Choose a Radiology Technician Course online

How to choose a radiology technician 
course online

Courses for radiology technicians have become quite popular in the past few years. With the population aging in the past decades, more and more people in the medical field are needed to address the demand of senior citizens. Radiology technicians are the people who operate the radiological machinery in the hospital. They are not exactly doctors but they are definitely experts in using expensive equipment like the x-ray machine or radiograph, the computed tomography or CT scan as well as the other devices used to look into people’s bodies with the use of a radioactive substance. They also make sure that the plates and films that are taken during the diagnostic process are clear enough to be interpreted by a doctor.

The Internet would be a good place to look for a radiology technician course. Most reputable schools have their programs listed and some institutions even go as far as advertising their programs online. If you want to go to school and be a radiology technician, you may find what you’re looking for over the Internet. Here’s how you choose the best course:

1. Browse through the nearby community colleges and university websites. A course in radiological technology is common in the set of courses offered by education institutions so it would not be that difficult to find one. Look for the details of the course in the website. It would be ideal if you could look at the curriculum, the number of hours needed and the type of training that you’ll get.
2. Arrange for an appointment if the website does not hold the necessary information to help you understand the ins and outs of the course. There would be an admission office for people like you who would need more convincing. These people would normally have a detailed pamphlet for you.
3. Inquire about the type of training that you’ll get by either calling the numbers on the website or sending an email. Aside from the things that you will learn in the class room, the amount of knowledge that you will learn in a real hospital environment will be very important in making you good in this field.
4. Ask about the employment opportunities that you have after you graduate from their institution. You could always inquire the careers of their past graduates and how they have fared in qualification and licensure examinations. The admission rates for further training in other hospitals and educational institutions should also be scrutinized.
5. Look up the rates and the cost of the course and try to compare it with institutions of similar stature. You may also ask about scholarship programs that the school offers so that you can have some part of your tuition subsidized.

Finding a good course to become a radiology technician online is quite an easy task if you know what to look for. This is a big monetary investment and career path so make sure that you make the best decision out of it.

How to Choose Radiology Graduate Programs

How to Choose Colleges Offering Radiology 

Graduate Programs

Radiology is a specialized branch in the health care industry. It utilizes imaging technology namely x-rays, CT scans, and MRI scans to diagnose and treat patients. A handful of selected universities across the country are offering radiology graduate programs.

Selecting a Radiology School

Radiology graduate programs differ from school to school due to the highly specialized nature of master’s degree programs. Aspiring students have to narrow down their scope of interest in radiology and choose a school that best embodies those interests.

If a research-based career is the first choice, the student might consider choosing a school with a program that heavily focuses on the physics aspect of radiology. Those who finish a Master of Science in Radiological Physics degree program are entitled to become research team members that investigate cases and problems in radiation oncology, nuclear medicine, diagnostic radiology, and radiation biology. They are also qualified to do hands-on work in diagnostic radiology and radiation oncology fields.

Radiologic technologists who are looking for ways to increase their current pay might want to consider getting a master’s degree in radiology. According to a survey by the American Society of Radiologic Technologists (ASRT) in 2004, radiologic technologists had a median income of about $63,000 (www.asrt.com). Meanwhile, according to Salary.com, their median salaries are a little below $50,000 as of this year.  In 2008, another survey by the ASRT showed that the radiologist assistant’s mean income was about $103,000.  Students who are interested in pursuing a career along these lines will do well to go after colleges offering a Master of Science – Radiologist Assistant.

Once students have selected a field for study, they should check out their prospective schools’ resources and facilities.  They should particularly look for the availability of PET scanners, image processing labs, and CT and MRI scanners. These will differ from school to school and they directly impact the educational experience of the student. Some programs take on a more hands-on approach than others during laboratory and lecture halls or seminars. But at the very least, a number of colleges offering distance-education-programs only require a physical attendance of not more than once a month as the rest of the course can be completed from home.

Radiology Graduate Program Overviews

Master of Science – Radiologist Assistant

The degree title of this program varies from school to school, but its aim will always be to make competent radiologic assistants out of their students. Those who undergo this course will take up units in human anatomy, medical terminology, image critiquing, pathophysiology, patient diagnosis and management, and medical legal issues. The Master of Science Radiologist Assistant program almost always requires hundreds of hours in a clinical placement, enabling students to acquire knowledge in the radiologic working environment from qualified professionals.

Master of Science in Radiological Physics

This program has a significant focus in radiation oncology, although this program is not fully related to radiology by nature. Students will be taking up units radiation safety, radiation therapy, radiation dosimetry, nuclear medicine, magnetic resonance, and diagnostic radiology. They will spend a great amount of time in radiation laboratories. As part of the program, their students are required to submit a thesis based on an approved project relating to the field of radiological physics.

Radiology Technician Schools

Radiology Technician School

For those of you who wish to take up a career as a radiology technician, you need to learn how to select a radiology technician school where you will be offered the best radiologic technologist program to get you through your training and educate you on your chosen subject.

Unlike several leading industries, the medical field does not appear to have been affected by economic problems and this is the reason why many people are opting for careers within this area. There is an endless amount of opportunities open to those wanting to venture into the medical industry and positions such as radiology employment, for example, are well paid and regularly sought after. A career as a radiology technologist can take the job holder anywhere and you could find yourself working in a small office, a clinic or a large hospital. However, when considering where to train you need to completely understand the skills required and the demands made as far as this kind of job is concerned and this will help you to select the right radiology tech school where your radiology technologist career goals can be achieved.

The job of radiologic technologist involves working with X-ray and ultrasound equipment in order to explain the process and techniques used and give the results of the diagnosis to the patient. The machines used also have to be maintained by the job holder. The average annual salary is in the region of $35,000 and $45,000, the exact amount being determined by where the work takes place. This could be in a clinic, a hospital, a nursing home or all manner of other health facility locations. It is useful to know which of these locations you would prefer to work in and what type of degree and training is needed prior to deciding which radiology school to attend.

The training provided at radiology schools has to be successfully completed in order to become a radiologist. The duration of the training is usually two years but there are four year courses on offer too. A radiologic technologist student can obtain a degree or a certificate. The latter is more often than not recommended for someone who is already trained and working in the medical field and looking for a change in career direction. A good program will be with an accredited college and hands on training using and maintaining the relevant equipment and dealing with patients will be part of the training program. When the program has been completed a person can then begin their career as a certified technician.

With so many options of different radiology education programs available, the one you choose all comes down to a matter of personal choice. Of course, personal needs also have to be taken into account when looking for a program to fit in with your schedule as it is necessary that you are able to attend class without disturbing or interfering with your other daily obligations.

It goes without saying that a good understanding of a career in this field is necessary before embarking on radiology training. If you are fully aware of the kind of skills you are required to have and the things you need to learn about, this will help you to choose the best school for you and by collecting together these details the program choosing task can be made so much easier. The radiology technician program you opt for should allow you to begin work in your new and interesting career as soon as the training is completed.

Picture archiving and communication system

Picture archiving and communication system (PACS)

A picture archiving and communication system (PACS) is a medical imaging technology which provides economical storage of, and convenient access to, images from multiple modalities (source machine types). Electronic images and reports are transmitted digitally via PACS; this eliminates the need to manually file, retrieve, or transport film jackets. The universal format for PACS image storage and transfer is DICOM (Digital Imaging and Communications in Medicine).

Types of images

Most PACSs handle images from various medical imaging instruments, including ultrasound (US),magnetic resonance (MR), positron emission tomography (PET), computed tomography (CT), endoscopy (ENDO), mammograms (MG),Digital radiography (DR), computed radiography (CR) ophthalmology, etc. Additional types of image formats are always being added. Clinical areas beyond radiology; cardiology, oncology, gastroenterology and even the laboratory are creating medical images that can be incorporated into PACS. (see DICOM Application areas).

Uses

PACS is offered by virtually all the major medical imaging equipment manufacturers, medical IT companies and many independent software companies. Basic PACS software can be found free on the Internet.

Hard copy replacement: PACS replaces hard-copy based means of managing medical images, such as film archives. With the decreasing price of digital storage, PACSs provide a growing cost and space advantage over film archives in addition to the instant access to prior images at the same institution. Digital copies are referred to as Soft-copy.

• Radiology Workflow Management: PACS is used by radiology personnel to manage the workflow of patient exams.

PACS is offered by virtually all the major medical imaging equipment manufacturers, medical IT companies and many independent software companies. Basic PACS software can be found free on the Internet.

Architecture

Querying & Image Retrieval

The communication with the PACS server is done through dicom objects that are similar to dicom images, but with different tags. A query typically looks as follows:

• The client establishes the network connection to the PACS server.
• The client prepares a query object which is an empty dicom dataset object.
• The client fills in the query object with the keys that should be matched. E.g. to query for a patient ID, the patient ID tag is filled with the patient's ID.
• The query object is sent to the server.
• The server sends back to the client a list of response dicom objects.
• The client extracts the tags that are of interest from the response dicom objects.

Image archival and backup

Digital medical images are typically stored locally on a PACS for retrieval. It is important (and required in the USA by the Security Rule's Administrative Safeguards section of HIPAA) that facilities have a means of recovering images in the event of an error or disaster. While each facility is different, the goal in image back-up is to make it automatic and as easy to administer as possible. The hope is that the copies won't ever be needed, but, as with other disaster recovery and business continuity planning, they need to be available if needed.

Integration

A chest image displayed via a PACS

A full PACS should provide a single point of access for images and their associated data. That is, it should support all digital modalities, in all departments, throughout the enterprise.

However, until PACS penetration is complete, individual islands of digital imaging not yet connected to a central PACS may exist. These may take the form of a localized, modality-specific network of modalities, workstations and storage (a so-called "mini-PACS"), or may consist of a small cluster of modalities directly connected to reading workstations without long term storage or management. Such systems are also often not connected to the departmental information system. Historically, Ultrasound, Nuclear Medicine and Cardiology Cath Labs are often departments that adopt such an approach.

Courtesy: en.wikipedis.org

Radiology Information System (RIS)

A radiology information system (RIS) is a networked software suite for managing medical imagery and associated data. An RIS is especially useful for managing radiological records and associated data in a multiple locations and is often used in conjunction with a picture archiving and communication system (PACS) to manage work flow and billing.

An RIS has several basic functions:

Scheduling 
Appointments can be made for both in- and out-patients with specific radiology staff.  

Patient tracking
A patient’s entire radiology history can be tracked from admission to discharge.  The history can be coordinated with past, present and future appointments

This can be done as, first the patient order booking and the 0rder acceptance

Results reportingAn RIS can generate statistical reports for a single patient, group of patients or particular procedure. 

Film tracking
An RIS can track individual films and their associate data.  

Billing
An RIS facilitates detailed financial record-keeping, electronic payments and automated claims submission.

Radiology: The complete info

Radiology  what is it??
Radiology is the branch or specialty of medicine that deals with the study and application of imaging technology like x-ray and radiation to diagnosing and treating disease.


Radiologists direct an array of imaging technologies (such as ultrasound, computed tomography (CT), nuclear medicine, positron emission tomography (PET) and magnetic resonance imaging (MRI)) to diagnose or treat disease. Interventional radiology is the performance of (usually minimally invasive) medical procedures with the guidance of imaging technologies. The acquisition of medical imaging is usually carried out by the radiographer or radiologic technologist.


Radiology-Modalities
The following imaging modalities are used in the field of diagnostic radiology:


Projection (plain) radiography
Radiographs (or Roentgenographs, named after the discoverer of X-rays, Wilhelm Conrad Röntgen) are produced by the transmission of X-Rays through a patient to a capture device then converted into an image for diagnosis. The original and still common imaging produces silver impregnated films. In Film - Screen radiography an x-ray tube generates a beam of x-rays which is aimed at the patient. The x-rays which pass through the patient are filtered to reduce scatter and noise and then strike an undeveloped film, held tight to a screen of light emitting phosphors in a light-tight cassette. The film is then developed chemically and an image appears on the film. Now replacing Film-Screen radiography is Digital Radiography, DR, in which x-rays strike a plate of sensors which then converts the signals generated into digital information and an image on computer screen.


Plain radiography was the only imaging modality available during the first 50 years of radiology. It is still the first study ordered in evaluation of the lungs, heart and skeleton because of its wide availability, speed and relative low cost.


Fluoroscopy
Fluoroscopy and angiography are special applications of X-ray imaging, in which a fluorescent screen and image intensifier tube is connected to a closed-circuit television system. This allows real-time imaging of structures in motion or augmented with a radiocontrast agent. Radiocontrast agents are administered, often swallowed or injected into the body of the patient, to delineate anatomy and functioning of the blood vessels, the genitourinary system or the gastrointestinal tract. Two radiocontrasts are presently in use. Barium (as BaSO4) may be given orally or rectally for evaluation of the GI tract. Iodine, in multiple proprietary forms, may be given by oral, rectal, intraarterial or intravenous routes. These radiocontrast agents strongly absorb or scatter X-ray radiation, and in conjunction with the real-time imaging allows demonstration of dynamic processes, such as peristalsis in the digestive tract or blood flow in arteries and veins. Iodine contrast may also be concentrated in abnormal areas more or less than in normal tissues and make abnormalities (tumors, cysts, inflammation) more conspicuous. Additionally, in specific circumstances air can be used as a contrast agent for the gastrointestinal system and carbon dioxide can be used as a contrast agent in the venous system; in these cases, the contrast agent attenuates the X-ray radiation less than the surrounding tissues.


CT scanning
CT imaging uses X-rays in conjunction with computing algorithms to image the body. In CT, an X-ray generating tube opposite an X-ray detector (or detectors) in a ring shaped apparatus rotate around a patient producing a computer generated cross-sectional image (tomogram). CT is acquired in the axial plane, while coronal and sagittal images can be rendered by computer reconstruction. Radiocontrast agents are often used with CT for enhanced delineation of anatomy. Although radiographs provide higher spatial resolution, CT can detect more subtle variations in attenuation of X-rays. CT exposes the patient to more ionizing radiation than a radiograph. Spiral Multi-detector CT utilizes 8,16 or 64 detectors during continuous motion of the patient through the radiation beam to obtain much finer detail images in a shorter exam time. With rapid administration of IV contrast during the CT scan these fine detail images can be reconstructed into 3D images of carotid, cerebral and coronary arteries, CTA, CT angiography. CT scanning has become the test of choice in diagnosing some urgent and emergent conditions such as cerebral hemorrhage, pulmonary embolism (clots in the arteries of the lungs), aortic dissection (tearing of the aortic wall), appendicitis, diverticulitis, and obstructing kidney stones. Continuing improvements in CT technology including faster scanning times and improved resolution have dramatically increased the accuracy and usefulness of CT scanning and consequently increased utilization in medical diagnosis.


The first commercially viable CT scanner was invented by Sir Godfrey Hounsfield at EMI Central Research Labs, Great Britain in 1972. EMI owned the distribution rights to The Beatles music and it was their profits which funded the research. Sir Hounsfield and Alan McLeod McCormick shared the Nobel Prize for Medicine in 1979 for the invention of CT scanning. The first CT scanner in North America was installed at the Mayo Clinic in Rochester, MN in 1972.


Ultrasound
Medical ultrasonography uses ultrasound (high-frequency sound waves) to visualize soft tissue structures in the body in real time. No ionizing radiation is involved, but the quality of the images obtained using ultrasound is highly dependent on the skill of the person (ultrasonographer) performing the exam. Ultrasound is also limited by its inability to image through air (lungs, bowel loops) or bone. The use of ultrasound in medical imaging has developed mostly within the last 30 years. The first ultrasound images were static and two dimensional (2D), but with modern-day ultrasonography 3D reconstructions can be observed in real-time; effectively becoming 4D.


Because ultrasound does not utilize ionizing radiation, unlike radiography, CT scans, and nuclear medicine imaging techniques, it is generally considered safer. For this reason, this modality plays a vital role in obstetrical imaging. Fetal anatomic development can be thoroughly evaluated allowing early diagnosis of many fetal anomalies. Growth can be assessed over time, important in patients with chronic disease or gestation-induced disease, and in multiple gestations (twins, triplets etc.). Color-Flow Doppler Ultrasound measures the severity of peripheral vascular disease and is used by Cardiology for dynamic evaluation of the heart, heart valves and major vessels. Stenosis of the carotid arteries can presage cerebral infarcts (strokes). DVT in the legs can be found via ultrasound before it dislodges and travels to the lungs (pulmonary embolism), which can be fatal if left untreated. Ultrasound is useful for image-guided interventions like biopsies and drainages such as thoracentesis). Small portable ultrasound devices now replace peritoneal lavage in the triage of trauma victims by directly assessing for the presence of hemorrhage in the peritoneum and the integrity of the major viscera including the liver, spleen and kidneys. Extensive hemoperitoneum (bleeding inside the body cavity) or injury to the major organs may require emergent surgical exploration and repair.


MRI (Magnetic Resonance Imaging)
MRI uses strong magnetic fields to align atomic nuclei (usually hydrogen protons) within body tissues, then uses a radio signal to disturb the axis of rotation of these nuclei and observes the radio frequency signal generated as the nuclei return to their baseline states plus all surrounding areas. The radio signals are collected by small antennae, called coils, placed near the area of interest. An advantage of MRI is its ability to produce images in axial, coronal, sagittal and multiple oblique planes with equal ease. MRI scans give the best soft tissue contrast of all the imaging modalities. With advances in scanning speed and spatial resolution, and improvements in computer 3D algorithms and hardware, MRI has become a tool in musculoskeletal radiology and neuroradiology.


One disadvantage is that the patient has to hold still for long periods of time in a noisy, cramped space while the imaging is performed. Claustrophobia severe enough to terminate the MRI exam is reported in up to 5% of patients. Recent improvements in magnet design including stronger magnetic fields (3 teslas), shortening exam times, wider, shorter magnet bores and more open magnet designs, have brought some relief for claustrophobic patients. However, in magnets of equal field strength there is often a trade-off between image quality and open design. MRI has great benefit in imaging the brain, spine, and musculoskeletal system. The modality is currently contraindicated for patients with pacemakers, cochlear implants, some indwelling medication pumps, certain types of cerebral aneurysm clips, metal fragments in the eyes and some metallic hardware due to the powerful magnetic fields and strong fluctuating radio signals the body is exposed to. Areas of potential advancement include functional imaging, cardiovascular MRI, as well as MR image guided therapy.


Nuclear Medicine
Nuclear medicine imaging involves the administration into the patient of radiopharmaceuticals consisting of substances with affinity for certain body tissues labeled with radioactive tracer. The most commonly used tracers are Technetium-99m, Iodine-123, Iodine-131, Gallium-67 and Thallium-201. The heart, lungs, thyroid, liver, gallbladder, and bones are commonly evaluated for particular conditions using these techniques. While anatomical detail is limited in these studies, nuclear medicine is useful in displaying physiological function. The excretory function of the kidneys, iodine concentrating ability of the thyroid, blood flow to heart muscle, etc. can be measured. The principal imaging device is the gamma camera which detects the radiation emitted by the tracer in the body and displays it as an image. With computer processing, the information can be displayed as axial, coronal and sagittal images (SPECT images, single-photon emission computed tomography). In the most modern devices Nuclear Medicine images can be fused with a CT scan taken quasi-simultaneously so that the physiological information can be overlaid or co-registered with the anatomical structures to improve diagnostic accuracy.


PET,(positron emission tomography), scanning also falls under "nuclear medicine." In PET scanning, a radioactive biologically-active substance, most often Fluorine-18 Fluorodeoxyglucose, is injected into a patient and the radiation emitted by the patient is detected to produce multi-planar images of the body. Metabolically more active tissues, such as cancer, concentrate the active substance more than normal tissues. PET images can be combined with CT images to improve diagnostic accuracy.


The applications of nuclear medicine can include bone scanning which traditionally has had a strong role in the work-up/staging of cancers. Myocardial perfusion imaging is a sensitive and specific screening exam for reversible myocardial ischemia. Molecular Imaging is the new and exciting frontier in this field.