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Forensic Research & Criminology International Journal

Research Article Volume 6 Issue 4

Dermatoglyphic patterns of female convicted criminals in Anambra state

Ozor Nwafia Chinyere Pricilla,1 Emelobe Chidiebele Samuel,2 Igbigbi Patrick Sunday2

1Department of Anatomy, Chukwuemeka Odumegwu Ojukwu University, Nigeria
2Department of Anatomy, Delta State University, Nigeria
3Department of Theatre Arts, Nnamdi Azikiwe University, Nigeria

Correspondence: Ozor Nwafia CP, Department of Anatomy, Faculty of Basic Medical Sciences, Chukwuemeka Odumegwu Ojukwu University, Uli, Nigeria

Received: January 01, 1971 | Published: August 17, 2018

Citation: Pricilla ONC, Samuel EC, SundayIP, et al. Dermatoglyphic patterns of female convicted criminals in Anambra state. Forensic Res Criminol Int J. 2018;6(4):294–296. DOI: 10.15406/frcij.2018.06.00219

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Abstrat

Dermatoglyphic is the study of epidermal ridges present on the hairless surfaces of the skin. This study was aimed to determine the dermatoglyphic patterns associated with criminal traits among female subjects in Anambra state. 100 female subjects constituting 50 female convicted criminals in Onitsha prison and 50 controls which comprises of female students and workers of Chukwuemeka Oduemegwu Ojukwu University, Uli campus. Details of crimes committed were obtained through an interviewed administered questionnaire on their consent to participate in the study. Hp Scanjet was used to scan their palm prints and saved as Jpeg image on a laptop. Dematoglyphic variables of fingerprint pattern of whorls, loops, arches, atd angles, total finger ridge counts (TFRC) and a–b ridge counts were obtained using AUTOCAD 2015 installed in a laptop. Qualitative dermatoglyphic variables of whorls, loops and arches were found to differentiate criminals from the controls. Worthy of note was specified allocation of arch patterns on criminals’ right thumb, right little finger and left thumb which were significantly different from the controls (P<0.05). Total finger ridge counts of the criminals also showed significant differences compared with the controls. a-b ridge counts and atd angles showed no significant difference between the criminals and the controls (p>0.05). Fingerprint patterns of whorls, loops, arches can be used to differentiate criminals and non- criminals in our studied population, more precisely allocation of arch pattern on the right thumb, right little finger and left thumb among female subjects can be a sign of predisposition to criminality as shown in our study.

Keywords: dermatoglyphics, fingerprints patterns, criminal traits

Introduction

The term dermatoglyphics was coined from two Greek words, Derms and Glyphics meaning skin and creases respectively.1 Fingerprints have been a critical tool for personal identification, most especially in detecting personal profile of a suspect in a crime scene, lifting of prints in a crime scene and comparing with the prints of a suspected persons have made dermatoglyphic studies crucial in forensic science.2 The dermatoglyphic patterns are developed during 12th to 13th week of the intrauterine life and from this stage remain unchanged throughout the life.3 This accounts for its unique role in personal identification, specificity in convicting a criminal or a suspect in a crime scene and early detection of defects due to chromosomal abnormalities.4,5 The tendency to commit crime and dermatoglyphics have been reported to be genetically influenced, therefore it will be important to investigate the relationship between crime and dermatoglyphics. Prevalence of radial loops fingerprint patterns was reported by Ascraellli among prostitutes.1 White6 reported significant decrease in mean finger ridge count (TFRC) when compared to non-criminal population in Anglosaxon and Spanish population.7 The dermatoglyphic patterns of Ersher who killed 19 people (17 women), serving a sentence of life imprisonment was examined by Yarovenko8 and study showed whorl patterns in his both right and left digits.

Despite the studies enumerated above, no documented study as far as we know have been reported for female convicted criminals in Anambra state of Nigeria. This study tends to fill this gap in knowledge.

Materials and methods

100 female Nigerian subjects residing in Anambra state were examined using dermatoglyphic tools and interview–administered questionnaires to confirm their citizenship, as well as details of crimes committed as regards to our study group. This involved 50 volunteered female convicted criminals in Onitsha prisons, Anambra state, Nigeria and 50 volunteered female students and staffs of Chukwuemeka Odumegwu Ojukwu University, Uli campus, Anambra State who served as control matched for age and gender respectively. Both the convicts and control subjects gave informed consent to participate in the study. The subjects’ palm prints were obtained by placing their palms on a Hp Scanjet with the thumb 300–400 along with the other digits 10–150 abducted. This was necessary to produce clear palm prints. A preliminary study using 10 subjects in each group showed equal variance hence the use of t-test for qualitative dermatoglyphic variables. The palm prints obtained, were recorded in a jpeg format in a laptop, then AutoCAD software version 2015 previously installed in the laptop was used to analyse the dermatoglyphic parameters of fingerprints patterns, atd angles and a–b ridge counts according to improvised method of dermatoglyphic analysis by Oghenemavwe et al.9 Counting the pattern ridges of arches, whorls, loops according to the standard technique of Cummins & Midlo10 The dermatoglyphic parameters analysed were subjected to statistical analysis using statistical package for Social Science Version 15 (SPSS) Chicago, Illinosis. Qualitative dermatoglyphic variables of fingerprint patterns (whorls, arches, loops) were evaluated with chi-square and quantitative dermatoglyphic variables (TFRC, atd angles, a–b ridge counts) were evaluated by means and frequencies with p–value less than 0.05 (p<0.05) was considered as significant.

Results

Higher frequencies of each patterns was observed on the right digits of the criminal group compared to the control group with a total percentages of 13.2% and 4.*% respectively (Table 1). Loops and whorls were significantly higher on the right digits of the control group than the criminal group with percentages of 31.0%, 25.6% and 14.2%, 11.2% respectively (Table 1). Left digits of the criminals were also observed with significant increase in arch patterns with percentage of 8.4% compared to the control group with percentage of 3.0%. Loop and whorl patterns were relatively higher in control group than the criminal group with percentages of 32.2%, 4.8% and 29.0%, 12.6% respectively (Table 2). The fingerprint pattern frequencies of the right and left digits of the control group were not significantly different (p>0.05), but in criminal group the fingerprint patterns of whorls, arches and loops on their left digits were statistically significantly different from that of their right digits (p<0.05) (Table 3). There was also no significant difference between the total finger ridge counts (TFRC), a–b ridge counts and atd angles of the criminals and control groups respectively (Table 4) (Table 5) (Table 6).

Fingerprint patterns

Control(frequencies)

Criminals (frequencies)

Total percentages

Whorls

71(14.2%)

56(11.2%)

25.40%

Loops

155(31.0)%

128(25.6%)

56.60%

Arches

24(4.8%)

66(13.2%)

18.00%

Table 1 Right palms fingerprint patterns distribution in control and criminal groups
P value, 0.001

Fingerprint patterns

Control(frequencies)

Criminals(frequencies)

Total percentages

Whorls

74(14.8%)

63(12.6%)

27.40%

Loops

161(32.2%)

145(29.0%)

61.20%

Arches

15(3.0%)

42(8.4%)

11.40%

Table 2 Left palms fingerprint patterns distribution in control and criminal groups
P value, 0.001

Control group

Criminal group

Fingerprint patterns

Left palm

Right palm

Percentages

Left palm

Right palm

Percentages

Whorls

74

71

29.00%

p value=0.324

63

56

23.80%

p value=0.033

Loops

161

155

63.20%

145

128

54.60%

Arches

15

24

78.00%

42

66

21.60%

Table 3 Left to Right palm fingerprint patterns cross-tabulation between the control and criminal groups

Control

Criminals

Fingers(status)

Mean±SD

Mean±SD

P values

RF1

10.88±5.97

6.74±6.90

0.02

RF2

10.84±5.14

9.16±6.40

0.151

RF3

12.64±5.71

9.94±6.61

0.031

RF4

15.14±5.01

12.74±6.57

0.043

RF5

12.68±4.10

10.68±5.70

0.047

LF1

13.80±7.21

8.82±7.52

0.001

LF2

12.16±5.35

9.40±6.35

0.021

LF3

12.04±4.53

10.72±5.08

0.173

LF4

14.60±4.53

13.58±5.03

0.29

LF5

11.78±3.92

10.64±5.29

0.224

Total

127.16±37.36

102.24±50.50

0.006

Table 4 Independent Sample t-test of a-b ridge counts between control group and criminals for both right and left palms

Control

Criminals

Status

Mean±SD

Mean±SD

P value

a-b Left Palm

39.36±5.36

39.78±3.90

0.655

a-b Right Palm

37.76±5.17

38.12±4.93

0.722

Table 5 Independent Sample t-test of a-b ridge counts between control group and criminals for both right and left palms

Control

Criminals

Status

Mean±SD

Mean±SD

P-Value

Left Palm

43.60±4.79

43.78±4.63

0.849

Right Palm

42.80±5.06

42.56±5.16

0.849

Table 6 Independent Sample t-test of atd angle between control and criminal groups for both right and left palms

Discussion

Our study have shown significant higher frequencies of arch patterns on both right and left digits of the female convicted criminals compared with controls. This was in concordance with Biswas11 who worked on Indian Juvenile criminals.

Prevalence of arch patterns was observed on the right first digits (right thumb), right fifth digits (little finger) and left first digit which was different from the control group.

Campbell12 in a German population reported previously studied reported that individuals with greater frequencies of aches were characterized as repressive, secretive in self defense, naturally suspicious and resentful of others achievement. In our study individuals convicted for child trafficking, murder and robbery were found with arch patterns on their right first digit (right thumb), right fifth digits (right little finger), and left first digit (left thumb). Studies have previously shown that qualitative dermatoglyphic variables differ between races and ethnic groups and also between the right and left palms and digits.13,14

There was significant higher occurrence of arch patterns on both left and right digits of the criminals compared with the control group, however, loops and whorl patterns showed no significant difference between the criminal and control groups.

Whorl and loop patterns were relatively higher on the left and right digit of the control compared with the criminals, and this was in line with the study conducted by Agarwal15.

Furthermore, getting define individual with greater frequencies of arches as crude, insensitive, hardhearted and definitely stubborn. In the same vein, Katakhar classified these individuals as high strong, nervous and too easily responsive to emotional stimulation.12 In the current study, right first digit (RFI) of the control was observed with a higher mean value of 10.88±5.97 compared to the criminals with mean value of 6.74±6.90 and the difference was statistically significant (P<0.05). The total finger ridge counts (TFRC) of the right third digit (RF3), right forth digits (RF4), right fifth digits (RF5), left first digit (LF1), and left second digits (LF2) of the criminals were found to be statistically significantly different from the controls (P<0.05). Our study showed no significant difference between criminals and controls in quantitative variables except TFRC as indeed was the case with a study of male convicted criminals reported previously in a Nigerian population.16 This study also demonstrated dermatoglyphic difference in qualitative variables as this study has shown.

In conclusion, this study has clearly shown differences in dermatoglyphic traits between female convicted criminals and controls in qualitative dermatoglyphic variables of arches, whorls and loops. Similarly TFRC can also differentiate convicted female criminals from controls but this was not the case with convicted male criminals in a Nigeria study previously documented.16 For female convicted criminals in our studied population, both qualitative variables and only one quantitative variable of TFRC can differentiate them from female controls and hence can serve as possible markers from the identification of potential female criminals in our studied population.

Authors contribution

Ozor-Nwafia C.P participated fully in the conception and analysis of the data. Emelobe C.S was involved in analysis and interpretation of data. Prof. P.S Igbigbi participated in interpretation of data, while Ozor C.K was in involved in social communication with the subjects, also in describing various traits among the subjects.

Acknowledgements

None.

Conflict of interest

Author declares that there is no conflict of interest.

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