Value of BOLD-fMRI in the protection of visual function during postoperative intensity-modulated radiotherapy for cerebral gliomas / 中华放射肿瘤学杂志

Objective To investigate the clinical value of blood oxygenation level-dependent functional magnetic resonance imaging(BOLD-fMRI)in the protection of visual function during postoperative radiotherapy for occipital lobe gliomas. Methods Twenty-eight patients with occipital lobe gliomas receiving postoperative radiotherapy from 2014 to 2016 were enrolled as subjects. All patients underwent computed tomography(CT) simulation,conventional MRI,and BOLD-fMRI before radiotherapy. The location and scope of the visual cortex on 3DT1anatomical images were used to guide the labeling of the visual cortex on simulated CT images. A visual cortex protective radiotherapy plan and a conventional radiotherapy plan were made by intensity-modulated radiotherapy. The feasibility of the visual cortex protective radiotherapy plan was evaluated using conformity index(CI),homogeneity index(HI),Dmax,and Dmeanfor planning target volume(PTV)and Dmaxand Dmean to the visual cortex. Results For the two plans, if the effective dose to target volume was guaranteed and the doses to conventional organs at risk were acceptable, there were no significant differences in CI or HI for PTV between them(P=0.874,P=0.602).Compared with the conventional radiotherapy plan,the Dmaxand Dmeanto the ipsilateral visual cortex were reduced by 8.40% and 9.25%, respectively, while the Dmaxand Dmeanto the contralateral visual cortex were reduced by 13.26% and 14.77%, respectively, in the protective radiotherapy plan. Conclusions With a guaranteed prescribed dose to target volume and BOLD-fMRI used as a guide, the visual cortex protective radiotherapy, compared with the conventional plan, can reduce the dose to the visual cortex and protect the corresponding functional areas.

Self-focusing hidden bar code.

A new type of diffractive optical bar code produced by computer-generated holographic technology is proposed. The message in the proposed bar code is hidden in the diffracted light of the bar code element and can be read from the first diffraction order. In contrast to the conventional hidden bar code, which needs a lens to focus the diffracted light, the proposed hidden bar code has a property of self-focusing. This self-focusing ability is achieved by modulating a function of the Fresnel zone plate into the bar code format. Consequently, the read-out process for the information in this hidden bar code avoids the use of a lens. Experiments have shown the feasibility of the proposed bar code and confirmed that it can perform better than the conventional hidden bar code.