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Child's Nervous System

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01.03.2011 | Original Paper

Radiation-induced tumors in children irradiated for brain tumor: a longitudinal study

verfasst von: Matthieu Vinchon, Pierre Leblond, Sabine Caron, Isabelle Delestret, Marc Baroncini, Bernard Coche

Erschienen in: Child's Nervous System | Ausgabe 3/2011

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Abstract

Background

Radiation-induced tumors (RIT) are increasingly recognized as delayed complications of brain irradiation during childhood. However, the true incidence is not established, their biology is poorly understood, and few guidelines exist regarding the long-term follow-up of irradiated children.

Methods

We studied retrospectively patients irradiated for brain tumor under 18 years and followed in our institution since 1970. RIT were defined as new masses, different from the original tumor, occurring after delay in irradiated areas, and not related to phacomatosis.

Results

Among 552 irradiated patients, 42 (7.6%) developed one or more RIT, 26 months to 29 years after irradiation (mean 12.8 years). The cumulated incidence was 2.0% at 5 years and 8.9% at 10 years. Of the patients, 73.8% were adult at the time of diagnosis of RIT, and 75% were diagnosed within 18.1 years after irradiation. We identified 60 cavernomas, 26 meningiomas, 2 malignant gliomas, 1 meningosarcoma, and 6 thyroid tumors. Compared with meningiomas, cavernomas appeared earlier, in children irradiated at an older age, and with a male predominance. Although RIT were correlated with higher irradiation doses, 80.9% of these occurred at some distance from the maximum irradiation field. Twenty-five lesions were operated in 20 patients; three patients died because of progression of the RIT.

Conclusion

A significant number of patients undergoing irradiation for brain tumor during childhood develop a RIT, often during adulthood. Our data suggest that radiation-induced cavernomas result from angiogenetic processes rather than true tumorigenesis. Protracted follow-up with MRI is warranted in children irradiated for brain tumor.

Arita K, Kurisu K, Sugiyama K (2006) Nervous system tumors and atomic bomb experience of Hiroshima and Nagasaki. In: McLendon RE, Rosemblum MK, Bigner DD (eds) Russell & Rubinstein's Pathology of tumors of the central nervous system, 7th edn. Hodder Arnold, London, pp 51–56

Al Mefty O, Topsakal C, Pravdenkova S, Sawyer JR, Harrisson MJ (2004) Radiation-induced meningiomas: clinical, pathological, cytokinetic, and cytogenetic characteristics. J Neurosurg 100:1002–1013CrossRefPubMed

Boljesikova E, Chorvath M, Hurta P, Steno J, Bizik I (2001) Radiation-induced meningioma with a long latency period: a case report. Pediatr Radiol 31:607–609CrossRefPubMed

Cahan WG, Woodard HQ, Higinbotham NL, Stewart FW, Coley BL (1948) Sarcoma arising in irradiated bone. Cancer 1:3–29CrossRefPubMed

Strojan P, Popović M, Jereb B (2000) Secondary intracranial meningiomas after high-dose cranial irradiation: report of five cases and review of the literature. Int J Radiat Oncol Biol Phys 48:65–73CrossRefPubMed

Amirjamshidi A, Abbassioun K (2000) Radiation-induced tumors of the central nervous system occurring in childhood and adolescence: four unusual lesions in three patients and a review of the literature. Child’s Nerv Syst 16:390–397CrossRef

Heckl S, Aschoff A, Kunze S (2002) Radiation-induced cavernous hemangiomas of the brain: a late effect predominantly in children. Cancer 94:3285–3291CrossRefPubMed

Paulino AC, Ahmed IM, Mai WY, Teh BS (2009) The influence of pretreatment characteristics and radiotherapy parameters on time interval to development of radiation-associated meningioma. Int J Radiat Oncol Biol Phys 75:1408–1414CrossRefPubMed

Salvati M, D’Elia A, Melone GA, Brogna C, Frati A, Raco A, Delfini R (2008) Radio-induced gliomas: 20-year experience and critical review of the pathology. J Neurooncol 89:169–177CrossRefPubMed

10.

Soffer D, Gomori JM, Siegal T, Shalit MN (1989) Intracranial meningiomas after high-dose irradiation. Cancer 63:1514–1519CrossRefPubMed

11.

Brada M, Ford D, Ashley S, Bliss JM, Crowley S, Mason M, Rajan B, Traish D (1992) Risk of second brain tumour after conservative surgery and radiotherapy for pituitary adenoma. Brit Med J 304:1343–1346CrossRefPubMed

12.

Lew SM, Morgan JN, Psaty EA, Lefton DR, Jeffrey AC, Abbott R (2006) Cumulative incidence of radiation-induced cavernomas in long-term survivors of medulloblastoma. J Neurosurg 104:103–107, 2 Suppl PediatricsPubMed

13.

Walter AW, Hancock ML, Pui CH, Hudson MM, Ochs JS, Rivera GK, Pratt CB, Boyett JM, Kun LE (1998) Secondary brain tumors in children treated for acute lymphoblastic leukemia at St Jude Children's Research Hospital. J Clin Oncol 16:3761–3767PubMed

14.

Averbeck D (2009) Does scientific evidence support a change from the LNT model for low-dose radiation risk extrapolation? Health Phys 97:493–504CrossRefPubMed

15.

Lonser RR, Walbridge S, Vortmeyer AO, Pack SD, Nguyen TT, Gobate N, Olson JJ, Bobo RH, Goffman T, Shunang Z, Oldfield EH (2002) Induction of glioblastoma multiforme in nonhuman primates after therapeutic doses of fractionated whole-brain radiation therapy. J Neurosurg 87:1378–1389

16.

Vinchon M, Dhellemmes P (2007) The transition from child to adult in neurosurgery. Adv Techn Standards Neurosurg 32:3–24CrossRef

17.

Duhem R, Vinchon M, Leblond P, Soto-Ares G, Dhellemmes P (2005) Cavernous malformations after cerebral irradiation during childhood: report of nine cases. Childs Nerv Syst 10:922–925CrossRef

18.

Strenger V, Sovinz P, Lackner H, Dornbusch HJ, Lingitz H, Eder HG, Moser A, Urban C (2008) Intracerebral cavernous hemangioma after cranial irradiation in childhood; incidence and risk factors. Strahlenther Onkol 184:276–280CrossRefPubMed

19.

Burn S, Roxana G, Phipps K, Gaze M, Hayward R (2007) Incidence of cavernoma development in children after radiotherapy for brain tumors. J Neurosurg (Pediatrics) 106(suppl 5):379–383CrossRef

20.

Loeffler JS, Niemierko A, Chapman PH (2003) Second tumors after radiosurgery: the tip of the iceberg or a bump in the road? Neurosurgery 52:1436–1442CrossRefPubMed

21.

Sasagawa Y, Akai T, Itou S, Iizuka H (2009) Gamma knife radiosurgery-induced cavernous hemangioma: case report. Neurosurgery 64:E1006–E1007CrossRefPubMed

22.

Mack EE (1999) Radiation-induced tumors. In: Berger MS, Wilson CB (eds) The gliomas. Philadelphia, Saunders, pp 724–735

23.

Furuta T, Sugiu K, Tamiya T, Matsumoto K, Ohmoto T (1998) Malignant cerebellar astrocytoma developing 15 years after radiation therapy for a medulloblastoma. Clin Neurol Neurosurg 100:56–59CrossRefPubMed

24.

Hope AJ, Mansur DB, Tu PH, Simpson JR (2006) Metachronous secondary atypical meningioma and anaplastic astrocytoma after postoperative craniospinal irradiation for medulloblastoma. Childs Nerv Syst 22:1201–1207CrossRefPubMed

25.

Yang SY, Wang KC, Cho BK, Kim YY, Lim SY, Park SH, Kim IH, Kim SK (2005) Radiation-induced cerebellar glioblastoma at the site of a treated medulloblastoma. J Neurosurg 102(suppl 4):417–422PubMed

26.

Nimjee SM, Powers CJ, Bilsara KR (2006) Review of the literature on de novo formation of cavernous malformations of the central nervous system after radiation therapy. Neurosurg Focus 21:E4CrossRefPubMed

27.

Czech T, Slavic I, Aichholzer M, Haberler C, Dietrich W, Dieckmann K, Koos W, Budka H (1999) Proliferative activity as measured by MIB-1 labeling index and long-term outcome of visual pathway astrocytomas in children. J Neurooncol 42:143–150CrossRefPubMed

28.

Simsek E, Yavuz C, Ustundag N (2003) Atypical meningioma and extensive calvarium defects in neurofibromatosis type 1. Pediatr Radiol 33:551–553CrossRefPubMed

29.

Amlashi SFA, Riffaud L, Brassier G, Morandi X (2003) Nevoid basal cell carcinoma syndrome: relation with desmoplastic medulloblastoma in infancy; population-based study and review of the literature. Cancer 98:618–624CrossRefPubMed

30.

Kantar M, Cetingu lN, Kansoy S, Anacak Y, Demirtas E, Ersahin Y, Mutluer S (2004) Radiotherapy-induced secondary cranial neoplasms in children. Childs Nerv Syst 20:46–49CrossRefPubMed

31.

Baumgartner JE, Ater JL, Ha CS, Kuttesch JF, Leeds NE, Fuller GN, Wilson RJ (2003) Pathologically proven cavernous angiomas of the brain following radiation therapy for pediatric brain tumors. Pediatr Neurosurg 39:201–207CrossRefPubMed

32.

Jain R, Robertson PL, Gandhi D, Gujar SK, Muraszko KM, Gebarski S (2005) Radiation-induced cavernomas of the brain. AJNR Am J Neuroradiol 26:1158–1162PubMed

33.

Koike S, Aida N, Hata M, Fujita K, Ozawa Y, Inoue T (2004) Asymptomatic radiation-induced telangiectasia in children after cranial irradiation: frequency, latency, and dose relation. Radiology 230:93–99CrossRefPubMed

34.

Pozzati E, Giangaspero F, Marliani F, Acciarri N (1996) Occult cerebrovascular malformations after irradiation. Neurosurgery 39:677–684CrossRefPubMed

35.

Lee JW, Kim DS, Shim KW, Chang JH, Huh SK, Park YG, Choi JU (2008) Management of intracranial cavernous malformation in pediatric patients. Childs Nerv Syst 24:321–327CrossRefPubMed

36.

Pettorini BL, Narducci A, de Carlo A, Abet F, Caldarelli M, Massimi L, Tamburrini G, Di Rocco C (2009) Thyroid neoplasm after central nervous system irradiation for medulloblastoma in childhood: report of two cases. Childs Nerv Syst 25:631–634CrossRefPubMed

37.

Mathews MS, Peck WW, Brant-Zawadzki M (2008) Brown–Séquard syndrome secondary to spontaneous bleed from postradiation cavernous angiomas. AJNR Am J Neuroradiol 29:1989–1990CrossRefPubMed

38.

Makidono A, Kobayashi N, Saida Y, Manabe A, Kawamori J, Suzuki K (2009) Metachronous gliomas following cranial irradiation for mixed germ cell tumors. Childs Nerv Syst 25:713–718CrossRefPubMed

39.

Pettorini BL, Park YS, Caldarelli M, Massimi L, Tamburrini G, Di Rocco C (2008) Radiation-induced brain tumours after central nervous system irradiation in childhood: a review. Childs Nerv Syst 24:793–805CrossRefPubMed

40.

Kondziolka D, Kano H, Kanaan H, Madhok R, Mathieu D, Flickinger JC, Lunsford LD (2009) Stereotactic radiosurgery for radiation-induced meningiomas. Neurosurgery 64:463–470CrossRefPubMed

Titel: Radiation-induced tumors in children irradiated for brain tumor: a longitudinal study
verfasst von: Matthieu Vinchon
Pierre Leblond
Sabine Caron
Isabelle Delestret
Marc Baroncini
Bernard Coche
Publikationsdatum: 01.03.2011
Verlag: Springer-Verlag
Erschienen in: Child's Nervous System / Ausgabe 3/2011
Print ISSN: 0256-7040
Elektronische ISSN: 1433-0350
DOI: https://doi.org/10.1007/s00381-011-1390-4

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Abstract

Background

Methods

Results

Conclusion

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