X-ray microcomputed tomography (micro-CT) with a respiratory gating system is a useful non-invasive approach to evaluate lung tumor development in living animal models. Here micro-CT was applied for the detection of lung lesions induced by a single intraperitoneal injection (250 mg/kg) of urethane in male A/J mice, at 2-week intervals from 10 to 30 weeks after carcinogen exposure. In micro-CT cross sections, lung tumor images were easily distinguished from surrounding non-tumorous tissues, the smallest detected tumor being approximately 0.5 mm in diameter. All of the urethane-treated mice (n = 15) developed lung tumors and the number of tumors developed in each mouse was 8.6 ± 3.9. Six tumors, determined histopathologically to be adenocarcinomas, were detected, growing at different rates during the experimental period. The most aggressive carcinoma, increasing in diameter from 0.9 to 3. (1) For detecting lung cancer, X-ray fluoroscopy has been used widely in practical screening. X-ray computed tomography (CT) is also used to detect early stage lesions and to evaluate tumor progression and metastasis during clinical treatment.(2) Moreover, X-ray CT is a useful tool for monitoring lung tumor development in living animal models (3) and major efforts have been invested in developing devices for imaging the inner anatomy of small animals. As with CT for human cases, micro-CT for rodents allows evaluation of bones and other calcified changes as well as diagnosis of soft tissue changes, such as lung tumor development.(4,5) Non-invasiveness, the ability to monitor therapeutic effects, the capacity to optimize the experimental period, and a lowering in the number of animals used can all be considered advantages of this novel approach. However, there are also disadvantages in that it is difficult to make a refined evaluation in very small rodents, and the image quality is strongly affected by motion-related artifacts. Several efforts, particularly the development of a method with a respiratory gating system for obtaining sharper images, have been made to overcome these difficulties. (6)(7)(8) Hitherto, the utility of micro-CT has been reported for detecting lung tumors in a metastatic rodent model, a K-ras transgenic lung cancer model, and a urethane-induced mouse lung tumor model. (5,(8)(9)(10) However, in those reports the mice were scanned only once by micro-CT, and then killed for histopathological analysis of lung lesions. Full utilization of the advantages of respiration-gated micro-CT for periodic detection of sizes in lung tumors and their growth over time has not been made.In the present study, urethane-induced tumor development was therefore monitored periodically using respiration-gated micro-CT. The results obtained indicate that tumors grow at markedly varying speeds, which may not directly reflect the histopathological findings after autopsy. The necessity for appropriate scanning methods of micro-CT images, which link to histopathology, is discussed in the text.
Materials and MethodsAnimals. Male A/J Jms Sl...
