Paediatric CBCT protocols for image-guided radiotherapy; outcome of a survey across SIOP Europe affiliated countries and literature review.

BACKGROUND: Implementation of daily cone-beam CT (CBCT) into clinical practice in paediatric image-guided radiotherapy (IGRT) lags behind compared to adults. Surveys report wide variation in practice for paediatric IGRT and technical information remains unreported. In this study we report on technical settings from applied paediatric CBCT protocols and review the literature for paediatric CBCT protocols. METHODS: From September to October 2022, a survey was conducted among 246 SIOPE-affiliated centres across 35 countries. The survey consisted of 3 parts: 1) baseline information; technical CBCT exposure settings and patient set-up procedure for 2) brain/head, and 3) abdomen. Descriptive statistics was used to summarise current practice. The literature was reviewed systematically with two reviewers obtaining consensus RESULTS: The literature search revealed 22 papers concerning paediatric CBCT protocols. Seven papers focused on dose-optimisation. Responses from 50/246 centres in 25/35 countries were collected: 44/50 treated with photons and 10/50 with protons. In total, 48 brain/head and 53 abdominal protocols were reported. 42/50 centres used kV-CBCT for brain/head and 35/50 for abdomen; daily CBCT was used for brain/head = 28/48 (58%) and abdomen = 33/53 62%. Greater consistency was seen in brain/head protocols (dose range 0.32 - 67.7 mGy) compared to abdominal (dose range 0.27 - 119.7 mGy). CONCLUSION: Although daily CBCT is now widely used in paediatric IGRT, our survey demonstrates a wide range of technical settings, suggesting an unmet need to optimise paediatric IGRT protocols. This is in accordance with the literature. However, there are only few paediatric optimisation studies suggesting that dose reduction is possible while maintaining image quality.

Corrigendum to 'quantitative determination of 64Cu-liposome accumulation at inflammatory and infectious sites: Potential for future theranostic system': [journal of controlled release 327 (2020) 737-746].

BACKGROUND: Therapeutic interventions for infectious and inflammatory diseases are becoming increasingly challenging in terms of therapeutic resistance and side-effects. Theranostic systems to ameliorate diagnosis and therapy are therefore highly warranted. The pathophysiological changes in inflammatory lesions provide an attractive basis for extravasation and accumulation of PEGylated liposomes. The objective of this study was to provide direct quantitative information on the theranostic potential of radiolabeled liposome for accumulation in inflammatory models using position emission tomography (PET). METHOD: Preclinical murine models of inflammation (turpentine and LPS), infection (Staphylococcus aureus) and collagen-induced arthritis (CIA) was established and monitored using bioluminescence imaging (BLI). Across all models PET imaging using radiolabeled PEGylated liposomes (64Cu-liposomes) were performed and evaluated in terms of accumulation properties in inflammatory and infectious lesions. RESULTS: BLI demonstrated that the inflammatory and infectious models were successfully established and provided information on lesion pathology. Activity of 64Cu-liposomes were increased in inflammatory and infectious lesions between early (10-min or 3-h) and late (24-h) PET scans, which validates that a continuous extravasation and accumulation of long circulation PEGylated liposomes occurs. CONCLUSION: The theranostic potential of long circulating PEGylated radiolabeled liposomes was shown in multiple preclinical models. Impressive accumulation was seen in both inflammatory and infectious lesions. These results are encouraging towards advancing PEGylated liposomes as imaging and drug delivery systems in inflammatory and infectious diseases.