Magnetic resonance (MR) imaging uses radio waves and a strong magnetic field rather than x-rays to provide clear and detailed pictures of internal organs and tissues. Functional magnetic resonance imaging (fMRI) is a relatively new procedure that uses MR imaging to measure the quick, tiny metabolic changes that take place in an active part of the brain. Physicians know the general areas of the brain where speech, sensation, memory, and other functions occur. However, the exact locations vary from individual to individual. Injuries and disease, such as stroke or brain tumor, can even cause functions to shift to other parts of the brain. fMRI not only helps radiologists look closely at the anatomy of the brain, but can help them determine precisely which part of the brain is handling critical functions such as thought, speech, movement, and sensation. This information can be critical to planning surgery, radiation therapy, treatment for cerebral vascular or other interventions to treat brain disorders.
fMRI is becoming the diagnostic method of choice for learning how a normal, diseased or injured brain is working, as well as for assessing the potential risks of surgery or other invasive treatment of the brain. The term “Functional MRI” (with a “capital F”) can also include other MRI techniques that are sensitive to physiologic changes (such as changes in water motion), whereas “little f” fMRI usually refers to mapping of brain activity using MRI. As a group, these “Functional MRI” techniques appear to provide the most sensitive method currently available for identifying, investigating, and monitoring brain tumors, cerebral vascular, and certain chronic disorders of the nervous system such as multiple sclerosis. In addition, these methods appear to provide a useful means of documenting some brain abnormalities related to dementia or seizures.
In routine practice, fMRI studies are often used in planning brain surgery, since they can help physicians monitor normal brain function as well as any disturbed brain function. While research is still ongoing, it appears that fMRI can also help assess the effects of cerebral vascular, trauma, or degenerative disease (such as Alzheimer’s) on brain function.
Since fMRI uses an MRI device, the standard preparations for an MRI procedure are necessary. For example, because the strong magnetic field used for MRI will pull on any ferromagnetic metal object implanted in the body, MRI staff will ask whether you have a heart pacemaker (or artificial heart valve), implanted port, infusion catheter (brand names Port-o-cath, Infusaport, Lifeport), intrauterine device (IUD), or any metal plates, pins, screws, or surgical staples in your body. In most cases, surgical staples, plates, pins and screws pose no risk during MRI. Red dyes used in tattoos and permanent eyeliner may contain metallic iron oxide and could heat up during MRI, however this is rare. You will be asked if you have ever had a bullet or shrapnel in your body, or ever worked with metal. If there is any question of metal fragments, you may be asked to have an x-ray that will detect any such metal objects. Tooth fillings are not affected by the magnetic field, but they may distort images of the facial area or brain, so the technologist should be aware of them. The same is true of braces, which may make it hard to “tune” the MRI unit to your body. You will be asked to remove anything that might degrade MRI images of the head, including hairpins, jewellery, eyeglasses, hearing aids, and any removable dental work.
The radiologist or an assistant may ask about drug allergies and whether head surgery has been done in the past. If you might be pregnant, this should be mentioned. Less than one in 20 patients who undergo MRI in an enclosed unit may feel confined or claustrophobic.
The conventional MRI unit is a cylindrical magnet in which the patient must lie totally still for several seconds at a time, and consequently may feel closed-in or truly claustrophobic. However, new patient-friendly designs are rapidly coming into routine use. The “short-bore” systems are wider and shorter and do not fully enclose the patient. Some newer units are open on all sides; however, the image quality may vary.
MRI uses radio waves and a strong magnetic field rather than x-rays to provide clear and detailed pictures of internal organs and tissues. fMRI uses this technology to identify regions of the brain where blood vessels are expanding, chemical changes are taking place, or extra oxygen is being delivered—all signs that this part of the brain is currently processing information and giving commands to the body.
In fMRI, the patient performs a particular task while the imaging is taking place. The metabolism in the area of the brain responsible for this task will increase, and the signal in the MR image will change. By performing specific tasks that correspond to different functions, it is possible to locate the corresponding area of the brain that governs the function. This information can then be incorporated into a surgical planner to help a surgeon avoid these areas.
The patient lies on a sliding table, with his or her head in a brace designed to help hold the head still. This brace may include a mask created especially for the individual. As the examination proceeds, the patient will be asked to perform a number of small tasks, such as tapping the thumb of one hand against each of the fingers of that hand, or rubbing a block of sandpaper, or answering simple questions. The patient is able to communicate with the radiologist or technologist throughout the exam. Also, many MRI centers allow a friend or, if a child is being examined, a parent, into the room.
Depending on how many images are needed, the exam will generally take from 15 to 45 minutes, although a very detailed study may take longer. You will be asked not to move during the actual imaging process, but between sequences some movement is allowed. Patients are generally required to remain still for only a few minutes at a time.
When the exam is over the patient is asked to wait until the images are examined to determine if more images are needed.
MRI causes no pain, but there may be discomfort from being closed in or from the need to keep your head very still. You may notice a warm feeling in the area under examination; this is normal, but if it bothers you the radiologist or technologist should be told. The loud tapping or knocking noises heard at certain phases of imaging can be bothersome to some people. However, in fMRI exams, the actual imaging is done in a series of very short bursts, so the noise will not last long.
A radiologist, who is a physician experienced in MRI and other radiology examinations, will analyze the images and send a signed report with his or her interpretation to the patient’s referring physician. The patient receives the results from the referring physician who ordered the test. New technology also allows for distribution of diagnostic reports and referral images over the Internet at many facilities.