8 research outputs found
Risk of Subsequent Bone Cancers Among 69 460 Five-Year Survivors of Childhood and Adolescent Cancer in Europe
Introduction: We investigate the risks of subsequent primary bone cancers after childhood and adolescent cancer in 12
European countries. For the first time, we satisfactorily address the risks beyond 40 years from diagnosis and beyond 40 years
of age among all survivors.
Methods: This largest-ever assembled cohort comprises 69 460 five-year survivors of cancer diagnosed before age 20 years.
Standardized incidence ratios, absolute excess risks, and multivariable-adjusted relative risks and relative excess risks were
calculated. All statistical tests were two-sided.
Results: Overall, survivors were 21.65 times (95% confidence interval ¼ 18.97 to 24.60 times) more likely to be diagnosed with a
subsequent primary bone cancer than expected from the general population. The greatest excess numbers of bone cancers were
observed after retinoblastoma, bone sarcoma, and soft tissue sarcoma. The excess number of bone cancers declined linearly with both
years since diagnosis and attained age (all P < .05). Beyond 40years from diagnosis and age 40 years, there were at most 0.45 excess
bone cancers among all survivors per 10000 person-years at risk; beyond 30years from diagnosis and age 30 years, there were at most
5.02 excess bone cancers after each of retinoblastoma, bone sarcoma, and soft tissue sarcoma, per 10000 person-years at risk.
Conclusions: For all survivors combined and the cancer groups with the greatest excess number of bone cancers, the excess
numbers observed declined with both age and years from diagnosis. These results provide novel, reliable, and unbiased
information about risks and risk factors among long-term survivors of childhood and adolescent cancer.</p
Risk of Soft-Tissue Sarcoma Among 69 460 Five-Year Survivors of Childhood Cancer in Europe
Background: Childhood cancer survivors are at risk of subsequent primary soft-tissue sarcomas (STS), but the risks of specific STS histological subtypes are unknown. We quantified the risk of STS histological subtypes after specific types of childhood cancer. Methods: We pooled data from 13 European cohorts, yielding a cohort of 69 460 five-year survivors of childhood cancer. Standardized incidence ratios (SIRs) and absolute excess risks (AERs) were calculated. Results: Overall, 301 STS developed compared with 19 expected (SIR = 15.7, 95% confidence interval [CI] = 14.0 to 17.6). The highest standardized incidence ratios were for malignant peripheral nerve sheath tumors (MPNST; SIR = 40.6, 95% CI = 29.6 to 54.3), leiomyosarcomas (SIR = 29.9, 95% CI = 23.7 to 37.2), and fibromatous neoplasms (SIR = 12.3, 95% CI = 9.3 to 16.0). SIRs for MPNST were highest following central nervous system tumors (SIR = 80.5, 95% CI = 48.4 to 125.7), Hodgkin lymphoma (SIR = 81.3, 95% CI = 35.1 to 160.1), and Wilms tumor (SIR = 76.0, 95% CI = 27.9 to 165.4). Standardized incidence ratios for leiomyosarcoma were highest following retinoblastoma (SIR = 342.9, 95% CI = 245.0 to 466.9) and Wilms tumor (SIR = 74.2, 95% CI = 37.1 to 132.8). AERs for all STS subtypes were generally low at all years from diagnosis (AER < 1 per 10 000 person-years), except for leiomyosarcoma following retinoblastoma, for which the AER reached 52.7 (95% CI = 20.0 to 85.5) per 10 000 person-years among patients who had survived at least 45 years from diagnosis of retinoblastoma. Conclusions: For the first time, we provide risk estimates of specific STS subtypes following childhood cancers and give evidence that risks of MPNSTs, leiomyosarcomas, and fibromatous neoplasms are particularly increased. While the multiplicative excess risks relative to the general population are substantial, the absolute excess risk of developing any STS subtype is low, except for leiomyosarcoma after retinoblastoma. These results are likely to be informative for both survivors and health care providers
The PanCareSurFup cohort of 83,333 five-year survivors of childhood cancer: a cohort from 12 European countries
Childhood cancer survivors face risks from a variety of late effects, including cardiac events, second cancers, and late mortality. The aim of the pan-European PanCare Childhood and Adolescent Cancer Survivor Care and Follow-Up Studies (PanCareSurFup) Consortium was to collect data on incidence and risk factors for these late effects among childhood cancer survivors in Europe. This paper describes the methodology of the data collection for the overall PanCareSurFup cohort and the outcome-related cohorts. In PanCareSurFup 13 data providers from 12 countries delivered data to the data centre in Mainz. Data providers used a single variable list that covered all three outcomes. After validity and plausibility checks data was provided to the outcome-specific working groups. In total, we collected data on 115,596 patients diagnosed with cancer from 1940 to 2011, of whom 83,333 had survived 5 years or more. Due to the eligibility criteria and other requirements different numbers of survivors were eligible for the analysis of each of the outcomes. Thus, 1014 patients with at least one cardiac event were identified from a cohort of 39,152 5-year survivors; for second cancers 3995 survivors developed at least one second cancer from a cohort of 71,494 individuals, and from the late mortality cohort of 79,441 who had survived at least 5 years, 9247 died subsequently. Through the close cooperation of many European countries and the establishment of one central data collection and harmonising centre, the project succeeded in generating the largest cohort of children with cancer to date
CO12.1 - A case-control study to identify potential genetic biomarkers related to cardiac diseases occurrence in childhood cancer survivors
International audienceSurvival rates in paediatric oncology continue to improve with current 5-year survival after treatment reaching 80%. However, Cardiac Disease (CD) is the most common non-cancerous long-term adverse effect in this population, causing long-term morbidity and early mortality. Indeed, exposition to anthracyclines/or radiotherapy where the heart was exposed is significantly associated with CD. Nevertheless, these treatments alone cannot explain the individual variability in the prevalence and severity of CD. The current study aims to identify genetic expression biomarkers associated with CD occurrence after childhood cancer treatment, and to build a genomic signature linked to this cardiotoxicity