Browsing Academic Department of Radiation Oncology - ADRO by Subjects
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Hypoxia-associated markers in gastric carcinogenesis and HIF-2alpha in gastric and gastro-oesophageal cancer prognosis.The study investigated hypoxia-associated markers (HIF-2alpha, Epo, Epo-R, Glut-1 and VEGF) along with Ki-67 in a gastric carcinogenesis model, and the prognostic significance of hypoxia-inducible factor (HIF)-2alpha in surgically treated gastro-oesophageal cancer. Protein expression was examined using immunohistochemistry on formalin-fixed, paraffin-embedded biopsies of normal mucosa (n=20), Helicobacter pylori-associated gastritis (n=24), intestinal metaplasia (n=24), dysplasia (n=12) and intestinal (n=19) and diffuse (n=21) adenocarcinoma. Relationships between HIF-2alpha expression and prognosis were assessed in resection specimens from 177 patients with gastric and gastro-oesophageal junction adenocarcinoma. Expression of all markers increased with progression along the gastric carcinogenesis sequence (P=0.0001). Hypoxia-inducible factor-2alpha was expressed in 63% of 177 resection specimens and at a high level in 44%. The median overall survival in patients with HIF-2alpha-expressing tumours was 22 (95% CI 18-26) months, whereas those with HIF-2alpha-negative tumours had a median survival of 37 (95% CI 29-44) months (P=0.015). Hypoxia-inducible factor-2alpha had no independent prognostic significance in multivariate analysis. In view of the lack of independent prognostic significance, HIF-2alpha has no role as a routine prognostic indicator. However, the high expression of HIF-2alpha suggests that it may be of value as a potential therapeutic target.
Radical chemoradiotherapy for adenocarcinoma of the distal oesophagus and oesophagogastric junction: what planning margins should we use?Distal oesophageal and Type I-II oesophagogastric junctional adenocarcinomas have a poor prognosis. In radical chemoradiotherapy, consensus is lacking on radiotherapy margins. Here, we review the effect of common imaging modalities on the extent of the gross tumour volume (GTV) and the evidence for margins. To do this, papers were identified from PubMed, and geometric uncertainties were combined using the British Institute of Radiology formula. CT and endoscopic ultrasound were best for GTV delineation, but the role of positron emission tomography is uncertain. Evidence suggests 3 cm proximal and 5 cm distal GTV-CTV (clinical target volume) margins (along the mucosa) for advanced tumours, but is lacking for early tumours and radial margins. Nodal spread, present in most pT2 tumours, is strongly prognostic and is initially to regional nodes (not wholly covered by typical radiotherapy). Calculated CTV-PTV (planning target volume) margins for three-dimensional conformal radiotherapy using literature estimates of tumour motion and set-up errors with bony online set-up correction, ignoring delineation errors, are 2.2 cm superiorly (sup) and inferiorly (inf) and 1.2-1.3 cm radially (1.3 cm sup-inf; 0.8 cm radially if the tumour's mid-position is known). As these margins may risk excessive toxicity, we propose treating microscopic disease for potentially curable tumours (cT2N0, some cT3N0), but gross disease only for advanced tumours. Recommended GTV-CTV margins are a maximum of 3 cm proximally and 5 cm distally up to cT2N0; 3 cm proximally and 5 cm distally for cT3N0 if anticipated toxicity allows; and 0 cm for cT4 and most node-positive tumours. The CTV-PTV margins above must be added to this for all stages. Methods of including elective nodal areas close to the GTV should be researched, e.g. nodal maps and intensity-modulated radiotherapy.
The role of PET in target localization for radiotherapy treatment planning.Positron emission tomography (PET) is currently accepted as an important tool in oncology, mostly for diagnosis, staging and restaging purposes. It provides a new type of information in radiotherapy, functional rather than anatomical. PET imaging can also be used for target volume definition in radiotherapy treatment planning. The need for very precise target volume delineation has arisen with the increasing use of sophisticated three-dimensional conformal radiotherapy techniques and intensity modulated radiation therapy. It is expected that better delineation of the target volume may lead to a significant reduction in the irradiated volume, thus lowering the risk of treatment complications (smaller safety margins). Better tumour visualisation also allows a higher dose of radiation to be applied to the tumour, which may lead to better tumour control. The aim of this article is to review the possible use of PET imaging in the radiotherapy of various cancers. We focus mainly on non-small cell lung cancer, lymphoma and oesophageal cancer, but also include current opinion on the use of PET-based planning in other tumours including brain, uterine cervix, rectum and prostate.