A comparative study of Palatal rugae patterns among Igbo and Ikwerre ethnic groups of Nigeria: a University of Port Harcourt study.
The appropriate method for human identification is of paramount importance in the field of forensics science. Palatal rugae are epithelial ridges on anterior part of palatal mucosa on each side of mid-palatine raphe behind incisive papilla. They are protected from trauma and high temperatures because of their internal position in the oral cavity, surrounded and protected by lips, cheeks, tongue, teeth, and bone (Kamala et al. ). In the literature there is consensus opinion that palatal rugae remain fairly stable in number and do not undergo any change due to growth, ageing, tooth extraction, and disease [2-4]. Morphological changes may occur due to trauma, surgery, persistent pressure, and proliferative benign and malignant lesions . Once formed, it only changes in its length, due to normal growth, staying in the same position throughout the life of a person (Bharath et al. ). combination patterns amongst the Palatal rugae have been studied for various reasons, most important one being personal identification . Though rugoscopy can be used in forensic identification, few studies have questioned this application in patients undergoing orthodontic treatment and in edentulous patients because of the chances of change in rugae pattern over a period of time in these patients [6, 7]. Nevertheless in patients undergoing orthodontic treatment, changes in the length of the rugae have been reported while the pattern remains unchanged [2, 6]. Palatal rugae appear to possess the features of an ideal forensic identification parameter because of its uniqueness, postmortem resistance, and stability. In addition, rugae pattern may be specific to racial and sex groups facilitating population identification which may be required after a disaster. In fact, differences in rugae pattern have been found in relatively similar population groups (Kapali et al. ). It has been reported that no similarity exists in palatal rugae patterns of siblings, twins, and even their parents (Faisal et al.  and Kamala et al. ). Studies have shown that certain rugae patterns are specific to a particular population (Kapali et al. , Nayak et al. , Arora et al. , Bajracharya et al. , Kiran Shetty et al. , and Shetty et al. ).
Hence palatal rugae might be of immense help in identification of individuals in Forensic Odontology, provided both ante- and postmortem details are available Bajracharya et al., .
However, the use of palatal rugae patterns in human identification has not been reported in the population of study. This work is therefore aimed at investigating the different rugae patterns among Igbo and Ikwerre ethnic groups of Nigeria.
2. Materials and Methods
The study consisted of 140 healthy human subjects between 18 and 35 years of age who were randomly selected. The sample size is comprised of 70 Igbo (males and females) 70 Ikwerre (males and females). The subjects were briefed regarding the procedure and nature and only those who gave their informed consent and showed keen cooperation participated in the study. Questionnaire method was used to ascertain their ethnicity (three generations proved ethnicity), family history, and health issues. This study was conducted at the dental center of the University of Port Harcourt Teaching Hospital, Rivers State, South-South Nigeria.
2.1. Ethical Considerations. Research Ethics Committee of the College of Health Sciences, University of Port Harcourt, approved the study.
2.2. Exclusive Criteria. The subjects with congenital anomalies/malformations, previous orthognathic surgery, bony and soft tissue protuberances, active lesions, deformity or scars, and trauma of the palate were not selected. Also, subjects who were wearing partial dentures and braces were excluded.
2.3. Inclusive Criteria. Normal subjects, whose parents and grandparents are of Igbo and Ikwerre origins within University of Port Harcourt, are included.
2.4. Methodology. The subjects were made to sit upright on the dental chair. The alginate paste was prepared by mixing the alginate impression powder (Spofadental, A Kerr Company, LOT: 2302461) with water as instructedbythe manufacturer. Maxillary impressions of the subjects were taken using a perforated impression tray loaded with an alginate. Dental casts were made with type 4 dental stone (Spofadental A Kerr Company, LOT: 4511215). The rugae were highlighted by a black pen marker on the cast under spotlight and recorded while the length was measured with a digital caliper calibrated to 0.0 mm.
2.5. Method of Identification. The study was based on the classification given by Thomas and Kotze  and Kapali et al. .
Length of Rugae. The length of rugae is as follows:
fragmentary (<3 mm),
secondary (3-5 mm),
primary (>5 mm).
Shape of Rugae. The shapes of individual rugae were classified into 4 major types.
Curvy: the curved type had a simple crescent shape with a gentle curve.
Wavy: the wavy rugae were serpentine (snake-like) in shape.
Straight: the straight types ran directly from their origin to insertion.
Circular: they are classified as rugae that showed definite continuous ring formation.
Unification. This occurs when two rugae are joined at their origin or termination. Unification is classified into two categories.
Diverging: rugae were considered to be diverging if two rugae had the same origin but immediately branched.
Converging: rugae were considered to be converging if two rugae with different origins join on their lateral portions.
2.6. Statistical Analysis. The total numbers of the various rugae patterns were counted, the percentages were recorded, and pie charts were used to describe the distribution of the various patterns within the tribes. Z-test was used to compare the difference in the mean values of the classified length as well as proportionality differences in distribution of the patterns in the ethnic groups. The associations between the distributions of the different rugae shapes with ethnicity in relation to sex were tested using chi-square analysis. P value [less than or equal to] 0.05 is considered as being statistically significant.
The rugae patterns were uniquely structured and patterned in all the individuals, and there was no evidence of similarity in the combination patterns amongst the tribes (Figure 1). The total number of various rugae patterns and their percentages are shown in Figures 2 and 3. The Igbo females have more rugae than the Ikwerre females while the Ikwerre males have more rugae than the Igbo males. The different shapes of rugae were obviously observed with varying degrees of predominance. In decreasing order of predominance are the wavy, curvy, and straight patterns. The circular pattern and unification of rugae were less common in both tribes. We observed some degree of ethnic variability in the proportionality of some rugae shapes which was statistically significant (P > 0.05). The wavy pattern in Igbo males and females was significantly higher in proportion than the Ikwerre males and females at P < 0.05, while the Ikwerre males and females have more curvy patterns which is significantly higher in proportion than the Igbo males at P < 0.05. The Ikwerre female showed high proportion than the Igbo female for the straight and unification (diverging) rugae shape which was statistically significant (P < 0.05) (Tables 1 and 2).
The distribution of the total number of individual rugae pattern in Igbo and Ikwerre did not show any significant association except in the unification (diverging) rugae (Table 3). There was significant association in distribution of total number of rugae pattern in Igbo and Ikwerre in relation to sex (Table 4). Chi-square analysis of individual rugae patterns based on sides and total sides did not show any significant association (Tables 5 and 6). The analysis of rugae length showed that primary rugae were more in Ikwerre while secondary rugae were more in Igbo although primary rugae dominated. The male Ikwerre had significantly higher mean value of primary rugae than the male Igbo (P = 0.011) while female Ikwerre had an insignificantly higher number of primary rugae than female Igbo (Table 7).
The uniqueness and stability of palatal rugae as an adjunct of human identification have been well known and implemented in the field of forensics and orthodontics [8, 15]. Despite the controversy about the stability of qualitative and quantitative characteristics of rugae and the extent of differences between ethnic groups and sex, the uniqueness to individuals has been recognized in forensic science as providing potential source of identification .
The present study evaluated the different shapes of rugae, level of predominance, combination pattern, total number of rugae, and length of rugae. The various rugae shapes were duly represented with varying degrees of predominance. The most predominant rugae pattern was the wavy followed by curvy and straight, while circular and unification of rugae were obviously less common in both populations. There was no similarity in the combination patterns which confirms its individualistic nature. The high incidence of predominance in wavy and curvy patterns has been reported by Nayak et al. , Kotrashetti et al. , Kumar et al. , Surekha et al. , Shanmugam et al. , Mohammed et al. , Bajracharya et al., , and Kapali et al. , and this effect could be regarded as dominant pattern in most populations. The study, however, found considerably higher number of straight patterns in Ikwerre which is in accordance with Shanmugam et al.  and Paliwal et al.  but in contrast to the finding by Kallianpur et al.,  who reported the straight type to be the second predominant pattern in Nepalese population, and Rath and Reginald  in their study of palatal rugae. Generally, the Igbo populations are predominantly wavy in pattern while the Ikwerre populations are predominantly curvy and straight in pattern. The rugae pattern in males and females of these populations followed a specific trend. Putting the predominant patterns into consideration, the Igbo males and females had more numbers of wavy patterns which is significantly higher in proportion when compared with Ikwerre males and females. This, however, agrees with Kiran Shetty et al.,  who said that the comparison for two populations revealed that there was a significant difference between Malayalees and Kodavas for wavy and unification patterns. The Ikwerre males and females had more curvy patterns which is also statistically significant when compared with Igbo males and females, which agrees with Surekha et al.,  who found that the curved pattern was predominant in Manipuri population than in Kerala and was statistically significant. These findings also agree with Shetty et al.,  who revealed that Indian males had more curvy patterns than Tibetan males while Tibetan females had more numbers of wavy patterns than Indian females. The Igbo males had more circular patterns which is statistically insignificant than Ikwerre males while the Ikwerre females had more straight patterns with high significant difference in proportion than the Igbo females. These significant differences in proportionality found in wavy, curvy, and straight patterns could be attributed to population differences due to environmental factors. Although there were ethnic peculiarities with respect to significant level of proportionality in shapes, chi-square test, however, did not show significant association in the pattern of distribution of the various rugae shapes among the tribes. The distribution patterns were randomly influenced. The total number of rugae in male and female Igbo population showed no significant difference which is in accordance with Bharath et al.  in the Indian study and studies by Faisal et al.  in the Saudi population and Shetty and Premalatha  in the Mangalorean population but in contrast with Dohke and Osato  in their studies in Japanese population and Shetty et al.  in Mysorean and Tibetan populations which revealed that females had fewer number of rugae than males. The Ikwerre population showed that males had more rugae than the females, though insignificant but agrees with Dohke and Osato . The right and left distribution of rugae pattern revealed that males and females of the two populations had more rugae on the left as compared to the right and this contradicts with Kapali et al. , Paliwal et al. , and Madhankumar et al.  who did not observe much difference between the left and right sides in their various population. The higher number of rugae on left side agrees with study done by Surekha et al. , Kallianpur et al. , S. Goyal and S. Goyal , and Bajracharya et al.  who explained that it was due to phenomenon of regressive evolution dominating the right side of the palate and being more evident in females. Also, the Igbo females had more rugae on both right and left than Ikwerre females while the Ikwerre males had more rugae on both right and left than Igbo males. The Igbo males had more unification patterns of rugae (converging and diverging) than the Ikwerre males while the Ikwerre females had more unification patterns of rugae than the Igbo females, with significant difference in proportion in diverging pattern. These findings are in disagreement with Manjunath et al.,  who said that comparisons of the unification of rugae both converging and diverging did not show any specific trend. The evaluation of rugae length showed that they were basically primary rugae. The males in both populations had more primary rugae than their females and this observation corresponds with that made by Shetty et al.  who reported that the Mysorean males had more numbers of primary rugae than their female counterparts. The analysis of rugae length showed that primary rugae were more in Ikwerre while secondary rugae were more in Igbo although primary rugae dominated. This finding is in accordance with Surekha et al.  who said that primary rugae were considerably longer in Kerala population than in Manipuri population, whereas secondary rugae were longer in Manipuri population. The palatal rugae shape and length showed clear evidence of discriminant characteristics in these two tribes. When genetically similar populations were considered for differentiation, continuous variables such as rugae measurement may have its limitations; therefore discrete variables such as rugae shapes could provide better result (Nayak et al. , Shanmugam et al. , and Rath and Reginald ).
The individualistic nature of palatal rugae patterns and its ethnic variability were evident in this study. The patterns of Igbo were predominantly wavy while those of Ikwerre were curvy and straight. This shows that every population including Igbo and Ikwerre has unique predominant pattern with individual differences. The rugae pattern could therefore be a strong forensic tool in analyzing races, provided antemortem records are available. Further studies from other ethnic groups in Nigeria are therefore required to validate these findings.
Conflict of Interests
The authors declare that there is no conflict of interests regarding the publication of this paper.
The authors are sincerely grateful to Dr. C. N. Orish of the Department of Human Anatomy, College of Health Science, University of Port Harcourt, Nigeria, for her generosity, encouragement, and support. The authors express their profound gratitude to the University of Port Harcourt students for their wonderful cooperation throughout the study.
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P. C. Ibeachu, (1) B. C. Didia, (1) and A. O. Arigbede (2)
(1) Department of Human Anatomy, College of Health Sciences, University of Port Harcourt, PMB 5323, Choba, Rivers, Nigeria
(2) Department of Restorative Dentistry, College of Health Sciences, University of Port Harcourt, Choba, Rivers State, Nigeria
Correspondence should be addressed to P. C. Ibeachu; firstname.lastname@example.org
Received 6 May 2014; Revised 9 July 2014; Accepted 28 July 2014; Published 8 September 2014
Academic Editor: Levent Sarikcioglu
TABLE 1: Z-test of proportionality difference in rugae pattern distribution between Ikwerre and Igbo males. Pattern Tribe Obs. Sampled Obs. population population proportion (n) (N) Wavy Ikwerre 119 335 0.356 Igbo 161 312 0.511 Curvy Ikwerre 151 335 0.451 Igbo 87 312 0.279 Circular Ikwerre 12 335 0.036 Igbo 19 312 0.061 Straight Ikwerre 33 335 0.099 Igbo 19 312 0.061 Converging Ikwerre 7 335 0.021 Igbo 10 312 0.032 Diverging Ikwerre 13 335 0.039 Igbo 16 312 0.051 Pattern Tribe z-value [absolute value P value (calculated) of (z)] critical (obs.) Wavy Ikwerre -3.98 1.96 <0.0001 Igbo Curvy Ikwerre 4.53 1.96 <0.0001 Igbo Circular Ikwerre -1.49 1.96 0.136 Igbo Straight Ikwerre 1.76 1.96 0.078 Igbo Converging Ikwerre -0.89 1.96 0.373 Igbo Diverging Ikwerre -0.77 1.96 0.441 Igbo Pattern Tribe Inference Wavy Ikwerre Significant difference in proportions * Igbo Curvy Ikwerre Significant difference in proportions * Igbo Circular Ikwerre No significant difference in proportions Igbo Straight Ikwerre No significant difference in proportions Igbo Converging Ikwerre No significant difference in proportions Igbo Diverging Ikwerre No significant difference in proportions Igbo The asterisks were used to demonstrate values with significant difference. TABLE 2: Z-test of proportionality difference in rugae pattern distribution between Ikwerre and Igbo females. Pattern Tribe Obs. Sampled Obs. population population proportion (n) (N) Wavy Ikwerre 117 289 0.405 Igbo 188 314 0.599 Curvy Ikwerre 99 289 0.343 Igbo 82 314 0.261 Circular Ikwerre 14 289 0.048 Igbo 21 314 0.067 Straight Ikwerre 34 289 0.118 Igbo 15 314 0.048 Converging Ikwerre 7 289 0.024 Igbo 5 314 0.016 Diverging Ikwerre 18 289 0.062 Igbo 3 314 0.01 Pattern Tribe z-value [absolute value P value (calculated) of (z)] critical (obs.) Wavy Ikwerre -4.7572 1.96 <0.0001 Igbo Curvy Ikwerre 2.1791 1.96 0.02926 Igbo Circular Ikwerre -0.9672 1.96 0.33204 Igbo Straight Ikwerre 3.1373 1.96 0.00168 Igbo Converging Ikwerre 0.7289 1.96 0.4654 Igbo Diverging Ikwerre 3.5282 1.96 0.00042 Igbo Pattern Tribe Inference Wavy Ikwerre Significant difference in proportions * Igbo Curvy Ikwerre Significant difference in proportions * Igbo Circular Ikwerre No significant difference in proportions Igbo Straight Ikwerre Significant difference in proportions * Igbo Converging Ikwerre No significant difference in proportions Igbo Diverging Ikwerre Significant difference in proportions * Igbo The asterisks were used to demonstrate values with significant difference. TABLE 3: Association of tribe and the distribution of individual rugae shape with sex. Tribe DF Chi square Critical Igbo Ikwerre ([chi square]2) value Wavy Male 161 119 1 1.039 3.84 Female 188 117 Curvy Male 19 12 1 0.011 3.84 Female 21 14 Circular Male 87 151 1 3.270 3.84 Female 82 99 Straight Male 19 33 1 0.397 3.84 Female 15 34 Converging Male 10 7 1 0.829 3.84 Female 5 7 Diverging Male 16 13 1 8.642 3.84 Female 3 18 Chi ([rho]) Inference calculated P value Wavy Male 0.31 No significant association Female Curvy Male 0.91 No significant association Female Circular Male 0.07 No significant association Female Straight Male 0.53 No significant association Female Converging Male 0.36 No significant association Female Diverging Male 0.003 Significant association * Female The asterisks were used to demonstrate values with significant difference. TABLE 4: Association between the tribe and sex with rugae pattern distribution. Ikwerre Igbo DF Male Female Male Female Rugae patterns Wavy 119 117 161 188 15 Curvy 151 99 87 82 Circular 12 14 19 21 Straight 33 34 19 15 Converging 7 7 10 5 Diverging 13 18 16 3 Chi-square Critical Chi (p) ([chi square]) value calculated P value Rugae patterns Wavy 36.74 24.996 <0.001 Curvy Circular Straight Converging Diverging Inference Rugae patterns Wavy Significant association * Curvy Circular Straight Converging Diverging The asterisks were used to demonstrate values with significant difference. TABLE 5: Association between the individual pattern (based on sides) and the tribe with respect to sex. Sides Ikwerre Igbo DF Male Female Male Female Left 61 57 79 103 Wavy 3 Right 58 60 82 85 Left 78 52 49 44 Curvy 3 Right 73 47 38 38 Circular Left 4 6 7 7 3 Right 8 8 12 14 Straight Left 17 20 13 8 3 Right 16 14 6 7 Converging Left 5 3 5 1 3 Right 2 4 5 4 Diverging Left 6 14 5 1 3 Right 7 4 11 2 Sides Chi-square Critical Chi (p) ([chi square]) calculated value P value Left Wavy 1.55 7.81 0.67 Right Left Curvy 0.51 7.81 0.92 Right Circular Left 0.39 7.81 0.94 Right Straight Left 1.54 7.81 0.67 Right Converging Left 3.20 7.81 0.67 Right Diverging Left 0.39 7.81 0.94 Right Sides Inference Left No significant association Wavy Right Left No significant association Curvy Right Circular Left No significant association Right Straight Left No significant association Right Converging Left No significant association Right Diverging Left No significant association Right TABLE 6: Association between the tribes with the total pattern distribution (based on sides). Ikwerre Igbo DF Chi-square ([chi square]) Male Female Male Female Total patterns Left 171 152 158 164 3 0.32 Right 164 137 154 150 Critical Chi (p) Inference value calculated P value Total patterns Left 7.81 0.96 No significant association Right TABLE 7: Z-test for difference in mean length of the primary rugae of the two ethnic groups. Variable Sample Min Max Mean SD z size (N) Male Igbo >5MM 273 5.01 18.48 10.18 2.99 Male Ikwerre >5 MM 312 5.01 19.12 9.54 3.11 Female Igbo >5 MM 264 5.01 18.5 10.03 3.18 Female Ikwerre >5 MM 285 5.01 17.21 9.66 2.96 Variable (calculated [absolute value value) of (z)] (critical value) Male Igbo >5MM 2.535 1.96 Male Ikwerre >5 MM Female Igbo >5 MM 1.406 1.96 Female Ikwerre >5 MM Variable P value Inference (calculated) Male Igbo >5MM 0.011 Significant * Male Ikwerre >5 MM Female Igbo >5 MM 0.16 Not significant Female Ikwerre >5 MM The asterisks were used to demonstrate values with significant difference. Figure 2: (a) Percentage distribution for Ikwerre males, (b) percentage distribution for Ikwerre females. Ikwerre male (a) Wavy 119 35% Curvy 151 45% Circular 12 4% Straight 33 10% Converging 7 2% Diverging 13 4% Ikwerre female (a) Wavy 117 41% Curvy 99 34% Circular 14 5% Straight 34 12% Converging 7 2% Diverging 18 6% Note: Table made from pie chart. Figure 3: (a) Percentage distribution for Igbo males, (b) percentage distribution for Igbo females. Igbo male (a) Wavy 188 60% Curvy 82 26% Circular 21 7% Straight 15 5% Converging 5 1% Diverging 3 1% Igbo female (b) Wavy 161 52% Curvy 87 28% Circular 19 6% Straight 19 6% Converging 10 3% Diverging 16 5% Note: Table made from pie chart.
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|Title Annotation:||Clinical Study|
|Author:||Ibeachu, P.C.; Didia, B.C.; Arigbede, A.O.|
|Publication:||Anatomy Research International|
|Date:||Jan 1, 2014|
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