论文信息 - Implantation of an RFID-tag into human molars to reduce hard forensic identification labor. Part 2: physical properties.

Implantation of an RFID-tag into human molars to reduce hard forensic identification labor. Part 2: physical properties.

Modifying and implanting existing RFID-tags into extracted human molars was described previously [P. Thevissen, G. Poelman, B. Puers, M. De Cooman, G. Willems, Implantation of RFID-tag into human molars to reduce hard forensic identification labor. Part 1. Working principle, Forensic Sci. Int. 156 (2006)]. Maximal vertical occlusal load during which the implanted RFID-tags remain active was evaluated in vitro. The temperature dependency of the implanted RFID-tags was studied on the extracted teeth to find out the maximal obtainable temperature before failure and a test with embedded thermistors to verify temperature distributions. The maximal working temperature of the implanted RFID-tags was revealed and gave indications for the set-up of measuring intra oral and intra tooth temperature during the cremation of a human body. Fatigue was induced on the implanted teeth by thermocycling. The results of this investigation showed the need of putting an extra insulating layer around the modified tags before implantation. The different in vitro tests indicated that the implanted RFID-tags can support certain oral and forensic circumstances.

[1] Thomas Euler,et al. In vivo validation of the historical in vitro thermocycling temperature range for dental materials testing , 2004, Clinical Oral Investigations.

[2] Tore Solheim,et al. Odontological identification of fire victims —potentialities and limitations , 2005, International Journal of Legal Medicine.

[3] Robert Puers,et al. Implantation of an RFID-tag into human molars to reduce hard forensic identification labor. Part I: working principle. , 2006, Forensic science international.

[4] A. Osculati,et al. Observations on dental prostheses and restorations subjected to high temperatures: experimental studies to aid identification processes. , 2002, The Journal of forensic odonto-stomatology.

[5] C. Barclay,et al. A pilot study of intraoral temperature changes. , 2000 .

[6] B. Darvell,et al. Thermal cycling procedures for laboratory testing of dental restorations. , 1999, Journal of dentistry.

[7] R. Frankenberger,et al. Evaluation of the fatigue behavior of the resin-dentin bond with the use of different methods. , 2003, Journal of biomedical materials research. Part B, Applied biomaterials.

[8] J T Watts,et al. Intra-oral temperature variation over 24 hours. , 1999, European journal of orthodontics.

[9] M. Barco,et al. Temperature extremes produced orally by hot and cold liquids. , 1992, The Journal of prosthetic dentistry.