[Creation of 3D Stereo and MPR Color Anatomical Charts in the Hepatic Segments].

We used the Voronoi diagram of a computed tomography (CT) application (i.e., CT liver volume measurement) to depict the liver area, and we obtained depictions of the hepatic segments as a three-dimensional (3D) image based on clinical data; this information can be used for the patient's education and for surgical planning.

Image Quality Assessment of Deep Learning Image Reconstruction in Torso Computed Tomography Using Tube Current Modulation.

Novel deep learning image reconstruction (DLIR) reportedly changes the image quality characteristics based on object contrast and image noise. In clinical practice, computed tomography image noise is usually controlled by tube current modulation (TCM) to accommodate changes in object size. This study aimed to evaluate the image quality characteristics of DLIR for different object sizes when the in-plane noise was controlled by TCM.

[Accuracy of Virtual Non-contrast Image Reconstruction Using Material Decomposition for Fast kV-switching Dual-energy CT].

Purpose: Dual-energy computed tomography (DECT) system can generate virtual non-contrast (VNC) images. Although several reconstruction algorithms are defined, there are not many researches using deep learning image reconstruction (DLIR) algorithm. In this study, we evaluated the accuracy of the VNC image reconstruction under various conditions using DLIR algorithm.

[Creation of Bone X-ray Radiography Manual Using Human Bone Specimens for Bone X-ray Radiography Education].

Senior radiological technologists have made various improvements and have supported the clinical and educational fields by explaining bone X-ray radiography to students and junior radiological technologists to understand the procedure using illustrations, X-ray images, and photographs in a way that corresponds to the design software available for that era. Because human bone specimens are only available in the anatomy laboratory of medical schools, they could not be used for the explanation of bone X-ray radiography until now. Therefore, we have developed a bone X-ray radiography manual using bone specimens for the bone X-ray radiography education, which helps students to understand the procedure of bone X-ray radiography.

[Creation of a Stereo-paired Bone Anatomical Chart Using Human Bone Specimens for X-ray Anatomical Education Part III: Addition of Anaglyph Three-dimensional Images for Those Who Hardly See Stereo-paired Photographs with the Naked Eye].

We published a report entitled "Creation of a stereo-paired bone anatomical chart using human bone specimen for radiation education" in this journal in order to accurately understand the surface structure and three-dimensional structure of bones, and assist in bone image interpretation. However, some people cannot see stereoscopically with the naked eye. Therefore, we created anaglyph three-dimensional (3D) images from stereo-paired images of the stereo X-ray anatomical chart of the bone specimen.

[Creation of Stereo-paired Color Vascular Anatomical Charts Using 3-dimentional Images].

Three-dimensional (3D) images of blood vessels in the human body, which are acquired by X-ray computed tomography (CT) and cone-beam CT of Angiography devices, are widely used in medical diagnosis and treatment. Using the 3DCT images of blood vessels, we created stereo-paired color vascular anatomical charts for better understanding of vascular anatomy in clinical settings, patient explanations, and student education. Since it is difficult to distinguish branches of blood vessels that show three-dimensionally complicated running such as cerebral blood vessels, we made it easier to identify them anatomically by color-coding each branch of the blood vessel.

[Creation of a Stereo-paired Bone Anatomical Chart Using Human Bone Specimens for X-ray Anatomical Education Part II: Addition of Stereo-paired X-ray Bone Images to the Anatomical Chart].

In a previous issue of this journal, we published a report entitled "Creation of Stereo-paired Bone Anatomical Charts Using Human Bone Specimens for Radiation Education" To understand how the bone specimen is visualized as an X-ray image, we newly created a bone specimen stereo-paired X-ray anatomical chart by adding the X-ray images of the same bone specimen. When a bone is X-rayed, the surface structure and internal structure of the bone are visualized as a composite image of the difference in X-ray absorption, and each bone becomes a unique X-ray image. Therefore, we took stereo-paired X-ray images of the bone specimens by the same method as the stereo-paired anatomical chart of the bone specimens.

[Creation of Stereo-paired Bone Anatomical Charts Using Human Bone Specimens for Radiation Education].

In radiological examinations of patients, we often take stacked images and three-dimensional (3D) images of human bone radiological images such as X-ray images and CT images. In general, learning of bone structure using specialized anatomy books is currently performed at medical radiological technologist education facilities. In the anatomy education of the medical school, in order to understand the structure of human and the individual bone shapes in detail, a real human bone specimen is used to gain knowledge of skeleton, bone shape, bone name and bone function.

[Creation of Stereo Color Anatomical Charts Showing Nerve Fibers in the Cerebral Lobe and Gyrus of the Brain for Use in the MR Examination].

In anatomical charts in conventional books, the pathways of nerve fibers are drawn in illustrations. Conversely, with diffusion tensor tractography (DTT), we can visually understand the trajectory of nerve fibers through color. We created a stereo color anatomical chart of the nerve fibers that can be used for magnetic resonance (MR) examination to diagnose the pathway of nerve fibers and that can be used to explain the results of MR examination to visually understand how nerve fiber information is transmitted from the frontal lobe, parietal lobe, occipital lobe, temporal lobe, cerebellar lobe, and cerebral cortex.

Reaction of the Mo3S4 cluster with dimethylacetylenedicarboxylate: an ESR-active cluster and an organometallic cluster formed by alpha,beta-conjugate addition.

A seven-electron cluster [Mo3(mu3-S){mu3-SC(CO(2)CH(3))=C(CO(2)CH(3))S}{mu-SC(CO(2)CH(3))=CH(CO(2)CH(3))}(dtp)3(mu-OAc)] [2, S2P(OC(2)H(5))2-; dtp = diethyldithiophosphate] and an organometallic cluster [Mo3(mu3-S){mu3-SC(CO(2)CH(3))=C(CO(2)CH(3))S}{mu-SC(CO(2)CH(3))CH(OCH(3))(CO2)}(dtp)2(CH(3)OH)(mu-OAc)](Mo-C) (3) were obtained by reaction in methanol of the sulfur-bridged trinuclear complex [Mo3(mu3-S)(mu-S)3(dtp)3(CH(3)CN)(mu-OAc)] (1) with dimethylacetylenedicarboxylate (DMAD). The X-ray structures of 2 and 3 revealed the adduct formation of two DMAD molecules to the respective Mo(3)S(4) cores. 2 is paramagnetic and obeys the Curie-Weiss law: the mu(eff) value at 300 K is 1.

Photochromic isomerization of a dinuclear molybdenum complex with ethylene-1,2-dithiolate and disulfur ligands: x-ray structures of the two isomers.

A photochromic complex with disulfur and dimethyl-ethylene-1,2-dithiolate ligands, [Mo(2)(mu-S(2))(mu-S(2)C(2)Me(2))(2)(S(2)C(2)Me(2))(2)] (3), was synthesized and characterized. Photoirradiation of 3 with visible light resulted in the formation of the isomer (3'). The electronic spectrum of 3' has a new intense peak in the near infrared region, and in the dark, the spectrum returns to that of 3.