Intracranial Vascular Treatments
- What are Intracranial Vascular Treatments?
- What are some common uses of the procedure?
- How should I prepare?
- What does the equipment look like?
- How does the procedure work?
- How is the procedure performed?
- What will I experience during and after the procedure?
- Who interprets the results and how do I get them?
- What are the benefits vs. risks?
- What are the limitations of Intracranial Vascular Treatments?
What are Intracranial Vascular Treatments?
Intracranial vascular treatments are minimally invasive procedures that, depending on the patient's condition, involve image-guided internal catheter navigation of the body's blood vessels to improve or block blood flow in the brain's arteries and veins, or image-guided delivery of focused internal radiation from a source outside of the body.
Endovascular therapy refers to precise treatments involving navigation of blood vessels internally with catheters, such as:
- Embolization: synthetic solid or liquid materials called embolic agents are placed through a catheter into a blood vessel or blood vessel abnormality to prevent blood flow to a specific area. Commonly used embolic agents include Polyvinyl Alcohol Particles, liquid agents that harden (NBCA glue or Onyx), liquid agents that sclerose blood vessels (alcohol), microspheres and Gelfoam.
- Drug delivery: medications are delivered very precisely through a catheter to specific locations in the brain through the blood vessels. These drugs include thrombolytic agents to dissolve clots, drugs to relax blood vessels in spasm, or chemotherapy drugs for cancer.
- Device delivery: permanently implanted or temporary medical devices that are placed through a catheter. These include:
- Stents: small tubes used to open blood vessels, redirect blood flow or stabilize other devices such as coils.
- Balloons: devices used to open blood vessels (angioplasty) or assist in the placement of other embolic agents or devices. See the Angioplasty and Vascular Stenting page (http://www.radiologyinfo.org/en/info.cfm?pg=angioplasty) for more information.
- Coils: devices that block blood flow. Coils are most commonly used in the treatment of intracranial aneurysms.
- Mechanical retrievers/aspiration systems: used to remove clots or embolic devices or debris.
Stereotactic radiosurgery is a precise form of radiation therapy that uses highly focused x-rays to eliminate abnormal blood vessels.
What are some common uses of the procedure?
Intracranial vascular treatments are used to occlude, or close off, vessels that are supplying blood to a tumor, especially when the tumor is difficult or impossible to remove. These treatments can also be used to block blood flow to vessel abnormalities, including:
- an aneurysm, a bulge or sac that develops in an artery because the wall of the blood vessel is weak.
- arteriovenous malformation (AVM), a tangle of dilated blood vessels that disrupts normal blood flow in the brain.
- arteriovenous fistula (AVF), an abnormal connection or passageway between an artery and a vein.
- tumors with excessive blood flow.
These treatments can also be used to improve blood flow, including:
- acute stroke treatment.
- opening narrow blood vessels to prevent stroke.
- treatment of intracranial vasospasm, or tension/contracting of blood vessels.
How should I prepare?
Prior to your procedure, your blood may be tested to determine how well your kidneys are functioning and whether your blood clots normally.
You should report to your doctor all medications that you are taking, including herbal supplements, and if you have any allergies, especially to local anesthetic medications, general anesthesia or to contrast materials containing iodine (sometimes referred to as "dye" or "x-ray dye"). Your physician may advise you to stop taking aspirin, nonsteroidal anti-inflammatory drugs (NSAIDs) or blood thinners for a specified period of time before your procedure.
Also inform your doctor about recent illnesses or other medical conditions.
Women should always inform their physician and x-ray technologist if there is any possibility that they are pregnant. Many imaging tests are not performed during pregnancy so as not to expose the fetus to radiation. If an x-ray is necessary, precautions will be taken to minimize radiation exposure to the baby. See the Safety page (www.RadiologyInfo.org/en/safety/) for more information about pregnancy and x-rays.
You will receive specific instructions on how to prepare, including any changes that need to be made to your regular medication schedule.
Other than medications, you may be instructed to not eat or drink anything for several hours before your procedure.
You will be given a gown to wear during the procedure.
You should plan to stay overnight at the hospital for one or more days.
You may want to have a relative or friend accompany you and drive you home afterward.
You should also tell your physician if any of the following apply to you:
What does the equipment look like?
These procedures, similar to surgery, are performed in specific rooms or suites, using specific tools and involving highly trained personnel. X-ray equipment, catheters and a variety of synthetic materials, medications, embolic agents, detachable coils and other devices may be used.
The equipment typically used consists of a fluoroscopic angiography suite with a procedure table, movable x-ray sources and detectors on opposite sides of the table, and television-like monitors for viewing images produced by the x-ray equipment. Monitors are located in the examining room and in a nearby control room with a structure allowing real-time viewing by the treating doctors suspended over the procedure table on which the patient lies. Typically, anesthetic equipment is present as well as physiologic monitoring equipment for use during the procedures, including an intravenous line (IV) and equipment that monitors heartbeat, blood pressure and oxygenation level.
Catheters are small tubes made of synthetic material and coated with a lubricating layer. They vary in size and length depending upon specific uses. Commonly, longer, smaller catheters are placed through larger, shorter catheters to allow navigation of the body's blood vessels.
Your physician will select an embolic agent depending on the size of the blood vessel or malformation and whether the treatment is intended to be permanent or temporary. These include:
- Gelfoam™, a gelatin sponge material, which is cut into small pieces that are injected into an artery and float downstream until they can go no further. After a period ranging from a few days to two weeks, the material dissolves.
- particulate agents, including Polyvinyl alcohol (PVA) and gelatin-impregnated acrylic polymer spheres, which are suspended in liquid and injected into the bloodstream to block small vessels. These agents are used to block or occlude vessels permanently, including the treatment of uterine fibroid tumors.
- various sized metallic coils made of stainless steel or platinum are used to block or occlude large arteries. They can be positioned very precisely to stop bleeding from an injured artery or halt arterial blood flow into an aneurysm.
- liquid sclerosing agents such as alcohols, which are used to destroy blood vessels and vessel malformations. Filling a vessel or a vascular malformation with this liquid agent causes blood clots to form, closing up the abnormal vascular channels.
- liquid embolic agents. When injected into the target channel that needs to be closed off, these block blood flow by quickly hardening.
Aneurysm coils are made of soft platinum wire smaller than a strand of hair that is wound into complex shapes. Various detachment mechanisms allow for precise, controlled placement by the treating physician. They are available in different diameters and lengths.
All detachable coils are scientifically proven to be safe and effective and approved by the U.S. Food and Drug Administration (FDA).
There are three types of embolic coils:
- bare platinum coils
- coated platinum coils
- biologically active coils
There are three basic kinds of stereotactic radiosurgery equipment, each of which uses different instruments and sources of radiation:
- The Gamma Knife®, which uses 192 or 201 beams of highly focused gamma rays all aiming at the target region. The Gamma Knife is ideal for treating small to medium size lesions. See the Gamma Knife page (www.RadiologyInfo.org/en/info.cfm?pg=gamma_knife) for more information.
- Linear accelerator (LINAC) machines, prevalent throughout the world, deliver high-energy x-rays, also known as photons. The linear accelerator can perform radiosurgery on larger tumors in a single session or during multiple sessions, which is called fractionated stereotactic radiotherapy. Multiple manufacturers make this type of machine, which have brand names such as Novalis Tx™, XKnife™, and CyberKnife®. See the Linear Accelerator page (www.RadiologyInfo.org/en/info.cfm?pg=linac) for more information.
- Proton beam or heavy-charged-particle radiosurgery is in limited use in North America, though the number of centers offering proton therapy has increased dramatically in the last several years. See the Proton Therapy page (www.RadiologyInfo.org/en/info.cfm?pg=protonthera) for more information.
How does the procedure work?
Embolization: Using x-ray imaging and a contrast material to visualize the blood vessel, the interventional radiologist inserts a catheter through the skin into a blood vessel and advances it to the treatment site. A device or synthetic material called an embolic agent is then inserted through the catheter and positioned within the blood vessel, aneurysm or malformation where it will remain permanently, causing blockage of blood flow. In the case of brain aneurysms, commonly treated with devices called coils, the body responds by forming blood clots around the coil(s), which helps block the flow of blood into the bulge or passageway and keeps the vessel from rupturing or leaking.
Stroke Treatment: Using x-ray imaging and contrast material to visualize blocked or narrow blood vessels, the interventional radiologist inserts a catheter system through the skin into a blood vessel and advances it to the blockage. Devices such as balloons, stents or retrieval/aspiration systems to open narrow blood vessels or remove clots can then be advanced through the catheter. Medications that dissolve clots or relax blood vessel spasms can also be injected.
Stereotactic radiosurgery is a highly precise form of radiation therapy used primarily to treat tumors and other abnormalities of the brain. Despite its name, stereotactic radiosurgery is a non-surgical procedure that delivers a single high-dose of precisely-targeted radiation using highly focused gamma-ray or x-ray beams that converge on the specific area or areas of the brain where the tumor or other abnormality resides, minimizing the amount of radiation to health brain tissue. When treated with radiosurgery, arteriovenous malformations (AVMs) begin to thicken and close off slowly, typically over several years.
How is the procedure performed?
You will be positioned on the examining table.
You may be connected to monitors that track your heart rate, blood pressure and pulse during the procedure.
A nurse or technologist will insert an intravenous (IV) line into a vein in your hand or arm so that sedative medication can be given intravenously. Moderate sedation may be used. As an alternative, you may receive general anesthesia.
Your physician will numb the area with a local anesthetic.
The area of your body where the catheter is to be inserted will be shaved, sterilized and covered with a surgical drape.
A very small nick is made in the skin at the site.
Catheter embolization: Using imaging guidance, a catheter (a long, thin, hollow plastic tube) is inserted through the skin into a blood vessel and maneuvered to the treatment site.
A contrast material then is injected through the catheter and a series of x-rays are taken to locate the exact site of bleeding or abnormality. The medication or embolic agent is then injected through the catheter. Additional x-rays are taken to ensure proper treatment of the abnormality.
You can expect to stay in bed for six to eight hours after your procedure.
The length of the procedure varies from 30 minutes to several hours depending on the complexity of the condition.
Embolization of brain aneurysms and fistulas: Using image-guidance, a catheter, a long, thin, hollow plastic tube, is inserted through the skin into a blood vessel and maneuvered to the treatment site. A contrast material is then injected through the catheter and a series of x-rays are taken to locate the exact site of the abnormality.
The medication, embolic agent or device is then injected or advanced through the catheter. Additional x-rays are taken to ensure proper treatment of the abnormality.
At the end of the procedure, the catheter will be removed and pressure will be applied to stop any bleeding. The opening in the skin is then covered with a dressing. No sutures are needed.
Occasionally, a device or plug will be used to seal over or close the hole in the artery. This allows patients to return to their normal activities more quickly.
Your intravenous line will be removed.
The length of the procedure varies from 30 minutes to several hours depending on the complexity of the condition.
You can expect to stay in bed for six to eight hours after your procedure.
Gamma Knife radiosurgery involves four phases: placement of the head frame, imaging of the tumor location, computerized dose planning, and radiation delivery. In the first phase, a nurse will place a small needle in your hand or arm to give you medications and a contrast material, if needed, for imaging.
A neurosurgeon will use local anesthesia to numb two spots on your forehead and two spots on the back of your head. A box-shaped head frame will be attached to your skull using specially designed pins to keep your head from moving until the treatment session is finished. This lightweight aluminum head frame is also a guiding device that makes sure the Gamma Knife beams are focused exactly where the treatment is needed.
Next, you will be taken to an imaging area where a magnetic resonance imaging (MRI) scan will be performed to show the exact location of the tumor in relation to the head frame. In some cases, a computed tomography (CT) scan may be performed instead of, or in addition to, an MRI scan. If you are having treatment for an arteriovenous malformation, you may also have an angiogram.
During the next phase, you will be able to relax for an hour or two while your treatment team identifies the tumor(s) for treatment and develops a treatment plan using special computer software to optimally irradiate the tumor and minimize dose to surrounding normal tissues.
Next, you will lie down on the Gamma Knife bed and your head frame will be fixed to the machine before beginning treatment. You will be made comfortable with a pillow or wedge-shaped sponge under your knees and a blanket over you. The treatment team will then go to the control room outside of the treatment room to begin your treatment. You will be able to talk to your physician through a microphone in the helmet and a camera will allow the team to see you at all times. The bed you are lying on will move backward into the Gamma Knife machine. You will not feel the treatment and the machine is very quiet.
Depending on the Gamma Knife model and the treatment plan, the whole treatment may be performed without interruption or it may be broken up into multiple smaller parts. The total treatment may last less than one hour or up to four hours. A chime will sound when the treatment is complete and the bed will return to its original position. As soon as the treatment is finished, you will sit up and the head frame will be removed. In most cases, you should be able to go home soon afterward.
Linear accelerator (LINAC) radiosurgery is similar to the Gamma Knife procedure and its four phases: head frame placement, imaging, computerized dose planning and radiation delivery. Unlike the Gamma Knife, which remains motionless during the procedure, part of the LINAC machine called a gantry rotates around the patient, delivering radiation beams from different angles. Compared to the Gamma Knife, the LINAC is able to use a larger x-ray beam, which enables it to treat larger tumors more uniformly and it can be used for fractionated radiosurgery or stereotactic radiotherapy using a relocatable frame, which is an advantage for large tumors or particularly critical locations.
For CyberKnife radiosurgery, a head frame is not necessary. Instead, a plastic mesh mask will be made to help hold your head in position and a detailed CT scan will be performed with your mask on. You may also have an MRI scan to align with this CT scan in the treatment planning computer. The imaging, treatment planning, and first treatment may be spread out over multiple days. You may have up to five treatments over the span of one or one and a half weeks.
For the treatment, you will lie down and the mask will be placed over your head. X-ray images will be taken to ensure that you are in proper position, and then the treatment will begin. Your radiation therapist will monitor you at all times from outside the treatment room. The robotic arm will move around you to aim at the target from a hundred or several hundred directions. Your head won't have to remain perfectly still during treatment; x-ray images taken every minute or so will detect any small movements of your head and the robot will correct for these small movements to ensure accuracy throughout the treatment. The treatment may last about one or two hours.
What will I experience during and after the procedure?
Devices to monitor your heart rate and blood pressure will be attached to your body.
You will feel a slight pin prick when the needle is inserted into your vein for the intravenous line (IV) and when the local anesthetic is injected.
If you receive a general anesthetic, you will be unconscious for the entire procedure, and you will be monitored by an anesthesiologist.
If the case is done with sedation, the intravenous (IV) sedative will make you feel relaxed and sleepy. You may or may not remain awake, depending on how deeply you are sedated.
You may feel slight pressure when the catheter is inserted, but no serious discomfort.
As the contrast material passes through your body, you may get a warm feeling.
Most patients experience some side effects after embolization. Pain is the most common and can be controlled by medication given by mouth or through your IV.
Radiosurgery treatments are similar to having an x-ray. You will not be able to see, feel or hear the x-rays. There is no pain or discomfort from the actual treatment. If you experience pain for other reasons, such as back pain or discomfort from the head frame, you should let your doctor or nurse know.
When the head frame is removed, there may be some minor bleeding from the pin sites that will be bandaged. You may experience a headache and can ask for medication to help make you feel more comfortable. In most cases, patients can resume all of their normal activities within one or two days.
Who interprets the results and how do I get them?
The interventional radiologist can advise you as to whether the procedure was a technical success when it is completed.
Your interventional radiologist may recommend a follow-up visit after your procedure or treatment is complete.
The visit may include a physical check-up, imaging procedure(s) and blood or other lab tests. During your follow-up visit, you may discuss with your doctor any changes or side effects you have experienced since your procedure or treatment.
What are the benefits vs. risks?
- No surgical incision is needed—only a small nick in the skin that does not have to be stitched closed.
- Embolization is a highly effective way of controlling bleeding, especially in an emergency situation.
- Embolization is much less invasive than conventional open surgery. As a result, there are fewer complications and the hospital stay is relatively brief—often only the night after the procedure. Blood loss is less than with traditional surgical treatment, and there is no obvious surgical incision.
- This method can be used to treat tumors and vascular malformations that either cannot be removed surgically or would involve great risk if surgery was attempted.
Embolization for brain aneurysms and fistulas:
- Using detachable coils to close off an aneurysm or fistula is effective in preventing bleeding and relieving symptoms.
- Embolization is a treatment for cerebral aneurysms and fistulas that previously were considered inoperable. This procedure is less invasive and requires significantly less recovery time than open surgery for aneurysm repair. Additional benefits include minimal blood loss and the option of local anesthesia.
- There is a very slight risk of an allergic reaction if contrast material is injected.
- Any procedure that involves placement of a catheter inside a blood vessel carries certain risks. These risks include damage to the blood vessel, bruising or bleeding at the puncture site, and infection.
- There is always a chance that an embolic agent can lodge in the wrong place and deprive normal tissue of its oxygen supply.
- There is a slight risk of death or illness. Coil embolization of unruptured aneurysms and fistulas carries less risk than embolization following a stroke. Approximately seven percent of cases require additional treatment or surgery.
What are the limitations of Intracranial Vascular Treatments?
Embolization of brain aneurysms and fistulas: Recurrence depends on the coils' success or failure in controlling the "neck" of the aneurysm or fistula. If the coil completely prevents blood flow into the aneurysm, then the patient need not be concerned about recurrence. The durability of coil embolization varies depending on the size and shape of the aneurysm. Coil embolization of small aneurysms with small necks has better results than embolization of large aneurysms with wide necks. Long-term follow-up has shown permanent success in more than 80 percent of aneurysms treated with coil embolization. Additional medical technologies, such as balloon assistance and microstenting are improving the success of treating brain aneurysms with coil embolization. Unfortunately, large aneurysms with wide necks remain a challenge.
Locate an ACR-accredited provider: To locate a medical imaging or radiation oncology provider in your community, you can search the ACR-accredited facilities database.
Interventional radiology: For more information on interventional radiology procedures, visit the Society of Interventional Radiology (SIR) website at www.sirweb.org.
Exam costs: The costs for specific medical imaging tests and treatments vary widely across geographic regions. Many—but not all—imaging procedures are covered by insurance. Discuss the fees associated with your medical imaging procedure with your doctor and/or the medical facility staff to get a better understanding of the portions covered by insurance and the possible charges that you will incur.
Web page review process: This Web page is reviewed regularly by a physician with expertise in the medical area presented and is further reviewed by committees from the American College of Radiology (ACR) and the Radiological Society of North America (RSNA), comprising physicians with expertise in several radiologic areas.
Outside links: For the convenience of our users, RadiologyInfo.org provides links to relevant websites. RadiologyInfo.org, ACR and RSNA are not responsible for the content contained on the web pages found at these links.
This page was reviewed on July 25, 2012