Simulator Education Initiatives for On-Campus Practical Training in Nuclear Medicine Technology

DISCUSSION

In the past, our institution was not able to provide practical on-campus training in nuclear medicine technology because of a lack of diagnostic equipment. Therefore, we attempted to implement on-campus training in nuclear medicine technology using a diagnostic image processing simulator. In this questionnaire-based study, we surveyed students regarding their perceptions of the usefulness of simulator education for on-campus training.

Our on-campus practical training used SPECT data installed in the diagnostic image processing simulator. Through these data, students familiarized themselves with image reconstruction, the Butterworth filter cutoff frequency, preprocessing filters, and attenuation correction. The responses to the questionnaire showed that the students had acquired a good understanding of all these topics. Having the opportunity to perform image processing themselves gave the students an in-depth understanding that they were not able to obtain via lectures. The students were able to successfully link what they experienced in practical on-campus training with what they learned in classroom lectures, which we believe led to a better understanding of nuclear medicine technology and the importance of image processing.

Many students expressed a desire to continue using the simulator as part of on-campus practical training. However, some students wanted the simulator to be incorporated into regular classroom lectures. Before using the simulator for on-campus practical training, instructors had used the simulator in class to give students a preview of image processing methods. We believe that students will be better able to operate the simulator during on-campus practical training if they have been shown how to process images in advance during lectures in the classroom. Therefore, we plan to incorporate this educational simulator into classroom education in the future. We also found that students’ interest in nuclear medicine technology increased after on-campus practical training using the simulator. Most students expressed a preference for working in general radiography, CT, or MRI after graduation. However, we hope to increase the number of students who are interested in nuclear medicine technology by exposing them to it during on-campus training.

The feedback provided in the free-text description section of the questionnaire was generally positive, including comments such as “It was great to be able to actually experience image processing” and “I was able to deepen my understanding of work in nuclear medicine technology.” These comments indicated that the experience gained by practical on-campus training, which cannot be acquired in classroom lectures, improved students’ level of understanding and satisfaction. We believe that this experience will increase undergraduates’ interest in nuclear medicine technology and improve their learning. However, there were some negative comments regarding the operation of the simulator. We intend to discuss these comments with the manufacturer in a way that will lead to further development of simulator use.

On the basis of our findings, we believe that on-campus practical training in nuclear medicine technology using a simulator is beneficial for students. The focus of curricula in medical schools has changed from classroom lectures to demonstrative methods that assess the abilities of learners (1). Our educational institutions that train nuclear medicine technologists are promoting education that emphasizes practical skills. Simulation education also includes active engagement in learning (5), and students can learn independently using simulators. Furthermore, simulation training is able to improve technical skills in a risk-free environment while eliminating the human factor (2). For this reason, simulation education is currently being promoted at educational institutions that train nuclear medicine technologists. We believe that simulator education will become an essential component of future education at all educational institutions that do not have access to diagnostic imaging modalities for training.

It is important to note that students learn at different rates. There were differences in basic knowledge among our students, which led to differences in the speed at which practical training progressed. Students who had basic knowledge and were proficient in the use of PCs finished their assignments early, such that they had to wait before moving on to the next assignment. Before the on-campus practical training, all students were encouraged to review the basic practical content and were instructed to study the simulator operating manual. In the future, we would like to make adjustments to the timing and implement practical training.

In addition, we would like to use a simulator during regular classroom lectures to give presentations to students on how to process images. When students are able to understand image processing to a reasonable extent, operating a simulator during on-campus practical training will further improve their level of understanding and satisfaction. Remote education has become established because of the coronavirus disease 2019 pandemic (6–10). Some educational institutions offer a mixture of face-to-face and remote lectures (11). We believe that the simulator is an ideal teaching aid for use in remote lectures. Moreover, the simulator is loaded with data from various modalities. Currently, only nuclear medicine technology training is conducted using this simulator during on-campus training. It is hoped that modalities other than nuclear medicine technology will soon be incorporated into on-campus practical training.

The main limitation of this research was that, although the SPECT/CT modality of the SmartSimulator allows image processing using SPECT data, it is not possible to observe the photographing operation. Because it is necessary to have experience in operating a γ-camera and taking pictures, consideration of these elements is also required.