Explore the vast range of titles available.

The use of acid to obscure human remains is a tactic frequently associated with criminal activity, yet research on its effects on human dentition remains inconsistent. Dental tissues, among the body's most durable components, play a vital role in forensic identification. However, existing studies on acid dissolution of dentition often lack standardized methods, resulting in findings that are difficult to reproduce or generalize. This study addresses these gaps by examining the effects of hydrochloric acid (HCl) on permanent maxillary molars under controlled conditions, using a replicable methodology that incorporates experimental controls and evaluates the impact of handling techniques such as removal, rinsing, and drying. Five permanent maxillary molar samples were submerged in HCl (37 %) under varied handling conditions. Findings reveal that undisturbed samples dissolved more slowly than those subjected to periodic removal and rinsing, which accelerated dissolution rates by over 100 %. This highlights the significant influence of handling techniques on experimental outcomes. The study also identifies inconsistent reporting and the absence of standardized protocols in prior research as critical barriers to reproducibility. By providing a clear and replicable framework, this study advances understanding of the dissolution process and emphasizes the importance of methodological rigor in forensic science. These findings have broader implications for improving the reliability of forensic evidence and ensuring its applicability in criminal investigations. Addressing these issues is essential for enhancing public trust in forensic methods and strengthening their role in the justice system. •Clear, replicable research is critical to maintaining credibility in forensic applications.•Variability in dentition studies reveals critical gaps in forensic science's methodological rigor.•Introducing controls in forensic research can significantly improve the accuracy of findings.•It found that handling methods, like periodic rinsing, accelerate tooth dissolution compared to undisturbed conditions.•This study explores how hydrochloric acid affects human molars using a controlled, replicable approach.

(1) Teeth, in humans, represent the most resilient tissues. However, exposure to concentrated acids might lead to their dissolving, thus making human identification difficult. Teeth often contain dental restorations from materials that are even more resilient to acid impact. This paper aims to introduce a novel method for the 3D reconstruction of dental patterns as a crucial step for the digital identification of dental records. (2) With a combination of modern methods, including micro-computed tomography, cone-beam computer tomography, and attenuated total reflection, in conjunction with Fourier transform infrared spectroscopy and artificial intelligence convolutional neural network algorithms, this paper presents a method for 3D-dental-pattern reconstruction, and human remains identification. Our research studies the morphology of teeth, bone, and dental materials (amalgam, composite, glass-ionomer cement) under different periods of exposure to 75% sulfuric acid. (3) Our results reveal a significant volume loss in bone, enamel, dentine, as well as glass-ionomer cement. The results also reveal a significant resistance by the composite and amalgam dental materials to the impact of sulfuric acid, thus serving as strong parts in the dental-pattern mosaic. This paper also probably introduces the first successful artificial intelligence application in automated-forensic-CBCT segmentation. (4) Interdisciplinary cooperation, utilizing the mentioned technologies, can solve the problem of human remains identification with a 3D reconstruction of dental patterns and their 2D projections over existing ante-mortem records.