Daniel Umansky1,2, Benjamin W Corn2,3, Ido Strauss1,2,4, Natan Shtraus4,5, Shlomi Constantini2,6, Vladimir Frolov7, Shimon Maimon7, Andrew A Kanner8,9,10. 1. Department of Neurosurgery, Tel Aviv Sourasky Medical Center, Tel Aviv, Israel. 2. Tel Aviv University, Sackler School of Medicine, Tel Aviv, Israel. 3. Department of Oncology, Shaare Zedek Medical Center, Jerusalem, Israel. 4. Stereotactic Radiosurgery Unit, Tel Aviv Sourasky Medical Center, Tel Aviv, Israel. 5. Institute of Radiotherapy, Tel Aviv Sourasky Medical Center, Tel Aviv, Israel. 6. Department of Pediatric Neurosurgery, Tel Aviv Sourasky Medical Center, Tel Aviv, Israel. 7. Invasive Endovascular Treatment Unit, Tel Aviv Sourasky Medical Center, Tel Aviv, Israel. 8. Tel Aviv University, Sackler School of Medicine, Tel Aviv, Israel. andrewka@clalit.org.il. 9. Stereotactic Radiosurgery Unit, Tel Aviv Sourasky Medical Center, Tel Aviv, Israel. andrewka@clalit.org.il. 10. Department of Neurosurgery, Rabin Medical Center, Petach Tikva, Israel. andrewka@clalit.org.il.
Abstract
PURPOSE: Treatment of cerebral arteriovenous malformations (AVM)-the most common cause of stroke in the pediatric population-can be challenging due to the complexity of size, morphology, and location. There is a significant risk in comparison to AVM treatment among adults. Thus, AVM treatment in the pediatric population imposes unique challenges. Recent improvements include optimized catheter techniques and better embolization materials, such as Onyx, a non-adhesive liquid embolic agent used in the adult population. These improvements have increased the success rate of total and near-total obliteration of cerebral AVM. However, the use of Onyx causes significant distortion of the MR and CT images, which must be accounted for in any radiation treatment planning predicated on CT and MRI. These image distortions impact on the actual delivered dose to the nidus and behoove heterogeneity correction. Our group has previously shared a solution for heterogeneity correction in the adult population. The purpose of this study is to show our experience in this unique group of pediatric patients. METHODS: This is a retrospective review of pediatric patients, who were undergoing combined endovascular embolization followed by SRS. The cohort consists of 14 patients undergoing SRS treatment in our institute between November 2006 and December 2012 with a mean follow-up of 49.9 months. Within this cohort, we retrospectively reviewed 12 consecutive pediatric patients who underwent a combined endovascular and SRS approach with a mean follow-up of 52.1 months and two patients receiving SRS-only treatment were excluded. RESULTS: In our cohort of 14 patients, 7 (50%) were male, with a mean age of 17.3 years (12.0-22.9) at the time of radiosurgery treatment. Mean age of beginning the combined modality treatment was 15.3 years (8.4-20). The median time from diagnosis to SRS was 24.3 months (11.1-64.4 months) in the complete cohort and 25.6 months (11.1-64.4) in the multimodality group. The overall median follow-up period was 49.9 months (range 12.8-118.8 months) in the complete cohort and 52.1 months (range 12.8-118.8 months) in the multimodality group. Eleven (78.6%) patients had at least one episode of hemorrhage prior to treatment. Spezler-Martin grades at baseline ranged from 2 to 5 (mean 3.2). Fifty percent had grade IV and V. Patients underwent a median of 2 (range 1-5) embolization procedures. The radiosurgical treatment dose to the margin of the angiography-based nidus: median prescription dose of 21.49 Gy (14.39-27.51) with a median max dose of 27.77 Gy (18.93-32.52). The median treatment volume was 0.6 cm3 (0.1-7.3 cm3). The Onyx embolization reduced the nidus target volume by a median of 66.7% (12.0-92.7%). We confirmed 10/14 (71%) complete closures. In 2/14 (14.2%) additional patients, a significant flow reduction was noted. In 1/14 (7.1%) patients, no significant change was noted during the observation period and two (14.2%) patients were without follow-up information. In two patients, post-treatment edema was noted; however, none was clinically significant and resolved without additional intervention or treatment. CONCLUSIONS: This cohort comprises the largest combined Onyx-SRS pediatric experience in the literature. In conjunction with our adult group study, we show that the use of Onyx reduces the SRS treatment target volume significantly. Importantly, we implemented the heterogeneity correction to avoid increased radiation exposure to normal surrounding brain tissue. The combined approach appears to be safe provided that the above-mentioned corrections are implemented.
PURPOSE: Treatment of cerebral arteriovenous malformations (AVM)-the most common cause of stroke in the pediatric population-can be challenging due to the complexity of size, morphology, and location. There is a significant risk in comparison to AVM treatment among adults. Thus, AVM treatment in the pediatric population imposes unique challenges. Recent improvements include optimized catheter techniques and better embolization materials, such as Onyx, a non-adhesive liquid embolic agent used in the adult population. These improvements have increased the success rate of total and near-total obliteration of cerebral AVM. However, the use of Onyx causes significant distortion of the MR and CT images, which must be accounted for in any radiation treatment planning predicated on CT and MRI. These image distortions impact on the actual delivered dose to the nidus and behoove heterogeneity correction. Our group has previously shared a solution for heterogeneity correction in the adult population. The purpose of this study is to show our experience in this unique group of pediatric patients. METHODS: This is a retrospective review of pediatric patients, who were undergoing combined endovascular embolization followed by SRS. The cohort consists of 14 patients undergoing SRS treatment in our institute between November 2006 and December 2012 with a mean follow-up of 49.9 months. Within this cohort, we retrospectively reviewed 12 consecutive pediatric patients who underwent a combined endovascular and SRS approach with a mean follow-up of 52.1 months and two patients receiving SRS-only treatment were excluded. RESULTS: In our cohort of 14 patients, 7 (50%) were male, with a mean age of 17.3 years (12.0-22.9) at the time of radiosurgery treatment. Mean age of beginning the combined modality treatment was 15.3 years (8.4-20). The median time from diagnosis to SRS was 24.3 months (11.1-64.4 months) in the complete cohort and 25.6 months (11.1-64.4) in the multimodality group. The overall median follow-up period was 49.9 months (range 12.8-118.8 months) in the complete cohort and 52.1 months (range 12.8-118.8 months) in the multimodality group. Eleven (78.6%) patients had at least one episode of hemorrhage prior to treatment. Spezler-Martin grades at baseline ranged from 2 to 5 (mean 3.2). Fifty percent had grade IV and V. Patients underwent a median of 2 (range 1-5) embolization procedures. The radiosurgical treatment dose to the margin of the angiography-based nidus: median prescription dose of 21.49 Gy (14.39-27.51) with a median max dose of 27.77 Gy (18.93-32.52). The median treatment volume was 0.6 cm3 (0.1-7.3 cm3). The Onyx embolization reduced the nidus target volume by a median of 66.7% (12.0-92.7%). We confirmed 10/14 (71%) complete closures. In 2/14 (14.2%) additional patients, a significant flow reduction was noted. In 1/14 (7.1%) patients, no significant change was noted during the observation period and two (14.2%) patients were without follow-up information. In two patients, post-treatment edema was noted; however, none was clinically significant and resolved without additional intervention or treatment. CONCLUSIONS: This cohort comprises the largest combined Onyx-SRS pediatric experience in the literature. In conjunction with our adult group study, we show that the use of Onyx reduces the SRS treatment target volume significantly. Importantly, we implemented the heterogeneity correction to avoid increased radiation exposure to normal surrounding brain tissue. The combined approach appears to be safe provided that the above-mentioned corrections are implemented.
Authors: Hideyuki Kano; L Dade Lunsford; John C Flickinger; Huai-che Yang; Thomas J Flannery; Nasir R Awan; Ajay Niranjan; Josef Novotny; Douglas Kondziolka Journal: J Neurosurg Date: 2011-11-11 Impact factor: 5.115
Authors: Cheng-Chia Lee; Michael A Reardon; Benjamin Z Ball; Ching-Jen Chen; Chun-Po Yen; Zhiyuan Xu; Max Wintermark; Jason Sheehan Journal: J Neurosurg Date: 2015-04-03 Impact factor: 5.115
Authors: Hideyuki Kano; Douglas Kondziolka; John C Flickinger; Huai-Che Yang; Thomas J Flannery; Nasir R Awan; Ajay Niranjan; Josef Novotny; L Dade Lunsford Journal: J Neurosurg Pediatr Date: 2012-01 Impact factor: 2.375
Authors: Robert M Starke; Dale Ding; Hideyuki Kano; David Mathieu; Paul P Huang; Caleb Feliciano; Rafael Rodriguez-Mercado; Luis Almodovar; Inga S Grills; Danilo Silva; Mahmoud Abbassy; Symeon Missios; Douglas Kondziolka; Gene H Barnett; L Dade Lunsford; Jason P Sheehan Journal: J Neurosurg Pediatr Date: 2016-12-02 Impact factor: 2.375
Authors: Dale Ding; Robert M Starke; Hideyuki Kano; David Mathieu; Paul P Huang; Caleb Feliciano; Rafael Rodriguez-Mercado; Luis Almodovar; Inga S Grills; Danilo Silva; Mahmoud Abbassy; Symeon Missios; Douglas Kondziolka; Gene H Barnett; L Dade Lunsford; Jason P Sheehan Journal: J Neurosurg Pediatr Date: 2016-12-02 Impact factor: 2.375
Authors: Ido Strauss; Oz Haim; Daniel Umansky; Benjamin W Corn; Vladimir Frolov; Natan Shtraus; Shimon Maimon; Andrew A Kanner Journal: World Neurosurg Date: 2017-09-07 Impact factor: 2.104
Authors: Jody Filippo Capitanio; Pietro Panni; Alberto Luigi Gallotti; Carmen Rosaria Gigliotti; Francesco Scomazzoni; Stefania Acerno; Antonella Del Vecchio; Pietro Mortini Journal: Childs Nerv Syst Date: 2018-11-24 Impact factor: 1.475