Large Intracranial Arteriovenous Malformations Research Articles

Volume Fractionation Stereotactic Radiosurgery for Large Volume Intracranial Arteriovenous Malformations.

Arteriovenous malformations (AVMs) are common intracranial vascular anomalies. Common treatment modalities used to manage AVMs are surgical excision, embolization, and stereotactic radiosurgery (SRS). Large AVMs are defined as AVMs larger than 10 cm3 and pose a therapeutic challenge with high rates of treatment-related morbidity and mortality. Single-stage SRS is a good option for small AVMs but carries high risks of radiation-induced complications in large AVMs. Volume-staged SRS (VS-SRS) is a newer strategy used in large AVMs that allows one to deliver an optimal radiation dose to the AVMs while reducing the risk of radiation damage to the normal brain. It involves the division of AVM into multiple small sectors which are irradiated at different time intervals with high radiation doses. Good obliteration rates with less risk of radiation-induced complications have been described in the literature with VS-SRS.

Multistage stereotactic radiosurgery for large cerebral arteriovenous malformations using the Gamma Knife platform.

Radiosurgery is an established technique to treat cerebral arteriovenous malformations (AVMs). Obliteration of larger AVMs (> 10-15 cm3 or diameter > 3 cm) in a single session is challenging with current radiosurgery platforms due to toxicity. We present a novel technique of multistage stereotactic radiosurgery (SRS) for large intracranial arteriovenous malformations (AVM) using the Gamma Knife system. Eighteen patients with large (> 10-15 cm3 or diameter > 3 cm) AVMs, which were previously treated using a staged SRS technique on the Cyberknife platform, were retrospectively selected for this study. The AVMs were contoured and divided into 3-8 subtargets to be treated sequentially in a staged approach at half to 4 week intervals. The prescription dose ranged from 15 Gy to 20 Gy, depending on the subtarget number, volume, and location. Gamma Knife plans using multiple collimator settings were generated and optimized. The coordinates of each shot from the initial plan covering the total AVM target were extracted based on their relative positions within the frame system. The shots were regrouped based on their location with respect to the subtarget contours to generate subplans for each stage. The delivery time of each shot for a subtarget was decay corrected with 60 Co for staging the treatment course to generate the same dose distribution as that planned for the total AVM target. Conformality indices and dose-volume analysis were performed to evaluate treatment plans. With the shot redistribution technique, the composite dose for the multistaged treatment of multiple subtargets is equivalent to the initial plan for total AVM target. Gamma Knife plans resulted in an average PTV coverage of 96.3 ± 0.9% and a PITV of 1.23 ± 0.1. The resulting Conformality indices, V12Gy and R50 dose spillage values were 0.76 ± 0.05, 3.4 ± 1.8, and 3.1 ± 0.5 respectively. The Gamma Knife system can deliver a multistaged conformal dose to treat large AVMs when correcting for translational setup errors of each shot at each staged treatment.

Volume-Staged Stereotactic Radiosurgery for Intracranial Arteriovenous Malformations: Outcomes Based on an 18-Year Experience.

Radiation-based treatment options of large intracranial arteriovenous malformations (AVM) must balance the likelihood of obliteration with the risk of adverse radiation effects (ARE). To analyze the efficacy and risks of volume-staged stereotactic radiosurgery (VS-SRS) for AVM. Retrospective study of 34 AVM patients having VS-SRS between 1997 and 2012. A median of 2 stages (range, 2-4) was used to treat a median AVM volume of 22.2 cm 3 (range, 7.4-56.7). The median AVM margin dose was 16 Gy (range, 14-18); the median radiosurgery-based AVM score was 2.81 (range, 1.54-6.45). The median follow-up after VS-SRS was 8.2 years (range, 3-13.3). Nidus obliteration was noted in 18 patients (53%) after VS-SRS. The rate of obliteration was 14% at 3 years, 54% at 5 years, and 75% at 7 years. Six patients (18%) had 11 bleeds after VS-SRS. Two patients (6%) remained neurologically stable, 2 (6%) patients had significant deficits, and 2 patients (6%) died. The actuarial risk of a first bleed after VS-SRS was 6% at 1 year, 12% at 3 years, and 19% at 7 years. Six patients (18%) underwent repeat SRS; all achieved nidus obliteration for an overall cure rate of 71%. Two patients (6%) had a permanent ARE after VS-SRS or repeat SRS. VS-SRS permitted large volume intracranial AVM to be treated with a low rate of ARE. Further study is needed on dose escalation and decreasing the treatment volume per stage to determine if this will increase the rate of obliteration with this technique.

SU‐E‐T‐251: Novel Multi‐Stage Stereotactic Radiosurgery Technique for Large Cerebral Arteriovenous Malformations Using the Gammaknife System

Purpose:To develop a multi‐stage stereotactic radiosurgery delivery technique for large intracranial arteriovenous malformations (AVM) using the Gammaknife treatment platform.Methods:Eleven patients having large (>15 cm3) cerebral AVMs were selected for this study. AVMs were contoured and divided into 3‐8 subtargets with volumes ranging from 3–7 cm3. Each subtarget is to be treated sequentially in 1–4 week intervals between stages. The prescription dose was 16–20 Gy depending on the target volume. Gammaknife plans were retrospectively generated to treat the entire AVM target with a simulated Extend frame system that can reposition patients within a 1mm accuracy. The coordinates of each shot from the initial plan were extracted based on the shot position within the Extend frame system. Shots were then grouped based on their relative position to individual subtarget contours to generate stage‐specific plans. The delivery time of each shot of a subtarget was corrected for decay of each stage to generate the same dose distribution as that of the original plan for the entire AVM. Conformality and dose‐volume analysis was performed to evaluate the PITV (ratio of prescription isodose volume to target volume), R50 (ratio of 50% isodose volume to target volume), and V12Gy (percentage of brain volume receiving 12Gy or greater).Results:The total accumulated dose for the multi‐staged treatments was shown to be equivalent to the initial plan of the entire AVM target. The Gammaknife plans resulted in an average of 95.8%±0.6 PTV coverage with a PITV of 1.06±0.07. The resulting V12Gy and R50 dose spillage values were 4.2%±2.0 and 3.2±0.4, respectively.Conclusion:With the Extend frame, the Gammaknife system can deliver a multi‐staged conformal dose to treat large AVMs. Target dose coverage and conformality as well as normal brain toxicity measures were shown to be similar compared to that of a single fraction treatment.

Reset osmostat in pregnancy: a case report

The reset osmostat syndrome, a form of inappropriate antidiuretic hormone secretion (SIADH), occurs when the threshold for antidiuretic hormone secretion is moved downward. There is evidence to suggest a “reset osmostat phenomenon” in normal pregnancies, whereby the average plasma-osmolality is decreased by 5–10 mOsm/kg. We present a case of a non-physiologic reset osmostat in a pregnant patient, thought to be caused by large intracranial arteriovenous malformations and intraventricular hemorrhage. The presence of a reset osmostat should be suspected in any patient with apparent SIADH who has mild hyponatremia that is stable over many days despite variations in sodium and water intake. Therapeutic efforts to raise the serum sodium concentration appear to be unnecessary.

Clinical and radiobiological advantages of single-dose stereotactic light-ion radiation therapy for large intracranial arteriovenous malformations

Radiation treatment of large arteriovenous malformations (AVMs) remains difficult and not very effective, even though seemingly promising methods such as staged volume treatments have been proposed by some radiation treatment centers. In symptomatic patients harboring large intracranial AVMs not amenable to embolization or resection, single-session high-dose stereotactic radiation therapy is a viable option, and the special characteristics of high-ionization-density light-ion beams offer several treatment advantages over photon and proton beams. These advantages include a more favorable depth-dose distribution in tissue, an almost negligible lateral scatter of the beam, a sharper penumbra, a steep dose falloff beyond the Bragg peak, and a higher probability of vascular response due to high ionization density and associated induction of endothelial cell proliferation and/or apoptosis. Carbon ions were recently shown to be an effective treatment for skull-base tumors. Bearing that in mind, the authors postulate that the unique physical and biological characteristics of light-ion beams should convey considerable clinical advantages in the treatment of large AVMs. In the present meta-analysis the authors present a comparison between light-ion beam therapy and more conventional modalities of radiation treatment with respect to these lesions. Dose-volume histograms and data on peripheral radiation doses for treatment of large AVMs were collected from various radiation treatment centers. Dose-response parameters were then derived by applying a maximum likelihood fitting of a binomial model to these data. The present binomial model was needed because the effective number of crucial blood vessels in AVMs (the number of vessels that must be obliterated to effect a cure, such as large fistulous nidus vessels) is low, making the Poisson model less suitable. In this study the authors also focused on radiobiological differences between various radiation treatments. Light-ion Bragg-peak dose delivery has the precision required for treating very large AVMs as well as for delivering extremely sharp, focused beams to irregular lesions. Stereotactic light-ion radiosurgery resulted in better angiographically defined obliteration rates, less white-matter necrosis, lower complication rates, and more favorable clinical outcomes. In addition, in patients treated by He ion beams, a sharper dose-response gradient was observed, probably due to a more homogeneous radiosensitivity of the AVM nidus to light-ion beam radiation than that seen when low-ionization-density radiation modalities, such as photons and protons, are used. Bragg-peak radiosurgery can be recommended for most large and irregular AVMs and for the treatment of lesions located in front of or adjacent to sensitive and functionally important brain structures. The unique physical and biological characteristics of light-ion beams are of considerable advantage for the treatment of AVMs: the densely ionizing beams of light ions create a better dose and biological effect distribution than conventional radiation modalities such as photons and protons. Using light ions, greater flexibility can be achieved while avoiding healthy critical structures such as diencephalic and brainstem nuclei and tracts. Treatment with the light ion He or Li is more suitable for AVMs <or= 10 cm(3), whereas treatment with the light ion Li, Be, or C may be more appropriate for larger AVMs. A binomial model based on the effective number of crucial vessels in the AVM may be used quite well to predict AVM obliteration probabilities for both small and large AVMs when therapies involving either photons or light ions are used.

SU-FF-T-661: Investigating the Benefits of Stereotactic Light Ion Radiation Therapy for Treating Large Intracranial AVMs

Purpose The majority of complications occur in patients with large AVM volumes being treated with high doses. For large intracranial arteriovenous malformations, the special characteristics of high ionization density light ion beams offer several advantages over photon and proton beams for high dose stereotactic radiation therapy. These include a better depth dose‐distribution in tissue, negligible lateral scattering, a sharper penumbra, a steep dose fall‐off beyond the Bragg peak and a higher probability of vascular response. Material and Methods Peripheral doses and dose volume histograms (DVHs) of large AVMs were collected from different centers. Based on these data and using a maximum likelihood fitting, dose‐response parameters were derived for the Binomial model. A comparison was performed for different radiation modalities taking also into account their radiobiological differences. Results Light ion Bragg peak dose delivery has the precision required for treating very large AVMs, as well as for delivering extremely sharp focused beams to irregular lesions. For stereotactic radiosurgery with light ions, a better angiographic obliteration rate was observed. Furthermore, a lower complication rate and lower white matter necrosis was simultaneously achieved, which composed a more favorable overall clinical outcome. In patients treated by helium ion beams, a sharper dose‐response gradient was observed, which is probably related to a more homogenous radiosensitivity of the AVM nidus to ion beamradiation.Conclusion Based on this study of linear energy transfer of different therapeuticion beams19 (H, He, Li, C), Helium or Lithium ions may be most suitable for AVM's up to 10 cm3 and for larger AVMs Lithium to carbon ions may be more appropriate. The unique physical characteristics of light ion beams are of considerable advantage for the treatment of AVMs located in front of or adjacent to sensitive and functionally important brain structures.

Radiosurgical Considerations in the Treatment of Large Cerebral Arteriovenous Malformations

In order to establish the role of Gamma Knife radiosurgery (GKS) in large intracranial arteriovenous malformations (AVMs), we analyzed clinical characteristics, radiological features, and radiosurgical outcomes. Between March 1992 and March 2005, 28 of 33 patients with large AVMs (> 10 cm(3) in nidus-volume) who were treated with GKS underwent single session radiosurgery (RS), and the other 5 patients underwent staged volumetric RS. Retrospectively collected data were available in 23 cases. We analyzed treatment outcomes in each subdivided groups and according to the AVM sizes. We compared the estimated volume, defined as primarily estimated nidus volume using MR images, with real target volume after excluding draining veins and feeding arteries embedded into the nidus. Regarding those patients who underwent single session RS, 44.4% (8/18) had complete obliteration; regarding staged volumetric RS, the obliteration rate was 40% (2/5). The complete obliteration rate was 60% (6/10) in the smaller nidus group (10-15 cm(3) size), and 25% (2/8) in the larger nidus group (over 15 cm(3) size). One case of cerebral edema and two cases (8.7%) of hemorrhage were seen during the latent period. The mean real target volume for 18 single sessions of RS was 17.1 cm(3) (10.1-38.4 cm(3)), in contrast with the mean estimated volume of 20.9 cm(3) (12.0-45.0 cm(3)). The radiosurgical treatment outcomes of large AVMs are generally poor. However, we presume that the recent development in planning software and imaging devices aid more accurate measurement of the nidus volume, therefore improving the treatment outcome.

Fractionated stereotactic radiosurgery of a large intracranial arteriovenous malformation (AVM) – A case report

Fractionated stereotactic radiosurgery of a large intracranial arteriovenous malformation (AVM) – A case report

Repeat stereotactic radiosurgery for high-grade and large intracranial arteriovenous malformations

Background The treatment of large and high-grade (Spetzler-Martin III-V) AVMs remains a challenge. There is a paucity of literature addressing the efficacy of radiosurgery in this group. We retrospectively analyze our experience with repeat radiosurgery with such AVMs. Methods Between 1989 and 2004, 14 patients with large and high-grade AVMs deemed to be nonoperative candidates were treated with repeat radiosurgery. Patients were treated either on a LINAC or γ knife–based system at 2- to 3-year intervals with targeting of the entire nidus with each treatment. Patients who did not receive their full treatment course or follow-up at the institution were excluded. Results Mean follow-up was 18 months. The complete obliteration rate was 35.7%, with a mean volume reduction of 53% in the remaining lesions. Twenty percent of grade III and 50% of grade IV lesions experienced cure. Complications included persistent headaches (2 patients). Statistical analysis revealed no difference between obliterated and partially obliterated groups with regard to mean pretreatment volume (24.87 cm 3), median Spetzler-Martin grade (IV), mean follow-up (30.5 months), total delivered dose (3550 cGy), mean dose per stage (13 Gy), median number of stages (2), or mean interval between treatment stages (40 months). Conclusion The present study demonstrates the potential role of repeat radiosurgery in the treatment of this cohort in the context of our short follow-up. The benefits of repeat therapy could be derived from using lower doses per session and repeat targeting of the lesion in an effort to increase response and decrease complication rates.

Repeated Stereotactic Radiosurgery Can Result in Complete Obliteration for Large Intracranial Arteriovenous Malformations

Repeated Stereotactic Radiosurgery Can Result in Complete Obliteration for Large Intracranial Arteriovenous Malformations

Stereotactic proton beam therapy for intracranial arteriovenous malformations

To investigate hypofractionated stereotactic proton therapy of predominantly large intracranial arteriovenous malformations (AVMs) by analyzing retrospectively the results from a cohort of patients. Since 1993, a total of 85 patients with vascular lesions have been treated. Of those, 64 patients fulfilled the criteria of having an arteriovenous malformation and sufficient follow-up. The AVMs were grouped by volume: <14 cc (26 patients) and > or =14 cc (38 patients). Treatment was delivered with a fixed horizontal 200 MeV proton beam under stereotactic conditions, using a stereophotogrammetric positioning system. The majority of patients were hypofractionated (2 or 3 fractions), and the proton doses are presented as single-fraction equivalent cobalt Gray equivalent doses (SFEcGyE). The overall mean minimum target volume dose was 17.37 SFEcGyE, ranging from 10.38-22.05 SFEcGyE. Analysis by volume group showed obliteration in 67% for volumes <14 cc and 43% for volumes > or =14 cc. Grade IV acute complications were observed in 3% of patients. Transient delayed effects were seen in 15 patients (23%), becoming permanent in 3 patients. One patient also developed a cyst 8 years after therapy. Stereotactic proton beam therapy applied in a hypofractionated schedule allows for the safe treatment of large AVMs, with acceptable results. It is an alternative to other treatment strategies for large AVMs. AVMs are likely not static entities, but probably undergo vascular remodeling. Factors influencing angiogenesis could play a new role in a form of adjuvant therapy to improve on the radiosurgical results.

Hyperperfusion encephalopathies: hypertensive encephalopathy and related conditions.

Hypertensive encephalopathy (HTE) is a syndrome typified by headache, seizures, and neurologic signs associated with increased systemic blood pressures; edema in the subcortical white matter is seen on imaging studies and is usually reversible, although infarction or hemorrhage may supervene. Based on previous work, we theorize that HTE is associated with increased perfusion to the brain. Syndromes related to HTE may also be encountered in clinical situations in which perfusion to the brain is acutely increased without systemic hypertension (i.e., after treatment of high-grade carotid stenoses or large intracranial arteriovenous malformations, or in high altitude mountain sickness). We therefore refer to these conditions more generally as hyperperfusion encephalopathies (HPE). The clinical and radiographic data of 110 patients (average age, 50.1 years) who presented at the Brigham and Women's Hospital with clinical and radiographic signs of HPE were reviewed; 104 had systemic hypertension and 6 had postcarotid endarterectomy hyperperfusion syndrome. Edema involved the subcortical white matter and occasionally the cortex in all patients. In patients with systemic hypertension, the edema was usually bilateral and located predominantly in the occipital lobes; other brain regions included the parietal lobes, posterior frontal lobes, cerebellum, and splenium of the corpus callosum. The six patients with postcarotid endarterectomy hyperperfusion syndrome had edema in the hemisphere ipsilateral to the operated side involving the anterior and middle cerebral artery territories. The edema in HPE was associated with: increased low attenuation on CT; decreased T(1) and increased T(2) signal on MR imaging; increased cerebral perfusion on single emission computed tomography (SPECT) and perfusion MR imaging;did not show restricted diffusion on MR imaging. The syndrome resolved completely in most cases after the administration of antihypertensive agents, although rarely small infarcts and hemorrhages occurred. Three patients with thrombocytopenia developed large fatal intracranial hemorrhages. The symptoms of HPE are usually nonspecific, but the radiographic findings are consistent. Treatment should be instituted rapidly and patients should be followed until the condition resolves either clinically or radiographically; hemorrhagic complications, although rare, can be serious.

Jugular venous bulb oxygen saturation monitoring in arteriovenous malformation surgery.

We describe a case in which jugular venous bulb oxygen saturation (SjvO2) monitoring proved useful during the surgical resection of an intracranial arteriovenous malformation (AVM). Surgical resection of large intracranial AVMs may be followed by normal perfusion pressure breakthrough with brain swelling, hyperemia, and subsequent problems in achieving hemostasis. SjvO2 monitoring during AVM embolization by interventional radiology has been shown to help in deciding whether embolization is sufficient to avoid such postresection hyperemia, but its use during surgical resection has not been described. In the case discussed, SjvO2 monitoring enabled assessment of the risk of postresection hyperemia preoperatively and permitted the degree and completeness of surgical AVM resection to be followed intraoperatively. During the normal perfusion pressure breakthrough bleeding which followed complete AVM resection, SjvO2 monitoring helped with safe management of the controlled hypotension that finally permitted hemostasis to be achieved.

Computed tomography slice-by-slice target-volume delineation for stereotactic proton irradiation of large intracranial arteriovenous malformations: an iterative approach using angiography, computed tomography, and magnetic resonance imaging

: Target-volume delineation for stereotactic irradiation is problematic for large and irregularly shaped arteriovenous malformations (AVMs). The purpose of this report is to quantify modifications in the target volume hat result from iterative treatment planning that incorporates multimodality imaging data. : Stereotactic neuroimaging procedures were performed for 20 consecutive patients with AVM volumes > 10 cm3. Angiographically defined extrema were transformed into computed tomography (CT) space. The resulting target contours were then modified by a multidisciplinary treatment planning team after iterative review of angiographic, CT, and magnetic resonance imaging (MRI) data. Volumes of interest and dose-volume histograms for proton irradiation were calculated before and after iterative target delineation. : Initial (angiographically defined) target volumes ranged from 15.3 to 96.1 cm3 (mean, 43.6 cm3). Final (iteratively defined) target volumes ranged from 10.7 to 114.0 cm3 (mean, 38.4 cm3). The volume of presumed normal tissue excluded by iterative planning ranged from 2.6 to 47.0 cm3 (mean, 15.5 cm3). Initially untargeted AVM, most commonly obscured by embolization material, was identified in all cases (range, 0.3 to 57.8 cm3; mean, 10.3 cm3). Corresponding dose-volume histograms demonstrated marked differences regarding lesion coverage and sparing of normal tissue structures. : Iterative target-volume delineation resulted in significant modifications from initial, angiographically defined target volumes. Substantial amounts of apparently normal tissue were excluded from the final target, and additional abnormal vascular structures were identified for incorporation. We conclude that an iterative multimodality approach to target-volume delineation may improve the overall results for stereostatic irradiation of large and complex AVMs.

Computed tomography slice-by-slice target-volume delineation for stereotactic proton irradiation of large intracranial arteriovenous malformations: An iterative approach using angiography, computed tomography, and magnetic resonance imaging

Purpose : Target-volume delineation for stereotactic irradiation is problematic for large and irregularly shaped arteriovenous malformations (AVMs). The purpose of this report is to quantify modifications in the target volume hat result from iterative treatment planning that incorporates multimodality imaging data. Methods and Materials : Stereotactic neuroimaging procedures were performed for 20 consecutive patients with AVM volumes > 10 cm 3. Angiographically defined extrema were transformed into computed tomography (CT) space. The resulting target contours were then modified by a multidisciplinary treatment planning team after iterative review of angiographic, CT, and magnetic resonance imaging (MRI) data. Volumes of interest and dose-volume histograms for proton irradiation were calculated before and after iterative target delineation. Results : Initial (angiographically defined) target volumes ranged from 15.3 to 96.1 cm 3 (mean, 43.6 cm 3). Final (iteratively defined) target volumes ranged from 10.7 to 114.0 cm 3 (mean, 38.4 cm 3). The volume of presumed normal tissue excluded by iterative planning ranged from 2.6 to 47.0 cm 3 (mean, 15.5 cm 3). Initially untargeted AVM, most commonly obscured by embolization material, was identified in all cases (range, 0.3 to 57.8 cm 3; mean, 10.3 cm 3). Corresponding dose-volume histograms demonstrated marked differences regarding lesion coverage and sparing of normal tissue structures. Conclusions : Iterative target-volume delineation resulted in significant modifications from initial, angiographically defined target volumes. Substantial amounts of apparently normal tissue were excluded from the final target, and additional abnormal vascular structures were identified for incorporation. We conclude that an iterative multimodality approach to target-volume delineation may improve the overall results for stereostatic irradiation of large and complex AVMs.

The role of high-dose, single-fraction irradiation in small and large intracranial arteriovenous malformations

Purpose : Radiosurgery with external beam irradiation is an accepted treatment for small intracranial vascular malformations. It has been proven effective and safe for lesions with volumes of less than 4 cc. However, there is only some limited clinical data for malformations of grade 4 and grade 5, according to Spetzler and Martin. Methods and Materials : At the Heidelberg radiosurgery facility equipped with a linear accelerator, 212 patients with cerebral arteriovenous malformations have been treated since 1984. Thirty-eight percent of the arteriovenous malformations treated were classified inoperable, 14% grade 5, 19% grade 4, and 29% grades 1–3. Radiation doses between 10 and 29 Gy were applied to the 80% isodose contour. Results : Above a threshold dose of 18 Gy, the overall obliteration rate was 72%. After 3 years, the obliteration rates were 83% with volumes of less than 4.2 cc, 75% with volumes of up to 33.5 cc, and 50% with volumes of up to 113 cc. Of the patients presenting with seizures and paresis, 83% and 56%, respectively, showed improvement, which correlated with the degree of obliteration. After a follow-up period of up to 9 years, the rate of radiation-induced severe late complications was 4.3%. In grade 5 lesions, the risk of side effects was 10%. No serious complications occurred if a maximum dose of less than 25 Gy was applied to treatment volumes of less than 33.5 cc. Conclusion : The success of stereotactic high-dose irradiation of arteriovenous malformations depends on the dose applied. The incidence of radiation-induced side effects increased with the applied dose and treatment volumes. From our experience, doses of less than 25 Gy and treatment volumes of up to 33.5 cc are safe and effective. In the future, new techniques of radiosurgery with linear accelerators and dynamically reshaped beams will allow us to apply homogenous dose distributions. Additional use of magnetic resonance angiography for 3D treatment planning will help to identify the nidus more easily.

Is there a place for high single dose irradiation in large intracranial arteriovenous malformations?

Is there a place for high single dose irradiation in large intracranial arteriovenous malformations?

Intracranial arteriovenous malformation masquerading as a cardiac disorder

In this report, we describe an adult with a large intracranial arteriovenous malformation which mimicked a cardiac lesion. The patient presented with predominant cardiac symptoms, a prominent continuous murmur and signs of arterial run-off. The diagnosis was confirmed by digital subtraction angiography. We report the case to highlight the rare presentation.

Two-Dimensional and Doppler Evaluation of the Infant with a Large Intracranial Arteriovenous Malformation

Two-Dimensional and Doppler Evaluation of the Infant with a Large Intracranial Arteriovenous Malformation