Year : 2009 | Volume
: 1 | Issue : 2 | Page : 93--98
Effect of acids on the teeth and its relevance in postmortem identification
Kiran Jadhav, Nidhi Gupta, BR Ahmed Mujib, Vikram S Amberkar
Department of Oral and Maxillofacial Pathology, Bapuji Dental College, Davangere, Karnataka, India
Department of Oral & Maxillofacial Pathology, Bapuji Dental College & Hospital, Davangere, Karnataka
Background: The nature of crime is changing day by day and the forensic scientist is always facing new problems in the process of identification. For example, difficult though it may be to believe, criminals are now-a-days using acids to destroy bodies in order to avoid any personal identification. This is a matter of great interest to the forensic scientist. Is it possible to destroy the human body completely in an acid? If so, are there any means to identify the body? Objectives: The aim of this study was to identify the agent (acid) that is most likely to be used in such crimes and to find out if the morphological changes in the teeth could be used to deduce the approximate duration of time elapsed after immersion of a body in an acid. Since the natural teeth are most resistant to destruction they can persist for long after other skeletal structures have been destroyed by physical agents. The objective of study was to observe the morphological changes occurring in natural human teeth when they were kept immersed in an acid solution. Materials and Methods: Teeth were kept in 25 ml of aqueous solutions of three different acids and observed periodically for morphological changes. Results: The results showed that teeth could be completely dissolved in 37% hydrochloric acid (HCl) after 15 h of immersion, whereas in 65% nitric acid 20 h was required for complete dissolution. In the case of 96% sulphuric acid, the teeth reacted in a different manner. There was a residual precipitate observed at the bottom of the container after 144 h. It was possible to identify the characteristic morphological changes in the tooth until an advanced stage of degradation. Conclusion: Hydrochloric acid, nitric acid and sulfuric acid cause changes in the teeth and it is possible to deduce the approximate duration for which a body has been immersed in acid based on the charges observed.
|How to cite this article:|
Jadhav K, Gupta N, Ahmed Mujib B R, Amberkar VS. Effect of acids on the teeth and its relevance in postmortem identification.J Forensic Dent Sci 2009;1:93-98
|How to cite this URL:|
Jadhav K, Gupta N, Ahmed Mujib B R, Amberkar VS. Effect of acids on the teeth and its relevance in postmortem identification. J Forensic Dent Sci [serial online] 2009 [cited 2020 Jul 16 ];1:93-98
Available from: http://www.jfds.org/text.asp?2009/1/2/93/60381
The practice of destroying the human body by immersing it in an acid or some other caustic substance in order to avoid any personal identification is drawing a great deal of forensic interest these days. Crimes of this nature have been frequently reported in Italy. 
The forensic scientist needs to know whether it is possible to destroy the human body partially or totally by immersing it in an acid and, if so, how much time is necessary for its complete destruction. Another important question is whether there are any means of identifying the deceased individual from the residual remains.
Literature search revealed that there are very few studies that have actually focused on the issue of destruction of the human body by chemical means and the issue of positive identification after acid dissolution. There is brief mention in the Italian journal Archivio di Medicina Legale of an experimental animal destruction in an acidic environment. 
The identification of dental remains is of prime importance when the deceased person is skeletonized, decomposed, burned, or dismembered.  Joanna et al. have used various kinds of acids at various concentrations to compare the different decalcification methods for teeth.  It is well known that forensic odontological techniques help in the identification of an individual. Since the natural teeth are the most durable of all tissues, they can persist even long after other skeletal structures have been destroyed by physical agents. Further, it is now possible to extract DNA even decades after death. It is possible to employ these identification techniques until there has been complete destruction of the teeth. ,
The aim of this study was to identify the acid that may be used by criminals for destruction of a human body and to find out the approximate time taken for total destruction of a body after immersion in an acid. The objective was to observe the morphological changes in natural human teeth when they were kept immersed in an acid.
Materials and Methods
Sixty extracted human natural teeth were used for the study. All teeth were non-carious and had been extracted because of periodontal reasons. The teeth were kept in a dry environment at room temperature before the start of the experimental procedure.
The following acids were used in this study:
Aqueous solution of hydrochloric acid (HCl): 25 ml (14.6 ml of 37% HCl + 10.4 ml of water)Aqueous solution of nitric acid (HNO 3 ): 25 ml (16.25 ml of 65% HNO 3 + 8.75 ml of water)Aqueous solution of sulfuric acid (H 2 SO 4 ): 25 ml (24 ml of 96 % H 2 SO 4 + 1 ml of water)Teeth samples were divided into three groups as follows:
Hydrochloric acid (HCl) group: 20 extracted teethNitric acid (HNO 3) group: 20 extracted teethSulfuric acid (H 2 SO 4 ) group: 20 extracted teethThe teeth were immersed separately in different containers containing the three different acids. At various intervals (30 min, 1 h, 2 h, 4 h, 8 h, 15 h, 20 h, 24 h, 48 h, 72 h, 96 h, 120 h, and 144 h) the samples were taken out of the container and examined for any morphological changes; they were then photographed and placed back in the containers. The specimens were under observation until they had completely dissolved or completely precipitated.
We used Fisher's exact test to assess the significance of the morphological changes seen in a particular acid at a particular time.
The morphological changes observed in teeth following immersion in 37%HCI, 65% HNO 3 and 96% H 2 SO 4 are tabulated in [Table 1] and [Figure 1],[Figure 2],[Figure 3].
Hydrochloric acid group
There was effervescence in the solution after 30 min. Following this transparency was observed at the incisal edge; this progressively increased. After 4 h of immersion, disintegration of the crown and root was noticed. After 8 h of immersion in HCl, there was near complete dissolution of the tooth except for some remnants; these too had completely dissolved after 15 h [Figure 1] and [Figure 4].
Nitric acid group
There was effervescence in the solution and a yellow-colored residue was deposited over the tooth. This progressively increased until it had covered the entire tooth specimen. There was initiation of disintegration, which first involved the crown in the form of a vertical line running cervico-incisally/occlusally. This was followed by the disintegration of the root, beginning at the apical portion and progressing to involve the middle third. The teeth then exhibited a tendency for vertical splitting. After 15 h of immersion there was nearly complete dissolution of the tooth except for some remnants, which too had completely dissolved by 20 h [Figure 2] and [Figure 5].
Sulfuric acid group
There was no alteration observed in the tooth structure up to 4 h of immersion. After 8 h there was a slight white precipitate deposited over the tooth and at the bottom of the container. This white precipitate increased with time. At 24 h there was fragmentation of the tooth, which increased with the passage of time. The tooth could be recognized up to 120 h after immersion. After 144 h, the tooth had completely disintegrated and only the precipitate was observed [Figure 3] and [Figure 6].
The use of teeth in this study is justified by the evidence that the natural teeth are the most durable of all tissues. They can persist even long after other skeletal structures have been destroyed by physical agents. We used non-carious teeth because caries can modify the behavior of teeth when they are placed in an acid; there may be acceleration of destruction process because of cavitation secondary to caries. ,
In the case of 37% HCI and 65% HNO 3 the teeth were completely dissolved because of the chemical reaction that leads to the formation of a completely soluble salt. , The reaction is as follows:
In case of HNO 3 , the color change in the form of the yellow-colored deposit was mainly because of the nitrate formed in the chemical reaction, which is as follows , :
In the case of H 2 SO 4 there was no dissolution; instead, a white precipitate was formed. This was due to the formation of a non-soluble salt. The chemical reaction is as follows , :
Thus, there are clear differences in the destructive capacities of the different acids used in this study. The information derived in this study on the morphological changes observed in teeth after particular periods of immersion in an acid solution [Table 1] can be utilized for identification of the acid used and to deduce the approximate duration of immersion in the acid. The observed morphological changes may vary when the concentration of the acid used is different from that used in the present study; however, it must be noted that the concentrations that we have used are the ones that are most commonly available commercially.
Some other factors have also to be considered. For complete dissolution of body a minimum of 80-100 liters of acid is required.  Criminals will always be guided in their choice by ease of availability of the acid, cost, and efficiency of action. They will be more likely to use an acid that is easily available, cheap, and with the ability to destroy the body rapidly. Our investigations regarding the availability of the different acids showed that hydrochloric acid and sulfuric acid are more easily available commercially than is nitric acid. As far as the cost factor is concerned, hydrochloric acid is cheaper than sulfuric acid and nitric acid. 
Thus, based on these observations and our experimental results, we conclude that it is 37% hydrochloric acid that would be most likely used in such crimes. However, we must add that it is always advisable to carry out the usual biochemical tests to check which acid has been used. 
Recognizable morphological appearances of teeth persisted for 8 h in HCI, for 15 h in HNO 3 , and for up to 96 h in H 2 SO 4 . The morphological characteristics help the investigator in deciding whether the tooth is of human or animal origin, single or multi-rooted, deciduous or permanent, and restored or unrestored.
In situations where it is impossible to identify the dental structures, other investigations can be considered,  such as:
Chemical / histological analysis of the residuesDNA analysis (mitochondrial) of the residues Chemical analysis of the final residual solution Various studies have described the use of dental records in forensic identification. However, for this, antemortem dental records must be available.  DNA analysis, which has brought about a revolution in the field of forensic science, including forensic dentistry, anthropology, and archeology, has made identification easier and more accurate. 
Admittedly, the persent study does not take into account the influences of all possible factors that may be present in real life conditions. For example, the protection provided by the soft and hard tissues surrounding the teeth makes the root part more resistant to acid insults. Also, these findings obviously do not apply in the case of victims whose teeth have been replaced by prosthetic appliances.
It is possible to destroy the human body completely in an acid. In crimes of this nature, hydrochloric acid is the most commonly used acid. Morphological changes in teeth can help the forensic investigator to deduce the time elapsed since immersion of the body in the acid. By keeping in mind the likely choices of the criminal and by observing the morphological changes in the teeth, it may be possible to deduce which acid has been used to destroy the body. However, the final decision on which acid has been used should be based on biochemical tests.
We sincerely thank Dr. Yashwant, Assistant Professor, Department of Oral and Maxillofacial Surgery, College of Dental Sciences, Davangere, for his help and co-operation for the study. We also extend our thanks to Mr. A.G. Wandre, Professor, Department of Chemistry, Devchand College of Higher Education, Arjun Nagar, Maharashtra, and Dr U.R. Syed Mukith, Assistant Professor, Department of Oral Pathology, Rajiv Gandhi Dental College, Bangalore, for their help in formatting the manuscript.
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