandatory course that must be completed prior to externship.
Prerequisite: RDSC 356
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RDSC 407 - Seminar
Credit Hours: (Hours to be arranged each term.)
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RDSC 410 - Radiologic Science Externship
(F,W,S)
Lecture Hours: 0
Lab Hours: 40
Credit Hours: 15
Students must complete four terms (12 months) of clinical experience in both general radiography and special imaging modalities, to include computed tomography, magnetic resonance imaging, ultrasound, nuclear medicine and/or cardiovascular interventional technology at an affiliated clinical site. Students will complete all phases of general radiography and a maximum of 12 weeks in the special imaging modalities. Students under the direct supervision of qualified radiographers and radiologists.
Prerequisite: All academic coursework in the Radiologic Science curriculum
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RDSC 411 - Special Radiologic Science Externship
(F,W,S)
Lecture Hours: 0
Lab Hours: 40
Credit Hours: 15
This one-term (three-month) practicum is designed to develop the skills of the student in the special imaging modalities, i.e., computed tomography, magnetic resonance imaging, ultrasound, nuclear medicine and special radiographic procedures. The student is sent to an affiliated hospital that has the required special imaging equipment to give the hands-on experience to develop competency in each of three areas chosen by the student. The student will spend one month in each selected area.
Prerequisites: All academic coursework in the Medical Imaging program with grade “C” or better and be a Registered Technologist
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RDSC 411A - Special Radiologic Science Externship
(F,W)
Lecture Hours: 0
Lab Hours: 18
Credit Hours: 7
This two-term practicum is designed to develop skills of the degree completion student in special imaging modalities of computed tomography, magnetic resonance imaging, cardiovascular/interventional technology, mammography, quality assurance, nuclear medicine technology, or sonography. The student selects a local hospital or medical center that has the necessary equipment. Upon approval of the facility, the student begins a supervised experience to develop competencies in each of three chosen areas.
Prerequisites: All academic coursework in the Medical Imaging program with grade “C” or better and an ARRT registered technologist in good standing
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RDSC 411B - Special Radiologic Science Externship
(W)
Lecture Hours: 0
Lab Hours: 22
Credit Hours: 8
This two-term practicum is designed to develop skills of the degree completion student in special imaging modalities of computed tomography, magnetic resonance imaging, cardiovascular/interventional technology, mammography, quality assurance, nuclear medicine technology, or sonography. The student selects a local hospital or medical center that has the necessary equipment. Upon approval of the facility, the student begins a supervised experience to develop competencies in each of three chosen areas.
Prerequisites: All academic coursework in the Medical Imaging program with grade “C” or better and an ARRT registered technologist in good standing
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RDSC 471 - Clinical Imaging Education I
(S)
Lecture Hours: 1
Lab Hours: 0
Credit Hours: 1
Development and application of clinical education objectives relating to medical imaging technology. Instruments used to evaluate student clinical performance and competence.
Prerequisite: RT(R) (ARRT)
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Renewable Energy Engineering |
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REE 107 - Seminar
Credit Hours: (Hours to be arranged each term.)
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REE 201 - Introduction to Renewable Energy
Lecture Hours: 3
Lab Hours: 0
Credit Hours: 3
An introduction to renewable energy. Topics include photovoltaics, solar thermal systems, green building, fuel-cells, hydrogen, wind power, waste heat, biofuels, wave power, tidal power and hydroelectric. Discussions of economic, environment, politics and social policy are integral components of the course.
Prerequisite: MATH 111
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REE 207 - Seminar
Credit Hours: (Hours to be arranged each term.)
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REE 243 - Electrical Power
Lecture Hours: 3
Lab Hours: 3
Credit Hours: 4
Fundamentals of electrical power. Power systems components and equipment. Fundamental analysis and design of electrical power systems.
Prerequisites: EE 223 , MATH 252 , and PHY 222
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REE 253 - Electromechanical Energy Conversion
Lecture Hours: 2
Lab Hours: 3
Credit Hours: 3
Motoring and generating principles for direct current, synchronous, and induction Machines. Analysis and design of motor and generator power and control circuits.
Prerequisites: EE 223 , MATH 252 , and PHY 222
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REE 307 - Seminar
Credit Hours: (Hours to be arranged each term.)
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REE 331 - Fuel Cells
Lecture Hours: 2
Lab Hours: 3
Credit Hours: 3
Introduction to fuel cell technologies: PEM, PAFC, AFC, SOFC, MCFC and DMFC systems. Fuel cell components and systems; field flow plates, electrolytes, electrode materials, electrode catalysts, on-board reformers. Portable devices, utility-scale power production, transportation systems. Fuel types and fuel storage.
Prerequisites: CHE 260 with grade “C” or better and PHY 222
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REE 333 - Batteries
Lecture Hours: 2
Lab Hours: 3
Credit Hours: 3
This course covers fundamentals of the most important battery types including alkaline, zinc-air, lead-acid, nickel-cadmium, nickel metal hydride, lithium ion and lithium polymer. Applications include stationary, transportation and portable batteries. The lab deals with battery system design, testing and prototype assembly.
Prerequisite: CHE 260 with grade “C” or better
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REE 335 - Hydrogen
Lecture Hours: 2
Lab Hours: 3
Credit Hours: 3
This course will cover hydrogen production, storage, distribution and use. Specific energy scenarios such as renewable hydrogen cycles will be explored focusing on transportation applications. The concept of hydrogen economy will be discussed in the context of global energy crisis.
Prerequisite: CHE 260 with grade “C” or better
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REE 337 - Materials for RE Applications
Lecture Hours: 3
Lab Hours: 0
Credit Hours: 3
Electrical, mechanical, thermal, chemical, optical, and processing properties of materials in renewable energy systems; solid-state device characteristics and their material properties. Engineering applications.
Prerequisites: CHE 202 and CHE 205 or CHE 222 , and PHY 223
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REE 344 - Nuclear Energy
Lecture Hours: 3
Lab Hours: 0
Credit Hours: 3
Introduction to nuclear energy. Atomic and nuclear physics; the interaction of radiation and matter. Nuclear reactor operation; reactor components, nuclear cycles, neutron diffusion and moderation. Reactor shielding. Fuel reprocessing and waste disposal. Reactor licensing and safety. Economics and environmental concerns.
Prerequisites: CHE 202 and CHE 205 or CHE 222 , and PHY 223
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REE 345 - Wind Power
Lecture Hours: 3
Lab Hours: 0
Credit Hours: 3
Introduction to power production from wind resources. Historical uses of wind resources. The Earth’s wind systems. Physics of wind power. Vertical and horizontal axis turbines. Aerodynamics of wind turbines. Large-scale turbine farms and siting. Commercial development, economics and environmental impacts.
Prerequisites: MECH 326 or REE 253 , and PHY 222
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REE 346 - Biofuels and Biomass
Lecture Hours: 2
Lab Hours: 3
Credit Hours: 3
Introduction to power production from biomass resources. Historical uses of biomass resources. Biomass as a solar energy store; forestry and agricultural sources, crop wastes. Recycled sources; municipal solid wastes, landfill gas. Gaseous fuels; anaerobic digestion, gasification, liquid fuels, fermentation, hydrolysis, transesterification.
Prerequisites: CHE 202 and CHE 205 , or CHE 222 , and PHY 222
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REE 347 - Hydroelectric Power
Lecture Hours: 3
Lab Hours: 0
Credit Hours: 3
Introduction to hydro-resource power production. Hydro-power in history. Physics of hydrology. Power, head, flow-rate. Turbine hydrodynamics; Francis, Kaplan, Pelton, Turgo, cross-flow. System components: generators, governors, penstocks, spillways, valves, gates, trash racks. Large-scale and micro hydroelectric systems. Pumped storage. Economic, environmental considerations.
Prerequisite: MECH 318
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REE 348 - Solar Thermal Energy Systems
Lecture Hours: 3
Lab Hours: 0
Credit Hours: 3
Introduction to solar thermal energy systems for residential, commercial and industrial applications. Solar radiation; topics in heat transfer; flat plate and concentrating collectors; non-imaging optics; applications including water heating, building heating, cooling, industrial process heat, distillation, solar thermal power systems.
Prerequisites: ENGR 355 and MECH 323
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REE 407 - Seminar
Credit Hours: (Hours to be arranged each term.)
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REE 412 - Photovoltaic Systems
Lecture Hours: 3
Lab Hours: 0
Credit Hours: 3
The solar resource, sun charts, site assessments. Grid-connected and stand-alone systems. Module and array performance. PV system components including batteries, modules, charge controllers, maximum power point trackers, inverters. Economic considerations including investment tax credits, present-value analysis, IRR. Advanced PV materials.
Prerequisite: EE 343 or REE 337
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REE 413 - Electric Power Conversion Systems
Lecture Hours: 2
Lab Hours: 3
Credit Hours: 3
Power electronics devices in energy applications. DC-DC MPPT and charge controllers. Advanced inverter controls and applications. FACTS and HVDC systems and equipment.
Prerequisites: EE 419 and REE 243
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REE 425 - Electricity Markets and Modeling
Lecture Hours: 3
Lab Hours: 0
Credit Hours: 3
Introduction to restructured electricity markets. Students gain knowledge of theory, structures, successes and failures of markets, market participant behavior, risk and uncertainty, and basic simulation and optimization modeling for market analyses.
Prerequisites: ECO 201 or ECO 202 , and EE 221
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REE 427 - Greenhouse Gas Accounting/Footprints
Lecture Hours: 3
Lab Hours: 0
Credit Hours: 3
Course topics include US and international greenhouse gas (GHG) management policies. GHG assessment methods and tools, emissions trading programs, climate risk and risk management, data and information sources, measurement standards and protocols and related sustainability concepts and policies. Course also listed as ENV 427 (cannot be used for graduation credit by students who have taken ENV 427 ).
Prerequisites: Junior or Senior standing, MATH 361 or MATH 465 , and WRI 227
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REE 431 - Geothermal Heat Pump Design
Lecture Hours: 3
Lab Hours: 0
Credit Hours: 3
Theory/design of geothermal heat pump applications, emphasis ground heat exchanger simulation and design. Closed-loop, open loop, and hybrid geothermal heat pump systems will be examined. Exposure to the development and use of geothermal design and simulation tools.
Prerequisite: MECH 323
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REE 439 - Building Energy Auditing and Management
Lecture Hours: 3
Lab Hours: 0
Credit Hours: 3
Evaluating building thermal/electric/process loads, including lighting, hot water, HVAC and central plant systems, industrial refrigeration and motors. Opportunities for managing energy use through controls and operations/ maintenance strategies. Roles of commissioning, energy auditing, renewables and economic analysis in reducing energy use.
Prerequisite: MECH 433
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REE 451 - Geothermal Energy and Direct Use Applications
Lecture Hours: 3
Lab Hours: 0
Credit Hours: 3
Introduction to basic geothermal energy sources and generation. Basic geothermal energy applications including direct use, heat pumps and power generation. Geothermal reservoir, site analysis, exploration and drilling. Direct use application system design (HVAC) and equipment.
Prerequisite: ENGR 355
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REE 453 - Power System Analysis
Lecture Hours: 3
Lab Hours: 0
Credit Hours: 3
Faults: symmetric, un-symmetric. Modeling system components using positive, negative, zero sequence networks. System admittance matrixes. Load flow computational methods such as Gauss-Seidel, Newton-Raphson. Power system transients. Voltage, frequency stability. Power system stabilization. Power system analysis using software, emphasizing renewable resources.
Prerequisites: ENGR 267 and REE 243
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REE 454 - Power System Protection and Control
Lecture Hours: 3
Lab Hours: 0
Credit Hours: 3
Protection systems overview; protective devices; coordination and sequencing of relays; grounding practices; impedence protection. Methods of power systems operation and control; load-frequency control, automatic generation control. Modeling power system protection and control using power system analysis software, emphasizing renewable resources.
Prerequisite: REE 453
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REE 455 - Energy-Efficient Building Design
Lecture Hours: 3
Lab Hours: 0
Credit Hours: 3
Principles of integrated, energy-efficient building design. Interpretation/application of codes, standards. Use of software tools for modeling, simulation of building energy systems. Daylighting, natural ventilation, architectural features of passive solar buildings. Inclusion of renewable resources and net-zero designs. Life-cycle economic analysis.
Prerequisite: MECH 323
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REE 463 - Energy Systems Instrumentation
Lecture Hours: 2
Lab Hours: 3
Credit Hours: 3
Application of electrical and mechanical sensors, data acquisition and logic controllers as applied to energy systems. Determination of physical parameters necessary for control and data-logging. Methods of calibration and correction.
Prerequisite: EE 321
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REE 465 - Renewable Energy Transportation Systems
Lecture Hours: 3
Lab Hours: 0
Credit Hours: 3
Renewable energy transportation systems including fuel cells, hybrid gasoline-electric engines, electric vehicles, bio-diesel, flex-fuel vehicles, high-efficiency diesel engines, gas turbine prime-mover systems. Topics include fuel-air mixing, fuel storage, fuel delivery, cooling, fuel leak detection, chemical safety, and electrical power control systems.
Prerequisites: MECH 326 or REE 253
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REE 469 - Grid Integration of Renewables
Lecture Hours: 3
Lab Hours: 0
Credit Hours: 3
Issues unique to connecting renewable energy generation to the grid, Microgrids, Stability, transient and harmonic effects. Interconnect agreements and requirements, Standards development. SCADA and smart grid concepts, System optimization.
Prerequisite: REE 454
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REE 471 - Geothermal Power Plant Design
Lecture Hours: 3
Lab Hours: 0
Credit Hours: 3
Introduction to geothermal reservoir pressure, temperature and flow models and analysis. Basic geothermal power plant equipment and design for dry steam, single/double flash and binary cycle power plants. Plant thermodynamic analysis/efficiency using Rankine/ Kalina cycles. Plant environmental, economic and social impacts.
Prerequisite: ENGR 355
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REE 511 - Research Methods & Innovation I
Lecture Hours: 3
Lab Hours: 0
Credit Hours: 3
Intellectual Property (IP) development, evaluation, and strategy, IP fundamentals, patent fundamentals, conducting patentability searches, evaluating the patentability potential of an invention, drafting invention disclosures for patent applications, assessing the value of a patent or patent portfolio, and IP licensing fundamentals.
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REE 512 - Research Methods & Innovation II
Lecture Hours: 3
Lab Hours: 0
Credit Hours: 3
Fundamental concepts of scientific research, an introduction to the concepts underlying peer-reviewed research, evaluating the relevance and impact of sources, conducting literature reviews, evaluating published findings, using research productivity tools, using statistical methods, designing research studies, and writing scholarly articles.
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