Background: Dental caries is one of the most common oral diseases worldwide, significantly impacting patients' oral health and quality of life. Early diagnosis and treatment are crucial to prevent further deterioration. Traditional X-ray examinations, while providing detailed images, pose issues such as radiation exposure and limited resolution. Optical Coherence Tomography (OCT) is a non-invasive, high-resolution, and radiation-free imaging technique that has achieved significant success in fields like ophthalmology. OCT can provide real-time, micron (μm)-level cross-sectional images of biological tissues and generate threedimensional images. Although commercial OCT devices became available five years after its invention, its application in dentistry remains primarily at the research stage, highlighting challenges in scanning hard dental tissues. The main challenges include: (1) imaging depth and quality being limited by optical systems and the optical properties of teeth; (2) OCT image contrast relying on the distribution of optical properties within the tooth, with the linear arrangement of enamel prisms and dentinal tubules causing anisotropy and birefringence effects. Purpose: This study aims to evaluate the effectiveness of OCT in detecting dental hard tissues and caries, and to compare it with other imaging techniques such as X-rays and Cone Beam Computed Tomography (CBCT) to determine the advantages and limitations of OCT in caries diagnosis. Additionally, the study explores methods to enhance OCT image quality using high refractive index fluids (e.g., glycerin), and investigates the application of multi-angle scanning and color mapping techniques in OCT imaging, assessing their impact on image clarity and diagnostic accuracy. Furthermore, OCT will be used to measure dental tissue thickness to examine its accuracy. It is hoped that OCT can provide more precise and effective technical support for clinical dental diagnosis. Materials and methods: In this study, multiple tooth samples were collected and scanned using a Swept-Source Optical Coherence Tomography (SS-OCT) system. First, the tooth samples were cleaned and numbered, and then specific locations were selected for SS-OCT scanning. Additionally, visual examination, X-ray examination, and CBCT examination results were recorded to evaluate the accuracy of these methods in detecting caries. The image optimization experiment was divided into three parts: first, observing the optimization effects of images after applying glycerin; second, using multi-angle image synthesis techniques, including images from the front and 5-degree rotations to the left and right, and comparing these images with those without glycerin application and with Micro-CT images; and third, attempting to use color mapping techniques to mark caries lesion areas to enhance image visualization. The comparison of images used Micro-CT images as the gold standard. Both Micro-CT and OCT images were imported into Amira® 3D Pro (Thermo Fisher Scientific, USA) software for 3D image reconstruction and data analysis. Finally, the SS-OCT system was used to measure the thickness of the tooth structure to verify its accuracy and feasibility. Statistical analysis and plotting were performed using the data analysis functions in Excel software. Results: The research results indicate that OCT can clearly reveal the structural characteristics of carious lesions and has high sensitivity and accuracy in the early detection of dental caries. Compared to X-rays and CBCT, OCT has advantages in non-invasive diagnosis, particularly in avoiding radiation exposure and providing higher resolution images. After applying glycerin, the contrast and clarity of OCT images significantly improve, and the imaging depth is also enhanced. Multi-angle scanning and image synthesis techniques increase the amount of image information, further improving image quality. Additionally, the use of color mapping techniques makes the carious lesion areas in OCT images more intuitive and easier to identify. Measurements of tooth thickness show a high linear correlation between manual measurements and OCT data, but when the sample thickness exceeds 2mm, the discrepancy between manual measurements and OCT measurements increases significantly. Conclusion: OCT shows great potential in early caries detection, providing radiation-free, high resolution images of dental structures. Compared to traditional X-ray and CBCT techniques, OCT offers higher sensitivity and accuracy in the diagnosis of early caries, providing a safer and more effective diagnostic tool for clinical dentistry. The use of glycerin can further enhance the quality of OCT images. Multi-angle scanning and image synthesis techniques can increase image information, improving image clarity and contrast. The color mapping technique makes the visualization of caries lesions more intuitive. The results of measuring the dental tissue thickness demonstrate the feasibility of using OCT for this purpose. Future research should focus on promoting the clinical application of OCT technology and exploring more methods to improve image quality.