|Year : 2019 | Volume
| Issue : 3 | Page : 151-155
Sex determination using mandibular canine among Northeastern Nigerian population
Saleh Nuhu1, Babagana Mohammed Dalori2, Lawan Hassan Adamu3, Isyaku Ibrahim1, Maryam Nasir Aliyu1
1 Department of Human Anatomy, Faculty of Basic Medical Sciences, Northwest University, Kano State, Nigeria
2 Department of Human Anatomy, College of Medical Sciences, University of Maiduguri, Maiduguri, Borno State, Nigeria
3 Department of Anatomy, Faculty of Basic Medical Sciences, Bayero University, Kano State, Nigeria, Nigeria
|Date of Web Publication||18-Sep-2019|
Department of Human Anatomy, Faculty of Basic Medical Sciences, Northwest University, PMB 3220 Kano, Kano State
Source of Support: None, Conflict of Interest: None
Establishing a person's identity is important for both legal and humanitarian purposes. Sex determination is a key characteristic used in the identification of a deceased individual. The aim of this study was to determine sex by using mandibular canines among individuals in the Northeastern Nigerian population. Two hundred and eight individuals (102 men and 106 women) participated in this study. The mesiodistal widths of the mandibular canines and intercanine distances were measured using a vernier caliper and a divider. Step-wise logistic regression analyses were used to determine sex based on mandibular parameters. Male participants had significantly higher mandibular mesiodistal width than female participants. Similarly, the canine index was significantly higher in male participants than in female participants. The mesiodistal width of the left mandibular canine exhibited the highest sexual dimorphism (9.78%) and was the best characteristic for use in determining sex, with an accuracy of 75%. Among the Northwestern Nigerian population, sex can be most accurately determined using the mesiodistal width of the left mandibular canine.
Keywords: Forensic sciences, mandibular canine, Northeastern Nigeria, sex determination
|How to cite this article:|
Nuhu S, Dalori BM, Adamu LH, Ibrahim I, Aliyu MN. Sex determination using mandibular canine among Northeastern Nigerian population. J Forensic Sci Med 2019;5:151-5
|How to cite this URL:|
Nuhu S, Dalori BM, Adamu LH, Ibrahim I, Aliyu MN. Sex determination using mandibular canine among Northeastern Nigerian population. J Forensic Sci Med [serial online] 2019 [cited 2020 Nov 25];5:151-5. Available from: https://www.jfsmonline.com/text.asp?2019/5/3/151/267154
| Introduction|| |
Determining the sex of individuals involved in traffic accidents, bomb explosions, mass murders, or natural disasters is among the top priorities of a forensic investigator. Forensic identification of human remains is important for reconstructing an individual's profile from unidentified skeletal remains., Teeth are known to resist various forms of postmortem destruction. Crowns of permanent teeth are formed at an early stage of development, and their dimensions remain unchanged during further growth and development, except when specific changes and disorders of functionality, pathology, and nutrition influence the normal dimensions of teeth.
Often, canines are the last teeth to be extracted in older individuals, as they are least affected by abrasion from brushing, bear lesser occlusal loading, and are less affected by periodontal disease. Thus, they are regarded as the “key teeth” for personal identification;, this characterization is supported by their high degree of sexual dimorphism among all teeth.,,
As there are differences in odontometric features within specific populations, it is critical to determine specific population values to facilitate identification on the basis of odontometric measurements. To determine the existence of sexual dimorphism, which is instrumental in sex determination for forensic investigation, and to determine the best predictor of sex based on the mesiodistal dimension of permanent mandibular canines and intercanine distances among men and women in the Northeastern (NE) Nigerian population, the present study evaluated the mesiodistal dimension of permanent mandibular canines and intercanine distances in the NE Nigerian population.
| Materials and Methods|| |
The study was conducted at the University of Maiduguri in the NE region of Nigeria.
The study population comprised 208 students (102 men and 106 women, 17–35 years of age), at the University of Maiduguri. Individuals were included if they had a complete set of fully erupted, morphologically well-formed, periodontally healthy, noncarious, nonworn, nonhypoplastic teeth, including satisfactorily aligned mandibular teeth. All individuals provided informed consent to participate in the study. Individuals who had carious, restored, or hypoplastic teeth, as well as those who had teeth with prosthesis, attrition, abrasion, and/or mobility, were excluded from the study. This study was approved by the ethical committee of the institution.
Collection of biodata
A brief questionnaire (See Appendix) was completed for all participants, with age, sex, nationality, state of origin, measurement of the mesiodistal widths of their mandibular canines, mandibular intercanine distances (MnCDs), and mandibular canine indices (MnCIs).
The sliding vernier caliper (Tresna; Guilin, Guangxi, China) and manual divider (Starrett; Athol, Massachusetts, USA) used in the study were disinfected with chloroxylenol 4.8% after each use.
Mandibular canine width
The maximum mesiodistal dimensions of the two permanent mandibular canines were measured between the anatomic contact points directly on the participant, using a sliding vernier caliper with a resolution of 0.02 mm, held parallel to the occlusal plane in accordance with the method of Gupta et al. If the placement of the sliding vernier caliper was determined to be difficult, a manual divider with a fixing device and very fine tips was used, as shown in [Figure 1]. Subsequently, the divider distance was measured with the vernier caliper.
Mandibular intercanine distance
The MnCD was measured as the linear distance between the tips of the right and left mandibular canines when a divider was placed on the tip of the right canine and extended to the left canine, as shown in [Figure 2].
Mandibular canine indices and percentage sexual dimorphism
The formula used to calculate the MnCI was based on the method of Rao et al. as follows:
The percentage of sexual dimorphism was calculated using the formula given by Garn et al. as follows:
Where Xm= mean value of male participants, and Xf= mean value of female participants.
The data collected were entered in a spreadsheet (Excel 2013, Microsoft Corp., Redmond, WA, USA) and analyzed using SPSS statistical analysis software (version 20, IBM Corp., Armonk, NY, USA). Student's t-test was used to compare differences between the sexes. Sex was predicted based on mesiodistal width, intercanine distance, and mandibular canine index using step-wise binary logistic regression analysis. P < 0.05 was considered statistically significant.
| Results|| |
[Table 1] shows that there were statistically significant differences in the mean right mesiodistal mandibular canine width (MnCW) between the male and female participants (8.03 ± 0.65 mm and 7.38 ± 0.56 mm, respectively). Similarly, there was a statistically significant difference between the male and female participants in the mean left mesiodistal MnCW (8.08 ± 0.71 mm and 7.36 ± 0.56 mm, respectively). The right and left mean MnCIs were significantly different between the male and female participants (right MnCI: male participants, 2.88 ± 0.27 mm, and female participants, 2.69 ± 0.30 mm; left MnCI: male participants 2.90 ± 0.29 mm, and female participants, 2.66 ± 0.23 mm).
|Table 1: Mean mesiodistal and intercanine widths of mandibular canines in male and female participants using Student's t-test|
Click here to view
Furthermore, the left mesiodistal MnCW showed the greatest sexual dimorphism (9.78%), whereas MnCD showed the least dimorphism (0.79%). Moreover, proportions of sexual dimorphism for right MnCI, right mesiodistal MnCW, and left MnCI were 7.06%, 8.81%, and 9.02%, respectively [Table 2].
|Table 2: Sexual dimorphism in mandibular canine measurements between male and female patients|
Click here to view
All logistic regression equations discriminated sex at a rate better than that achieved by chance, with the value of Chi-square ranging from 58.995 to 68.103, P < 0.05. With respect to sex discrimination, left mesiodistal MnCW was the single best predictor of sex with 75% accuracy and a higher level of misclassification (Log2 likelihood = 229.278) than all other equations. However, the percentage accuracy decreased to 73.1% when three variables (left mesiodistal MnCW, right mesiodistal MnCW, and left MnCI) were included in the equation [Table 3].
|Table 3: Logistic regression equations for sex discrimination based on mandibular canine measurements|
Click here to view
| Discussion|| |
Odontometry has been performed on various tooth groups with the objective of establishing measurements that can serve as standards in dental surgery and forensic odontology. Dental identification involves either a comparative method or postmortem dental profiling. The main advantage involved in the use of dental evidence for identification is that it can be preserved nearly indefinitely after death. The unique patterns of teeth enable the analysis of antemortem and postmortem dental variables.
Various odontometric dimensions have been used for the purpose of sex estimation such as MnCI, the buccolingual dimension of the teeth, and the height of the teeth. Garn et al. studied the magnitude of sexual dimorphism by measuring the mesiodistal width of canine teeth and showed that mandibular canines showed a greater degree of sexual dimorphism than maxillary canines. However, Minzuno  reported that maxillary canines showed a greater degree of sexual dimorphism than mandibular canines in a Japanese population. This notable discrepancy in the use of canines for determining sex was presumed to be due to the influence of the Y chromosome, which was not uniform in all teeth. In contrast, the X-linked genetic influence on tooth width was relatively uniform in all teeth. Furthermore, the mean mesiodistal MnCW recorded in this study was similar to that observed in a North Indian population, but greater than those obtained in Egyptian, South Indian, and Croatian populations. This distinction may be due to differences in geographical location, genetic makeup, and dietary habits.
The accuracy of odontometric analysis for gender determination was investigated by Pettenati-Soubayroux et al. who studied sexual dimorphism in the permanent teeth of 146 skeletons dating from 1722 AD in Marseilles. Pettenati-Soubayroux et al. found lower canines to be the most accurate teeth for the analysis of dental sexual dimorphism; they recommended the use of this method to determine sex in fragmentary adult skeletons, immature materials, missing pieces, or ambiguities on postcranial remains in forensic medicine and anthropology.
To predict sex based on body variables, some researchers use discriminate function analysis, whereas others use logistic regression analysis. Shah et al. reported that logistic regression analysis provided greater accuracy than discriminate function analysis. Notably, we used logistic regression analysis to predict sex in the present study. Based on the analysis of sexual dimorphic traits, we found that the left mesiodistal MnCW was the best predictor of sex in the study population. However, ideal variables to predict sex are known to vary among populations, such that region-specific equations are needed.
Although DNA profiles give accurate results, measurements of linear dimensions (e.g., anthropometric or odontometric parameters) can be used to determine sex in a large population because these measurements are simple, reliable, and inexpensive. In the context of several mass murders and occupation of Boko Haram insurgents in the NE region of Nigeria, there is a need of a simple, reliable, and inexpensive method that can be used in the identification of individuals. The present study findings thus can be used in determining sex among individuals in the NE Nigerian population.
Despite the dimorphic nature of the dimensions considered in the study, different measurements can serve as predictors with varying degrees of accuracy. The sex of an individual in NE Nigeria can better be determined using a single mandibular canine tooth variable – left mesiodistal MnCW – with 75% accuracy. Although the 75% accuracy suggests that it could be increased by combination with other variables, the accuracy decreased when other variables were included in the prediction equation. Therefore, the results of this study indicate that left mesiodistal MnCW comprises the best predictor of sex among individuals in the NE Nigerian population. However, this study was limited in that it only assessed individuals aged 17–35 years. Therefore, a degree of caution is needed when attempting to generalize the data obtained in this study to individuals outside of this age range.
Sex determination based on skeletal remains constitutes the most important aspect of identification in the context of medicolegal examinations. This study determined sexual dimorphism and the potential for the use of mandibular canine tooth measurements in the sex determination of individuals in the NE Nigerian population. Among the parameters assessed in this study, left mesiodistal MnCW comprised the best predictor of sex among individuals in the NE Nigerian population.
We thank Ryan Chastain-Gross, Ph.D., from Liwen Bianji, Edanz Group, China (www.liwenbianji.cn/ac), for editing the English text of a draft of this manuscript.
Financial support and sponsorship
Conflicts of interest
There are no conflicts of interest.
| Appendix|| |
This is a study on “sex determination using mandibular canine measurements in the Northeastern Nigerian population” which will provide baseline data regarding the population of Northeastern Nigeria. Kindly spare your time, as it will require just a few minutes. Thank you.
State of origin_____________________
Mandibular canine measurements
| References|| |
Ramakrishnan K, Sharma S, Sreeja C, Pratima DB, Aesha I, Vijayabanu B. Sex determination in forensic odontology: A review. J Pharm Bioallied Sci 2015;7:S398-402.
Khangura RK, Sircar K, Singh S, Rastogi V. Sex determination using mesiodistal dimension of permanent maxillary incisors and canines. J Forensic Dent Sci 2011;3:81-5.
] [Full text]
Baoz K, Gupta C. Dimorphism in human maxillary and mandibular canines in establishment of gender. J Forensic Dent Sci 2009;1:42-4.
Kaushal S, Patnaik VV, Agnihotri G. Mandibular canines in sex determination. J Anat Soc India 2003;52:119-24.
Vodanovic M, Demo Z, Njemirovskij V, Keros J, Brkic H. Odontometrics: A useful method for sex determination in an archaeological skeletal population. J Archaeol Sci 2007;34:905-13.
Mohammed QA, Abdullah MA, Ashraf I, Khan N. Dimorphism of mandibular and maxillary canine teeth in establishing identity. Saudi Dent J 1997;9:17-20.
Anderson DL, Thompson GW. Interrelationships and sex differences of dental and skeletal measurements. J Dent Res 1973;52:431-8.
Dahlberg AA. Forensic dentistry. J Am Dent Assoc 1976;93:991-5.
Vishwakarma N, Guha R. A study of sexual dimorphism in permanent mandibular canines and its implications in forensic investigations. Nepal Med Coll J 2011;13:96-9.
Ibeachu PC, Didia BC, Orish CN. Sexual dimorphism in mandibular canine width and inter canine distance of university of Port-Harcourt student, Nigeria. Asian J Med Sci 2012;4:166-9.
Işcan MY, Kedici PS. Sexual variation in bucco-lingual dimensions in Turkish dentition. Forensic Sci Int 2003;137:160-4.
Gupta S, Chandra A, Gupta OP, Verma Y, Srivastava S. Establishment of sexual dimorphism in North Indian population by odontometric study of permanent maxillary canine. J Forensic Res 2014:5:224.
Ahmed HM. Genders Identification using mandibular canines: Iraqi study. J Baghdad Coll Dent 2014;26:150-3.
Rao NG, Rao NN, Pai ML, Kotian MS. Mandibular canine index – A clue for establishing sex identity. Forensic Sci Int 1989;42:249-54.
Garn SM, Lewis AB, Swindler DR, Kerewsky RS. Genetic control of sexual dimorphism in tooth size. J Dent Res 1967;46:963-72.
Rai B, Anand SC, Bhardwaj DN, Dhattarwal SK. Gender determination from odontometery. Int J Dent Anthrop 2006;9:8-12.
Kaushal S, Patnaik VV, Sood V, Agnihotri G. Sex determination in North Indians using mandibular canine index. J Indian Acad Forensic Med 2004;26:45-9.
Minzuno O. Sex determination from maxillary canine by Fourier analysis. Nihon Univ Dent J 1990;2:139-42.
Omar A, Azab S. Applicability of determination of gender from odontometric measurements of canine teeth in a sample of adult Egyptian population. Cairo Dent J 2009;167:180.
Kapila R, Nagesh KS, R Iyengar A, Mehkri S. Sexual dimorphism in human mandibular canines: A radiomorphometric study in South Indian population. J Dent Res Dent Clin Dent Prospects 2011;5:51-4.
Pettenati-Soubayroux I, Signoli M, Dutour O. Sexual dimorphism in teeth: Discriminatory effectiveness of permanent lower canine size observed in a XVIII century osteological series. Forensic Sci Int 2002;126:227-32.
Shah T, Patel MN, Nath S, Menon SK. Determination of sex using cephalo-facial dimensions by discriminant function and logistic regression equations. Egypt J Forensic Sci 2016;6:114-9.
Campbell J. U. S. Policy to Counter Nigeria's Boko Haram; Council Special Report. New York, USA: Council on Foreign Relations; 2014.
[Figure 1], [Figure 2]
[Table 1], [Table 2], [Table 3]