Use of Microfocus X-ray Computer Tomography for 3D-image Construction and Quantitative Morphoanalysis

Abstract

Microfocus X-ray computed tomography (μCT) is becoming widely used in various research fields relevant to the oral sciences. This technology, in conjunction with computer-assisted 3D reconstruction and quantitative structural analysis, is most suitable for investigating hard tissues in a non-invasive way. Despite this recognition, it still remains a concern whether the data acquisition process is conducted properly and accurately in order to ensure the reproducibility of 3D imaging and the determination of structural parameters such as bone volume (BV) and surface area (BS). In this report, we aim to provide an overview of the experimental procedures and conditions that are necessary for optimizing the acquisition of gray-scale CT images and their conversion into digital images (TIFF or JPEG) prior to 3D reconstruction and measurements. Towards these objectives, we collected μCT images of a 4-week-old mouse temporomandibular joint using a μCT apparatus (Nittetsu ELEX Co., ELE-SCAN model). Data proceedings and measurements were conducted using software (RATOC System Engineering Co., TRI-BON and TRI-SRF2). Special care was taken in optimizing experimental conditions and variables, e.g., X-ray tube voltage and current, selection of an adequate shiftvalue to compensate the mismatching between the specimen-rotating center and incident X-ray beam, and window level and width for contrast adjustment. The results of our empirical approach showed that careful selection of the experimental conditions and computation variables ensures the high quality of the 3D images and the accuracy and reproducibility of the quantitative measurements. The magnitude of errors associated with each of the determined structural parameters was confirmed to be within 3% of the determinations. Further knowledge and refinement of μCT technology and data acquisition will help to improve our understanding of the architecture and dynamic modeling of hard tissues.