Acoustic neuroma medical therapy: Difference between revisions
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==Medical Therapy== | ==Medical Therapy== | ||
There are three main courses of treatment for acoustic neuroma: | There are three main courses of treatment for acoustic neuroma: | ||
*Observation | *[[Observation]] | ||
*Surgery | *[[Surgery]] | ||
*Radiation therapy | *[[Radiation]] therapy | ||
The number of factors that decide selecting the right treatment include: | The number of factors that decide selecting the right treatment include: | ||
*Age | *Age | ||
Line 31: | Line 31: | ||
*Stereotactic [[radiotherapy]] | *Stereotactic [[radiotherapy]] | ||
*[[Proton]] beam therapy | *[[Proton]] beam therapy | ||
* | *Conventional fractionated [[radiation]] therapy | ||
===Stereotactic Radiosurgery=== | ===Stereotactic Radiosurgery=== | ||
In single dose treatments, many hundreds of small beams of radiation are aimed at the tumor. This results in a high dose of radiation to the tumor and very little to any surrounding [[brain]] structures. Many patients have been treated this way with high success rates. Facial [[weakness]] or [[numbness]], in the hands of experienced radiation physicians, occurs in only a small percent of cases. This can be performed with either the linear accelerator or [[gamma]] knife. Radiosurgery is a treatment option for patients with smaller tumors (<3 cm) or for patients with enlarging tumors who are not candidates for surgery. | In single dose treatments, many hundreds of small beams of radiation are aimed at the tumor. This results in a high dose of radiation to the tumor and very little to any surrounding [[brain]] structures. Many patients have been treated this way with high success rates. Facial [[weakness]] or [[numbness]], in the hands of experienced radiation physicians, occurs in only a small percent of cases. This can be performed with either the linear accelerator or [[gamma]] knife. [[Radiosurgery]] is a treatment option for patients with smaller tumors (<3 cm) or for patients with enlarging tumors who are not candidates for [[surgery]]. | ||
*Complications of stereotactic radiosurgery include: | *Complications of stereotactic radiosurgery include: | ||
**Post [[radiation]] [[tumor]] expansion | **Post [[radiation]] [[tumor]] expansion | ||
Line 40: | Line 40: | ||
**[[Malignant]] transformation | **[[Malignant]] transformation | ||
===Stereotactic Radiotherapy=== | ===Stereotactic Radiotherapy=== | ||
The multi-dose treatment, | The multi-dose treatment, FSR, delivers smaller doses of radiation over a period of time, requiring the patient to return to the treatment location on a daily basis, from 3 to 30 times, generally over several weeks. Each visit lasts a few minutes and most patients are free to go about their daily business before and after each treatment session. Early data indicates that FSR may result in better hearing preservation when compared to single-session SRS. | ||
===Proton beam therapy=== | ===Proton beam therapy=== | ||
The use of proton beam therapy permits the delivery of high doses of radiotherapy to the target volume while limiting the dose received by surrounding tissues. It provides maximum local tumor control with minimum [[cranial nerve]] injuries. | The use of proton beam therapy permits the delivery of high doses of radiotherapy to the target volume while limiting the dose received by surrounding tissues. It provides maximum local tumor control with minimum [[cranial nerve]] injuries. | ||
Follow-up after SRS and FSR typically involves an MRI scan and audiogram at six months, one year, then yearly for several years, then every second or third year indefinitely to make sure the tumor does not start to grow again. All types of radiation therapy for acoustic neuromas may result in "tumor control" in which the tumor cells die and necrosis occurs. Tumor control means that the tumor growth may slow or stop and, in some cases, the tumor may shrink in size. These techniques are performed in the outpatient setting, not requiring general [[anesthesia]] or a hospital stay. The purpose of these techniques is to arrest the growth of the [[tumor]] causing the tumor to die, which is called [[necrosis]]. This treatment has not been well studied and thus it is unclear if it is better than observation or [[surgery]]. Tumors under 2.5 - 3.0 cm, without significant involvement of the [[brainstem]], are more favorable for radiation treatment. Side effects can occur when the brainstem is irradiated and in some cases of large tumors, radiation is contraindicated. Studies are beginning to appear for the other modalities. All of the techniques use computers to create three dimensional models of the tumor and surrounding neural structures. Radiation physicists then create dosimetry maps showing the level of radiation to be received by the tumor and the normal [[tissues]]. Surgeons, radiation therapists and physicists then modify the dosimetry to maximize tumor doses and minimize radiation toxicity to surrounding normal tissues. The head is stabilized with a metal frame pinned to the [[head]] (Gamma Knife) or a fitted mask shield (CyberKnife, linear accelerator, fractionated XRT). Treatments generally last 30–60 minutes. Just like for surgery, the experience of the team in treating acoustic neuromas with all modalities (surgery and radiation) can affect outcomes. There are a multitude of studies supporting short-term (<5 yrs.) and longer-term (over 10 yrs.) tumor control with radiation. Unfortunately, as is the case with microsurgical studies, most have inconsistent follow-up to draw definitive conclusions. | Follow-up after SRS and FSR typically involves an MRI scan and audiogram at six months, one year, then yearly for several years, then every second or third year indefinitely to make sure the tumor does not start to grow again. All types of radiation therapy for acoustic neuromas may result in "tumor control" in which the tumor [[cells]] die and [[necrosis]] occurs. Tumor control means that the tumor growth may slow or stop and, in some cases, the tumor may shrink in size. These techniques are performed in the outpatient setting, not requiring general [[anesthesia]] or a hospital stay. The purpose of these techniques is to arrest the growth of the [[tumor]] causing the tumor to die, which is called [[necrosis]]. This treatment has not been well studied and thus it is unclear if it is better than observation or [[surgery]]. Tumors under 2.5 - 3.0 cm, without significant involvement of the [[brainstem]], are more favorable for radiation treatment. Side effects can occur when the brainstem is irradiated and in some cases of large tumors, radiation is contraindicated. Studies are beginning to appear for the other modalities. All of the techniques use computers to create three dimensional models of the tumor and surrounding neural structures. Radiation physicists then create dosimetry maps showing the level of radiation to be received by the tumor and the normal [[tissues]]. Surgeons, radiation therapists and physicists then modify the dosimetry to maximize tumor doses and minimize radiation toxicity to surrounding normal tissues. The head is stabilized with a metal frame pinned to the [[head]] ([[Gamma Knife]]) or a fitted mask shield (CyberKnife, linear accelerator, fractionated XRT). Treatments generally last 30–60 minutes. Just like for surgery, the experience of the team in treating acoustic neuromas with all modalities (surgery and radiation) can affect outcomes. There are a multitude of studies supporting short-term (<5 yrs.) and longer-term (over 10 yrs.) tumor control with radiation. Unfortunately, as is the case with microsurgical studies, most have inconsistent follow-up to draw definitive conclusions. | ||
Line 67: | Line 67: | ||
*Unknown incidence of secondary malignancies. | *Unknown incidence of secondary malignancies. | ||
*Long-term balance dysfunction. | *Long-term balance dysfunction. | ||
==References== | ==References== | ||
Line 93: | Line 73: | ||
{{WH}} | {{WH}} | ||
{{WS}} | {{WS}} | ||
[[Category:PNS neoplasia]] | |||
[[Category:Types of cancer]] | |||
[[Category:Disease]] |
Revision as of 18:46, 23 September 2015
Acoustic neuroma Microchapters | |
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Case Studies | |
Acoustic neuroma medical therapy On the Web | |
American Roentgen Ray Society Images of Acoustic neuroma medical therapy | |
Risk calculators and risk factors for Acoustic neuroma medical therapy | |
Editor-In-Chief: C. Michael Gibson, M.S., M.D. [1]Associate Editor(s)-in-Chief: Simrat Sarai, M.D. [2]
Overview
Optimal therapy for acoustic neuroma includes observation, surgery, and radiation therapy.[1]
Medical Therapy
There are three main courses of treatment for acoustic neuroma:
- Observation
- Surgery
- Radiation therapy
The number of factors that decide selecting the right treatment include:
- Age
- Other medical conditions
- Severity of the symptoms
- Size of the tumor
- Tumor growth
Observation
Since acoustic neuromas tend to be slow-growing and are benign tumors, careful observation over a period of time may be appropriate for some patients.The patient is observed for facial nerve function, hearing, tinnitus and ataxia. An MRI is performed every 6 months or yearly depending on the rate of tumor growth. The average growth rate of tumor is 1.15 to 2.4 mm per year. If the tumor grows or causes serious symptoms, treatment is suggested. If the scans show the tumor is growing or if the tumor causes progressive symptoms or other difficulties, you may need to undergo treatment. Observation is recommended in the following patients:[2]
- Patients with a tumor in their only hearing or better hearing ear.
- When the tumor is of a size that hearing preservation with treatment would be unlikely.
- Elderly patients.
- Small tumors in older individuals that do not grow.
- Patients with small tumors with good hearing.
- Patients with medical conditions that increase the risk of surgery.
- Patients who refuse treatment.
- Patients with a tumor on the side of an only hearing ear or only seeing eye.
Radiation Therapy
Another treatment option for an acoustic neuroma is radiation. Radiation therapy approaches that have been used in patients with acoustic neuroma include:[3]
- Stereotactic radiosurgery
- Stereotactic radiotherapy
- Proton beam therapy
- Conventional fractionated radiation therapy
Stereotactic Radiosurgery
In single dose treatments, many hundreds of small beams of radiation are aimed at the tumor. This results in a high dose of radiation to the tumor and very little to any surrounding brain structures. Many patients have been treated this way with high success rates. Facial weakness or numbness, in the hands of experienced radiation physicians, occurs in only a small percent of cases. This can be performed with either the linear accelerator or gamma knife. Radiosurgery is a treatment option for patients with smaller tumors (<3 cm) or for patients with enlarging tumors who are not candidates for surgery.
- Complications of stereotactic radiosurgery include:
Stereotactic Radiotherapy
The multi-dose treatment, FSR, delivers smaller doses of radiation over a period of time, requiring the patient to return to the treatment location on a daily basis, from 3 to 30 times, generally over several weeks. Each visit lasts a few minutes and most patients are free to go about their daily business before and after each treatment session. Early data indicates that FSR may result in better hearing preservation when compared to single-session SRS.
Proton beam therapy
The use of proton beam therapy permits the delivery of high doses of radiotherapy to the target volume while limiting the dose received by surrounding tissues. It provides maximum local tumor control with minimum cranial nerve injuries.
Follow-up after SRS and FSR typically involves an MRI scan and audiogram at six months, one year, then yearly for several years, then every second or third year indefinitely to make sure the tumor does not start to grow again. All types of radiation therapy for acoustic neuromas may result in "tumor control" in which the tumor cells die and necrosis occurs. Tumor control means that the tumor growth may slow or stop and, in some cases, the tumor may shrink in size. These techniques are performed in the outpatient setting, not requiring general anesthesia or a hospital stay. The purpose of these techniques is to arrest the growth of the tumor causing the tumor to die, which is called necrosis. This treatment has not been well studied and thus it is unclear if it is better than observation or surgery. Tumors under 2.5 - 3.0 cm, without significant involvement of the brainstem, are more favorable for radiation treatment. Side effects can occur when the brainstem is irradiated and in some cases of large tumors, radiation is contraindicated. Studies are beginning to appear for the other modalities. All of the techniques use computers to create three dimensional models of the tumor and surrounding neural structures. Radiation physicists then create dosimetry maps showing the level of radiation to be received by the tumor and the normal tissues. Surgeons, radiation therapists and physicists then modify the dosimetry to maximize tumor doses and minimize radiation toxicity to surrounding normal tissues. The head is stabilized with a metal frame pinned to the head (Gamma Knife) or a fitted mask shield (CyberKnife, linear accelerator, fractionated XRT). Treatments generally last 30–60 minutes. Just like for surgery, the experience of the team in treating acoustic neuromas with all modalities (surgery and radiation) can affect outcomes. There are a multitude of studies supporting short-term (<5 yrs.) and longer-term (over 10 yrs.) tumor control with radiation. Unfortunately, as is the case with microsurgical studies, most have inconsistent follow-up to draw definitive conclusions.
Several types of machines deliver focused radiation treatment suitable for treating acoustic neuromas. The underlying premise is to treat the tumor with a high dose of radiation while sparing the nerves and brain tissues. Much of the long term data comes from the Gamma Knife literature since this was one of the earliest techniques used to radiate acoustic neuromas on a large scale. The machines suitable for treating acoustic neuroma include:
- Gamma Knife
- The Gamma Knife uses 195-201 fixed cobalt-60 radiation sources that are "collimated" to intersect at the site of the tumor and is a single dose treatment. In this way, each individual beam of radiation has very little effect, but where they all intersect produces a maximum effect on the tumor. Very similar results can be obtained using a linear accelerator (LINAC) as the radiation source, such as with the Novalis or CyberKnife with multi-dose treatment.
- Linear accelerator (LINAC)
- CyberKnife
- Novalis
- Trilogy
Advantages of radiation therapy
- Decreased length of stay.
- Decreased cost.
- Low immediate posttreatment, morbidity and mortality.
Disadvantages of Radiation therapy
- In almost no cases have acoustic neuroma tumors been completely eliminated by radiation treatments. Radiation does not remove the tumor like microsurgery can.
- Radiotherapy patients require lifetime follow-up with MRI scans.
- Rare reports of malignant degeneration (a benign tumor becoming malignant) after radiotherapy have been found.
- In some cases the tumor does not die and continues to grow. In those instances, another treatment is necessary - either microsurgery or sometimes another dose of radiation.
- Higher incidence of trigeminal nerve injury.
- Unknown incidence of secondary malignancies.
- Long-term balance dysfunction.