Advances in Animal and Veterinary Sciences

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AAVS_Nexus 674

 

Research Article

 

Forensic Identification of some Wild Animal Hair using Light and Scanning Electron Microscopy

 

Mayada Ragab Farag1*, Mervat Hassan Ghoniem1, Ali Heider Abou-Hadeed1, Kuldeep Dhama2

1Department of Forensic Medicine and Toxicology, Faculty of Veterinary Medicine, Zagazig University, Egypt; 2Division of Pathology, Indian Veterinary Research Institute, Izatnagar, Bareilly, 243122, Uttar Pradesh, India.

 

Abstract | The present study was conducted to investigate some morphological and numerical features of hair samples of some wild animal species using light and scanning electron microscopy to make a key for their identification. Samples of hair were obtained from different body regions (dorsal neck, dorsum and flank) of American black bear (Urus americanus), Blue Nile monkey (Ceropithecus mitis), Barbary sheep (Amotracus lervia), Bactrian camel (Camelus bactrianus) and Llama (Lama glama). The measurements and indices used are the diameter of hair shaft at three positions (proximal, middle and distal parts of hair shaft), medulla and cuticular indices, as well as the scale count and the ratio of scale width to scale height (X/Y feret). The diameter of the proximal part of hair shaft showed very small variations in dorsal neck, dorsum or flank between the individuals of the same species and the same observed for the diameter of middle and distal parts, where the differences in the hair thickness among species were clearly observed by changing the part of hair and body region. The medullary and cuticular indices of individuals from the same species showed very small variations by changing the body region, but on the species level they showed significant differences. The animals of the same species are more likely to have similar scale patterns and count along the shaft of hair and even in the different parts of the body. On the other hand scale patterns and count showed great variations between different species along the hair shaft and also according to the body region. The species differences in the numerical features of cuticular scales were more frequently observed at the tip side than at the root. Barbary sheep has the largest X/Y feret value among species. In conclusion, the differences in the morphological and numerical features of hair used in this study could be of great value for species identification.

 

Keywords | Hair, Identification, SEM analysis, Wild animals

 

Editor | Muhammad Munir (PhD), Avian Viral Diseases Programme, The Pirbright Institute, Woking, Surrey, GU24 0NF, UK.

Received | July 13, 2015; Revised | August 18, 2015; Accepted | August 19, 2015; Published | September 22, 2015

*Correspondence | Mayada Ragab Farag, Zagazig University, Egypt; Email: dr.mayadarf@gmail.com

Citation | Farag MF, Ghoniem MH, Abou-Hadeed AH, Dhama K (2015). Forensic identification of some wild animal hair using light and scanning electron microscopy. Adv. Anim. Vet. Sci. 3(10): 559-568.

DOI | http://dx.doi.org/10.14737/journal.aavs/2015/3.10.559.568

ISSN (Online) | 2307-8316; ISSN (Print) | 2309-3331

Copyright © 2015 Farag et al. This is an open access article distributed under the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original work is properly cited.

 

INTRODUCTION

 

The mammalian hair fibers represent an interesting biological material which can be easily sampled, collected and transported as well as resist putrefaction and remain for very long periods of time so could provide long-term information (Nowak, 1998; Tridico et al. 2014). Moreover, in forensic casework the present hair samples are sometimes the only available evidence found at a crime scene (Brauner et al., 2001; Farah et al., 2014). Furthermore, the hair morphology is useful for the study of evolution and domestication of various mammals in zoology, morphology, phylogenetic, taxonomic, textile testing, archeological studies and forensic sciences (Meyer et al., 2002; Farag et al., 2015).

 

The macro and microscopic structure features are widely used for identification of hair and investigation of their role in adaptation of animals to life conditions. The former include the degree of hair cover the body with different coloration, shape, length and width, as well as position, arrangement in groups and direction of villi. The latter comprise the specific features of the hair shaft architectonics (ratio of development of three layers, cuticle, cortex and medulla; heterogeneity and pigmentation of cortical layer; cuticular pattern; shape of cuticular scales; and the shape, size, pigmentation and position of medullar cells and cavities between or inside them) (Chernova, 2002; Nadia, 2012; Monica et al., 2015).

 

Most studies on mammalian hair was done using plastic impressions of cuticular scales and direct observation of whole mounts using light microscopy (Brunner and Coman, 1974; Valente, 1983; Wallis ,1993; Oli, 1993; Taru and Backwell , 2013), and scanning electron microscopes (SEM) which provide new technology that allowed for greater magnification and resolution (Andy and Tillman, 2006; Aris and George, 2008).

 

This study aims at using light and scanning electron microscopy to obtain some features of hair samples from different body regions (dorsal neck, dorsum and flank) of some wild animals in trying to differentiate between them.

 

MATERIALS AND METHODS

 

The Tested Species

Samples of hair were obtained from five animal species from Giza Zoo, Giza, Egypt. All species used in this study were listed in Table 1.

 

Examination of Hair Samples using Light and Scanning Electron Microscopy (L.M. and SEM)

Hair samples were collected from each of five adult healthy males of selected species (Table 1).Ten hairs were collected from each of three different body regions, that is dorsal neck, dorsum and flank. All samples were morphologically and numerically examined in this study.

 

Whole Mounts

The samples were cleaned thoroughly in an ether-alcohol mixture (1:1) and were dried between two filter papers. The samples were placed on a clean microscope slides. Then the samples were mounted in Canada balsam with (refractive index: 1.53), and were examined under light microscope (VM 250) with magnification of 400X according to Oli (1993) then photographed using (SONY, DSC-S950) camera.

 

Scanning Electron Microscope

In order to examine the pattern of the cuticular scales and to calculate the scale counts per (100µm) unit length and the ratio of scale width to scale height (X/Y feret): untreated hairs from different types of animals mentioned in Table 1 were cleaned according to the procedure of Hess et al. (1985) which is as follows, hair samples were placed in small petri dishes with distilled water containing a drop of detergent (Baby Johnson) and sonicated for 5 min. Hairs were then washed in distilled water and sonicated for 5 minutes in absolute acetone. Hairs left to be air dried then mounted on SEM stubs. All the specimens were placed in a vacuum champer and gold coated (Edwards sputter coater S150 B) before being examined with a JEOL JSM- T100 Scanning Electron Microscope. The micrographs were taken at 20 KV and 1,000 X.

 

Table 1: The names and classification of animal’s source of hair samples

Common name

Order

Family

Scientific name

American black bear

Carnivora

Ursidae

Urusamericanus

Blue nile monkey

Primates

Ceropithecidae

Ceropithecusmitis

Barbary sheep

Artiodactyla

Bovidae

Amotracuslervia

Bacterian camel

Artiodactyla

Camelidae

Camelusbactrianus

Llama

Artiodactyla

Camelidae

Lama glama

 

Measurements and Indices used in this Study

The measurements and indices used were calculated according to Sato (2002) and Sato et al. (2006) as given below:

  • The diameter of hair shaft at three positions (proximal, middle and distal parts of hair shaft) (L.M).
  • The medulla index is a ratio of medullary diameter to hair diameter X 100 (L.M).
  • The cuticular index is a ratio of cuticular diameter to hair diameter X100.
  • The scale count denotes the number of free edges of hair scale per unit length (100 µm field of view) (SEM).
  • X/Y feret measured by SEM (Areida et al., 2006)
  • These features were measured at three positions of the hair shaft i.e. the proximal, middle and distal parts. These parts were objectively controlled as follows, the proximal part was at the proximal one third of the hair shaft (toward the tip of hair), the middle part was at the central part along the hair shaft, the distal part was at the maximum width point near the root of the hair, and the measurements obtained were adjusted to the actual size of the sample using ultra structure size calculator (SPI supplies, Divisions of structure probe, Inc. USA, units of measurements 1mm= 1000µm, 1µm= 10,000 Ao, 1 nm= 10 Ao).

     

    Statistical Analysis

    Data were statistically analysed using general linear models procedure adapted by SPSS for user’s guide with one-way ANOVA. The differences among means were determined using the student Newman keuls test. The Mean values and standard error (SE) were reported. Statements of statistical significance were based on P < 0.05.

     

    Table 2: The measurements of the hair shaft (basal, middle and proximal parts) from dorsal neck, dorsum and flank regions of American black bear (Urus americanus)

    Parameters

    Basal part

    Middle part

    Proximal part

    Dorsal neck

    region

    Dorsum

    region

    Flank

    region

    Dorsal neck

    region

    Dorsum

    region

    Flank

    region

    Dorsal neck

    region

    Dorsum

    region

    Flank

    region

    Diameter (µm)

    56.6± 0.66 a

    54.66± 2.6 a

    57.6± 0.66 a

    37.8± 0.16a

    38.0± 0.57 a

    38.6± 0.4 a

    31.1±

    0.7a

    30.3±

    0.3a

    31.3± 0.7a

    Medullary index

    36.7±

    1.5b

    34.5± 0.28b

    41.0± 0.57a

    44.7±

    0.3 a

    41.0± 0.57a

    41.3± 0.6 a

    37.9±

    0.3a

    36.3± 0.88a

    36.7± 1.8a

    Cuticular index

    6.8±

    0.16 b

    7.0±

    0.00 b

    7.5±

    0.00 a

    6.5±

    0.11 a

    6.46± 0.21 a

    6.5± 0.24 a

    7.3±

    0.20 a

    7.33± 0.18a

    7.30± 0.2a

    Cortical index

    31.0±

    0.0 a

    31.0± 0.05 a

    31.3± 0.88a

    30.0±

    0.0 a

    30.0± 1.00 a

    30.6± 1.2a

    30.8± 0.05a

    30.7± 0.08a

    30.3± 0.4a

    Scale counts per (100µm)

    25.0±

    0.0 a

    24.3± 1.33 a

    24.3± 0.66 a

    20.0± 0.57 a

    20.3± 1.45 a

    20.0± 2.0 a

    12.0± 0.57a

    11.0± 0.57a

    12.3± 0.3a

    X/Y feret

    3.4±

    0.08 a

    3.4±

    0.03 a

    3.4±

    0.06 a

    2.4±

    0.05 a

    2.5±

    0.00 a

    2.3± 0.24 a

    1.1±

    0.03a

    1.10± 0.57 a

    1.2± 0.08 a

     

    Means within the same row in each item within each group carrying different superscripts are significantly different at (p< 0.05)

     

     

    Table 3: The measurements of the hair shaft (basal, middle and proximal parts) from dorsal neck, dorsum, and flank regions of Blue Nile monkey (Ceropithecus mitis)

    Parameters

    Basal part

    Middle part

    Proximal part

    Dorsal neck

    region

    Dorsum

    region

    Flank

    region

    Dorsal neck

    region

    Dorsum

    region

    Flank

    region

    Dorsal neck

    region

    Dorsum

    region

    Flank

    region

    Diameter (µm)

    45.83± 1.01a

    45.83± 0.44a

    45.00± 1.52a

    42.76± 0.14 a

    41.83± 1.16a

    41.96± 0.54 a

    31.00± 0.57a

    31.00± 1.15a

    29.00± 0.57a

    Medullary index

    49.86± 1.39a

    47.66± 1.85a

    49.00 ±1.52a

    48.16± 0.60 a

    48.33± 1.20a

    49.83± 0.16 a

    50.00± 0.57a

    49.66± 0.88a

    50.33± 0.33a

    Cuticular index

    3.10± 0.10a

    3.10± 0.05a

    3.20± 0.11a

    3.1±

    0.57 a

    3.5±

    0.11a

    3.4±

    0.17 a

    4.00± 0.057a

    3.96±

    0.08a

    4.00± 0.057a

    Cortical index

    32.00± 0.57a

    32.00± 1.55a

    32.66 ±1.76a

    32.00 ±1.00 a

    32.90± 0.73a

    33.00± 0.75a

    33.20± 0.05b

    32.80± 0.41b

    34.33± 0.16a

    Scale counts per (100µm)

    25.33± 0.33a

    25.00± 2.51a

    26.33 ±0.33a

    22.33± 1.20 a

    22.00± 1.00 a

    23.66± 0.88a

    18.33± 0.33 a

    19.33± 0.33b

    21.00± 0.00c

    X/Y feret

    3.50± .288 a

    3.60± 0.20 a

    4.00± 0.00 a

    3.00± 0.00 b

    3.13± 0.033 a

    3.10± 0.00a

    3.00±

    0.00 a

    3.10±

    0.00 a

    3.10± 0.05 a

     

    Means within the same raw in each item within each group carrying different superscripts are significantly different at (p< 0.05)

     

    RESULTS AND DISCUSSION

     

    Morphological examination of hair samples is the first step

    in forensic hair examination. The main medico-legal concerns with hair examination include identification of the species origin, ascertainment of the hair’s provenance from the body and, finally, comparison of the hair sample from the victim to the hair sample from the crime scene (Zafarina and Panneerchelvam, 2009). It is well-known that based on morphological features some hairs and consequently some animal species can be discriminated without any trouble, that makes the morphological examination of hairs is an important method that can be used in forensic medicine (Sato, 2002; Sato et al., 2006).

     

    Two of the features that make hair a good subject for establishing individual identity are its resistance to chemical decomposition and its ability to retain structural features over long period of time. Much of resistance and stability is attributed to the cuticle or outside covering of hair (Bernadette et al., 1996; Nowak et al., 1998).

     

    Our investigation concerning the diameter of hair revealed that the diameter of the proximal part of hair shaft showed very small or no variations when compared in the three examined body regions (dorsal neck, dorsum and flank) between the individuals of the same species. There were also non-significant differences in the diameter of middle and distal part of hair shaft in the three body regions of the same species but with comparing the diameter of hairs on the species level the differences in the hair thickness among species were clearly observed by changing the part of hair and body region. Similar results were obtained by

     

    Table 4: The measurements of the hair shaft (basal, middle and proximal parts) from dorsal neck, dorsum and flank regions of Barbary sheep (Amotracus lervia)

    Parameters

    Basal part

    Middle part

    Proximal part

    Dorsal neck

    region

    Dorsum

    region

    Flank

    region

    Dorsal neck

    region

    Dorsum

    region

    Flank

    region

    Dorsal neck region

    Dorsum

    region

    Flank

    region

    Diameter (µm)

    126.66 ±1.20 a

    126.00± 1.52 a

    127.00 ± 2.08 a

    95.00 ±0.00 a

    95.33 ±1.85a

    95.66 ± 1.86 a

    67.50 ±0.28 b

    67.00± 0.00 b

    68.33± 0.33 a

    Medullary index

    86.13± 0.88 a

    86.23± 0.62 a

    87.16± 0.44 a

    86.5± 0.10 a

    86.4± 0.057 a

    86.2± 0.43 a

    81.166± 0.16 a

    81.66± 0.33 a

    82.00± 0.57 a

    Cuticular index

    3.03± 0.03 a

    2.93± 0.03 a

    3.06± 0.14 a

    3.03± 0.033 b

    3.10± 0.00 b

    3.23± 0.033 a

    3.60± 0.57 a

    3.50± 0.10 a

    3.63± 0.145 a

    Cortical index

    8.06± 0.033 a

    8.20± 0.05 a

    8.20± 0.05 a

    7.7± 0.058 a

    7.5± 0.145 a

    7.4± 0.06 a

    7.30± 0.05 b

    7.40± 0.05 b

    7.60± 0.00 a

    Scale counts per (100µm)

    143.33± 6.66 a

    141.33± 1.20 a

    143.33 ±3.33 a

    88.33± 3.33 a

    88.34± 4.40 a

    86.66± 3.33 a

    90.00± 2.88 a

    91.66± 3.33 a

    92.33± 6.17 a

    X/Y feret

    7.00± 0.00 a

    7.00± 0.01 a

    7.00± 0.152 a

    5.00± 0.057 a

    5.00± 0.00 a

    4.90± 0.25 a

    5.33± 0.71 a

    6.03± 0.03 a

    6.03± 0.03 a

     

    Means within the same raw in each item within each group carrying different superscripts are significantly different at (p<05).

     

     

    Table 5: The measurements of the hair shaft (basal, middle and proximal parts) from dorsal neck, dorsum and flank regions of Llama (Lama glama)

    Parameters

    Basal part

    Middle part

    Proximal part

    Dorsal neck

    region

    Dorsum

    region

    Flank

    region

    Dorsal neck

    region

    Dorsum

    region

    Flank

    region

    Dorsal neck

    region

    Dorsum

    region

    Flank

    region

    Diameter (µm)

    44.66± 1.33a

    46.00± 0.57a

    47.13± 0.18a

    37.66±0.33a

    37.66± 0.16a

    38.00± 0.57 a

    34.00± 0.57 a

    34.33± 0.06 a

    34.00± 0.57 a

    Medullary index

    34.16± 0.44a

    33.33± 0.28a

    34.16± 0.44a

    33.96± 0.31a

    33.33± 0.88a

    33.36± 0.31 a

    34.90± 0.49 a

    34.00± 0.57 a

    35.10± 0.01a

    Cuticular index

    3.00± 0.00 a

    3.00± 0.05a

    3.03± 0.12a

    3.13±0.08a

    3.13± 0.06a

    3.20± 0.05a

    3.26± 0.12a

    3.23± 0.12a

    3.26± 0.06 a

    Cortical index

    42.36± 0.31a

    42.63± 0.68a

    42.00± 1.73a

    32.00±1.00a

    42.50± 0.76a

    42.10± 0.44a

    42.30± 0.25a

    42.53± 0.26a

    42.13± 0.40 a

    Scale counts per (100µm)

    13.00± 0.57a

    12.66± 1.20a

    12.66± 1.45a

    23.33± 2.02a

    23.33± 0.08a

    23.66± 1.33a

    35.00± 1.15a

    33.33± 0.88a

    33.00± 1.52 a

    X/Y feret

    1.56±0.03a

    4.80± 3.35a

    1.50± 0.10a

    2.03± 0.03a

    2.10± 0.05a

    2.00± 0.00 a

    1.26± 0.033 a

    1.23± 0.066 a

    1.30± 0.00 a

     

    Means within the same raw in each item within each group carrying different superscripts are significantly different at (p< 0.05)

     

    (Sato et al., 2006) who found that numerical features such as hair diameter can clearly be used to differentiate between hairs of dog and cat. Our results also in agreement with the results of Aris and George (2008) who studied the morphology of hairs of Capra prisca (goat) and the sheep wool and found that the diameter of hairs of goat and the diameter of wool varied greatly, they concluded that hair diameter could be useful for hair identification of mammalian species. Moreover, Jones et al. (2001) stated that diameter of hair shaft between species can vary from 10-250 µm and are influenced by the metabolic and nutritional status of the animal, which may play indirect role in the variability of hair diameter observed among different species used in our study.

     

    This study also revealed that the medullary index of individuals from the same species showed very small or no variations by changing the body region but comparing medullary index on the species level showed significant differences and was less than 1/3 in human hairs while that of animals was greater than 1/3 except for bactrian camel which have medullary index less than 1/3. These results are in agreement with Gaudette (1999) and Deedrick and Koch (2004) who stated that the medulla of hairs also valuable for species identification, animal medullary index is greater than human’s. Moreover the differences in medullary index and patterns observed between different species may be explained by Chernova (2003) who stated that the different structure of the medulla could be returned to structural and functional adaptation because the medulla is related to the thermal insulation of hair coat of different animals.

     

    Table 6: The measurements of the hair shaft (basal, middle and proximal parts) from dorsal neck, dorsum and flank regions of Bacterian camel (Camelus bactrianus)

    Parameters

    Basal part

    Middle part

    Proximal part

    Dorsal neck

    region

    Dorsum

    region

    Flank

    region

    Dorsal neck

    region

    Dorsum

    region

    Flank

    region

    Dorsal neck

    region

    Dorsum

    region

    Flank

    region

    Diameter (µm)

    47.33± 1.20a

    45.66± 0.88a

    47.66± 0.57a

    43.16± 0.44b

    42.73± 0.14b

    44.23± 0.14a

    33.00±0.57a

    31.33± 0.88a

    31.00± 1.15a

    Medullary index

    16.66± 0.44b

    17.70± 0.05a

    17.46± 0.16b

    16.63± 0.49a

    16.73± 0.27a

    16.86± 0.28a

    16.50±0.28a

    16.66± 0.44a

    16.80± 0.40a

    Cuticular index

    2.30± 0.11a

    2.30± 0.17a

    2.30± 0.05a

    2.80± 0.05a

    2.86± 0.03a

    2.56± 0.17a

    2.70± 0.25a

    2.60± 0.15a

    2.66± 0.14a

    Cortical index

    33.00± 0.57a

    33.83± 0.60a

    34.16± 0.44a

    34.83± 0.16a

    34.70± 0.30a

    34.16± 0.60a

    33.33± 0.33a

    33.50± 0.76 a

    34.00± 1.15a

    Scale counts per (100µm)

    13.00± 0.00a

    12.33 ± 0.88a

    12.00± 1.00a

    11.66± 0.33a

    11.66± 0.66a

    11.00± 1.52a

    9.00± 0.57a

    8.33± 0.66a

    7.66± 0.66a

    X/Y feret

    1.33± 0.08a

    1.33± 0.16a

    1.26± 0.13a

    1.40± 0.05a

    1.36± 0.15a

    1.40± 0.12a

    1.16±0.03a

    1.20± 0.00 a

    1.20± 0.05a

     

    Means within the same raw in each item within each group carrying different superscripts are significantly different at (p< 0.05)

     

    A: proximal part, B: middle part and C: distal part; note the thickness of hair shaft, note also the overlapped short and wide imbricated scales of equal hastate with saw margin and without long free blade (X1000). The other side shows the three morphological regions of hair (the cuticle, the medulla and the cortex) along the hair shaft of Urus americanus (D: proximal part, E: middle part and F: basal part) under light microscope (X400)


    Regarding to the results of cuticular index our study revealed that there were no or very small differences in the cuticular index among individuals of the same species by examining the different parts of hair at different body region, meanwhile,there was a great difference in cuticular index among different species and this is in agreement with that mentioned by Jones et al. (2001) who reported that cuticle thickness varies markedly between species, for example the cuticle of fine merino wool fibers is normally one cell thick whereas in human hair and pig bristle the cuticle

     

    A: proximal part, B: middle part and C: distal part; note the thickness of hair shaft, note also the overlapped moderate length and wide imbricated scales of equal hastate with saw margin and without long free blade (X1000). The other side shows the three morphological regions of hair (the cuticle, the medulla and the cortex) along the hair shaft (D: proximal part, E: middle part and F: basal part) of Ceropithecus mitis under light microscope (X400)

     

    may range from 10 cells to 30 cell layers respectively and the author related this to the unique characteristics of hair cuticle cells which give mammalian hair its surface properties, these cells are important in a variety of applications ranging from textile processing to protection of fiber component from environmental damage.

     

    The examination of hair shaft with the aid of SEM provided useful information of the hair morphology of studied species concerning scale counts and the ratio of scale

     

    A: proximal part, B: middle part and C: distal part; note the thickness of hair shaft, note also the overlapped short and wide imbricated scales of equal hastate with smooth margin and without long free blade (X1000). The other side shows the three morphological regions of hair (the cuticle, medulla and the cortex) along the hair shaft of Amotracus lervia (D: proximal part, E: middle part and F: basal part) under light microscope (X400)

     

    A: proximal part, B: middle part and C: distal part; note the thickness of hair shaft, note also the overlapped moderate length and moderate width imbricated scales of equal hastate with saw margin and without long free blade (X1000). The other side shows the three morphological regions of hair (the cuticle, the medulla and the cortex) along the hair shaft of Lama glama (D: proximal part, E: middle part and F: basal part) under light microscope (X400)

     

    Table 7: The measurements and indices of the basal part of hair shaft of different body regions (dorsal neck, dorsum and flank) of the studied animals

    Animal species

    American black bear

    Blue nile monkey

    Barbary sheep

    Lama

    Bacterian camel

    Body regions

    Dorsal neck region

    Diameter (µm)

    31.16± 0.72c

    31.00± 0.57 c

    67.50±0.28a

    34.00±0.57b

    33.00± 0.57b

    Medullary index

    37.96± 0.29c

    50.00± 0.57b

    81.16± 0.16a

    34.90± 0.49d

    16.5± 0.28e

    Cuticular index

    7.33± 0.20a

    4.00± 0.057b

    3.60± 0.057bc

    3.26± 0.12c

    2.70± 0.5d

    Cortical index

    30.80± 0.05c

    33.20± 0.05b

    7.30± 0.05d

    42.30± 0.25a

    33.33± 0.33b

    Scale counts per (100µm)

    12.00± 0.57d

    18.33 ± 0.33c

    90.00± 2.88a

    35.00± 1.15b

    9.00± 0.57d

    X/Y feret

    1.06± 0.03d

    2.86± 0.08b

    6.00± 0.05a

    1.26± 0.03c

    1.16± 0.03cd

    Dorsum region

    Diameter (µm)

    30.33± 0.33c

    31.00± 1.10c

    67.00± 0.00a

    34.33± 0.66b

    31.33± 0.88c

    Medullary index

    36.33± 0.88c

    49.66± 0.88b

    81.66± 0.33a

    34.00± 0.57d

    16.56± 0.34e

    Cuticular index

    7.33± 0.18a

    3.96± 0.08b

    3.50± 0.10c

    3.23± 0.12c

    2.60± 0.15d

    Cortical index

    30.76± 0.08c

    33.10± 0.15b

    7.40± 0.05d

    42.53± 0.26a

    33.50± 0.76b

    Scale counts per (100µm)

    11.00± 0.57d

    19.33± 0.33c

    91.66± 3.33a

    33.33± 0.88b

    8.33±0.66d

    X/Y feret

    1.10± .05c

    2.90± 0.20b

    6.03± 0.03a

    1.23± 0.06c

    1.20± 0.00c

    Flank region

    Diameter (µm)

    31.33± 0.66c

    29.00± 0.57c

    68.33 ± 0.33a

    34.00 ± 0.57b

    31.00± 1.15c

    Medullary index

    36.66± 1.85c

    50.33± 0.33 b

    82.00± 0.57a

    35.16 ± 0.16c

    16.80 ± 0.40d

    Cuticular index

    7.30± 0.15a

    4.00± 0.05b

    3.63± 0.14bc

    3.26± 0.06c

    2.66 ± 0.14 d

    Cortical index

    30.30± 0.35c

    34.26± 0.14b

    7.60± 0.00d

    42.13 ± 0.40a

    34.00 ± 1.15b

    Scale counts per (100µm)

    12.33± 0.33cd

    21.33 ± 0.33c

    92.33 ± 6.17a

    33.00± 1.52b

    7.66 ± 066d

    X/Y feret

    1.16± 0.08c

    2.93± 0.03b

    6.03± 0.03a

    1.30± 0.00c

    1.20± 0.05c

     

    Means within the same raw in each item within each group carrying different superscripts are significantly different at (p< 0.05)

     

     

    Table 8: The measurements and indices of the middle part of hair shaft of different body regions (dorsal neck, dorsum and flank) of the studied animals

    Animal species

    American black bear

    Blue nile monkey

    Barbary sheep

    Lama

    Bacterian camel

    Body regions

    Dorsal neck region

    Diameter (µm)

    37.83± 0.16c

    42.76± 0.14b

    95.00± 0.00a

    37.66 ± 0.33c

    43.16± 0.44b

    Medullary index

    40.66± 0.33c

    48.16± 0.60b

    86.50± 0.01a

    33.96± 0.31d

    16.63± 0.49e

    Cuticular index

    6.50± 0.11a

    3.10± 0.05b

    3.03 ± 0.03 bc

    3.13± 0.08b

    2.80± 0.05c

    Cortical index

    30.00± 0.00d

    32.00± 1.00c

    7.70± 0.05e

    42.66± 0.33a

    34.83± 0.16b

    Scale counts per (100µm)

    20.00 ± 0.57b

    22.33 ± 1.20b

    88.33 ± 3.30a

    23.33± 2.00b

    11.66± 0.33c

    X/Y feret

    2.40± 0.05c

    3.00± 0.00b

    5.00± 0.05a

    2.03± 0.03d

    1.40± 0.05e

    Dorsum region

    Diameter (µm)

    38.00± 0.57c

    41.83± 1.16b

    95.33± 1.85a

    37.66± 0.16c

    42.66± 0.20b

    Medullary index

    41.00± 0.57c

    48.33± 1.20b

    86.40± 0.05a

    33.33± 0.88d

    16.73± 0.27e

    Cuticular index

    6.46± 0.21a

    3.50± 0.11b

    3.10± 0.00c

    3.13 ± 0.06c

    2.86± 0.03c

    Cortical index

    30.00± 1.00c

    32.90± 0.73b

    7.56± 0.14d

    42.50± 0.76a

    34.70± 0.30b

    Scale counts per (100µm)

    20.00± 2.00b

    22.00± 1.00b

    88.33 ± 4.40a

    23.33± 0.88b

    11.66± 0.66c

    X/Y feret

    2.50± 0.00c

    3.13± 0.03b

    5.00± 0.00a

    2.10± 0.05 d

    1.36± 0.12e

    Flank region

    Diameter (µm)

    38.50± 0.50c

    41.96± 0.54b

    95.66± 1.85a

    38.00± 0.57c

    44.23± 0.14b

    Medullary index

    41.33± 0.66c

    49.83± 0.16b

    86.20±0.43a

    33.36± 0.31d

    16.86± 0.28e

    Cuticular index

    6.56± 0.24a

    3.46± 0.17b

    3.23± 0.03b

    3.20± 0.05b

    2.56± 0.17c

    Cortical index

    30.66± 1.20c

    33.00 ± 0.57b

    7.43±0.06d

    42.16± 0.44a

    34.16± 0.60b

    Scale counts per (100µm)

    20.00± 2.00b

    23.66 ± 0.88b

    86.66± 3.33a

    23.66± 1.33b

    11.00± 1.52c

    X/Y feret

    2.00± 0.52c

    3.10± 0.00b

    5.03 ± 0.12a

    2.00± 0.00c

    1.40± 0.15c

     

    Means within the same raw in each item within each group carrying different superscripts are significantly different at (p< 0.05)

     

    A: proximal part, B: middle part and C: distal part; note the thickness of hair shaft, note also the overlapped moderate length and moderate width imbricated scales of equal hastate with saw margin and without long free blade (X1000). The other side shows the three morphological regions of hair (the cuticle, the medulla and the cortex) along the hair shaft of Camelus bactrianus (D: proximal part, E: middle part and F: basal part) under light microscope (X400)

     

    width to scale height. Bower and Curry (1983) reported that scale patterns provided some of the most diagnostic characters for identifying hair samples.

     

    Regarding to the results of scale patterns we found that the animals of the same species are more likely to have similar scale patterns along the shaft of hair and even in the different parts of the body. On the other hand scale patterns show great variations between different species as shown in Figures 1, 2, 3, 4 and 5 which appeared as moderate length (short and wide) and sometimes have smooth margin or saw margin according to the species of animal. This is in agreement with the observation of Hess et al. (1985) who found that the surface scale patterns of Tayasuidae and Suidae family did not significantly differ when observed with scanning electron microscope. Inagaki and Tsukahara (1993) and Bakuneeta et al. (1993) used scale patters to identify chimpanzee hair.

     

    The study also revealed no significant difference in the scale counts of the proximal part, middle and basal parts of hair shaft when compared in the three body regions of the animals of the same species (Tables 2, 3, 4, 5 and 6). Meanwhile, comparing the scale counts in the different species

     

    Table 9: The measurements and indices in the proximal part of hair shaft at different body regions (dorsal neck, dorsum and flank) of the studied animals

    Animal species

    American black bear

    Blue nile monkey

    Barbary sheep

    Lama

    Bacterian camel

    Body regions

    Dorsal neck region

    Diameter (µm)

    31.16± 0.72c

    31.00± 0.57 c

    67.50±0.28a

    34.00±0.57b

    33.00± 0.57b

    Medullary index

    37.96± 0.29c

    50.00± 0.57b

    81.16± 0.16a

    34.90± 0.49d

    16.5± 0.28e

    Cuticular index

    7.33± 0.20a

    4.00± 0.057b

    3.60± 0.057bc

    3.26± 0.12c

    2.70± 0.5d

    Cortical index

    30.80± 0.05c

    33.20± 0.05b

    7.30± 0.05d

    42.30± 0.25a

    33.33± 0.33b

    Scale counts per (100µm)

    12.00± 0.57d

    18.33 ± 0.33c

    90.00± 2.88a

    35.00± 1.15b

    9.00± 0.57d

    X/Y feret

    1.06± 0.03d

    2.86± 0.08b

    6.00± 0.05a

    1.26± 0.03c

    1.16± 0.03cd

    Dorsum region

    Diameter (µm)

    30.33± 0.33c

    31.00± 1.10c

    67.00± 0.00a

    34.33± 0.66b

    31.33± 0.88c

    Medullary index

    36.33± 0.88c

    49.66± 0.88b

    81.66± 0.33a

    34.00± 0.57d

    16.56± 0.34e

    Cuticular index

    7.33± 0.18a

    3.96± 0.08b

    3.50± 0.10c

    3.23± 0.12c

    2.60± 0.15d

    Cortical index

    30.76± 0.08c

    33.10± 0.15b

    7.40± 0.05d

    42.53± 0.26a

    33.50± 0.76b

    Scale counts per (100µm)

    11.00± 0.57d

    19.33± 0.33c

    91.66± 3.33a

    33.33± 0.88b

    8.33±0.66d

    X/Y feret

    1.10± .05c

    2.90± 0.20b

    6.03± 0.03a

    1.23± 0.06c

    1.20± 0.00c

    Flank region

    Diameter (µm)

    31.33± 0.66c

    29.00± 0.57c

    68.33 ± 0.33a

    34.00 ± 0.57b

    31.00± 1.15c

    Medullary index

    36.66± 1.85c

    50.33± 0.33 b

    82.00± 0.57a

    35.16 ± 0.16c

    16.80 ± 0.40d

    Cuticular index

    7.30± 0.15a

    4.00± 0.05b

    3.63± 0.14bc

    3.26± 0.06c

    2.66 ± 0.14 d

    Cortical index

    30.30± 0.35c

    34.26± 0.14b

    7.60± 0.00d

    42.13 ± 0.40a

    34.00 ± 1.15b

    Scale counts per (100µm)

    12.33± 0.33cd

    21.33 ± 0.33c

    92.33 ± 6.17a

    33.00± 1.52b

    7.66 ± 066d

    X/Y feret

    1.16± 0.08c

    2.93± 0.03b

    6.03± 0.03a

    1.30± 0.00c

    1.20± 0.05c

     

    Means within the same raw in each item within each group carrying different superscripts are significantly different at (p< 0.05)

     

    revealed significant differences along the hair shaft and also according to the body region (Tables 7, 8 and 9). The species differences in the numerical features of cuticular scales were more frequently observed at the tip side than at the root and this disagreed with Sato et al. (2006) who suggested that scale counts at the distal part of hair shaft are important for the species discrimination when numerical features are used.

     

    Tonin et al. (2002) and Aris and George (2008) pointed out that the fiber diameter and scale pattern type as well as the rate of growth in fiber length and the distance between scale ridges are related to each other, they suggested that the thicker hairs showed higher density of scales, the results of our study confirmed the latter statement where barbary sheep have the greater diameter of hair shaft and higher density of scales and at the same time has the largest X/Y value among studied species and this might be due to the habitat of animal to accommodate itself during cold periods to increase the degree of insulation as the ratio of scale width to height could reflect an effective function for the cuticle scales in supporting (i.e. holding up) the hairs, these scales form a segmented tube that can support the cortex when hairs erected during cold periods in order to improve insulation. The hair cuticle cells have an extremely keratinized outer core which corroborates this idea and they are very resistant to environment (Jones and Rivett, 1997; Dobb et al., 1996; Areida et al., 2006).

     

    The ratio of scale width to scale height clearly indicates that the species specific shape and size of hair cuticle scales in mammals may be of specific value for biological interpretation with regard to hair coat structure and function (Meyer et al., 2002; Areida et al., 2006).

     

    From the observations of the present study we agreed with (Sato et al., 2006) who found that the morphological differences that are useful for species identification of animal hairs can be observed between animals classified at taxonomic position at relatively long distances from one another. Moreover animal hair morphologies may be influenced by habitat and body size, for example morphological differences in animal hairs were clearly observed between an aquatic animal and land animal and between a large sized animal and a small animal. On the other hand hair morphologies are similar between animals belonging to the same family and genus such as a dog and wolf (canidae canis) and are relatively similar between animals bearing some resemblance in terms of body size.

     

    Conclusion

     

    The measurements and indices used in the present study could provide useful information about hair from each studied species that could be of great value in their identification.

     

    ACKNOWLEDGEMENT

     

    All the authors of the manuscript thank and acknowledge their respective Universities and Institutes.

     

    CONFLICT OF INTEREST

     

    The authors declare that they have no competing interests.

     

    AUTHOR’S CONTRIBUTION

     

    Mayada Ragab Farag and Mervat Hassan Ghoniem carried out the experiment trial, performed the statistics and drafted the manuscript as well as revised the manuscript. Ali Heider Abou-Hadeed conceived the study, and participated in its design and coordination. Kuldeep Dhama reviewed and revised the manuscript. All authors read and approved the final manuscript.

     

    REFERENCES

     

  • Andy A, Tillman C (2006). Surface scanning electron microscopy of suri alpaca fiber and other members of the camel family. Science. 85-171. http://www.surinetwork.org/Resources/Documents/Tillman/SEM%20Suri%20Fiber.pdf
  • Areida SK, Ismail MF, Abdel Hady EK, Osman AO (2006). Molecular characterization of hair cuticle and its extracted proteins in seven mammalian species. Egypt. J. Hosp. Med. 23: 287–308.
  • Aris FP, George C (2008). Morphology of the hair in the Goat breed Capra prisca. J. Anim. Vet. Adv. 7(9): 1142-1145.
  • Bakuneeta C, Inagaki H, Reynolds V (1993). Identification of wild chimpanzee hair samples from feaces by electron microscopy. J. Primates. 34(2): 233-235. http://dx.doi.org/10.1007/BF02381396
  • Bernadette MM, Smith JR, Jacobs RM, Jones AOL, Altman JD (1996). Calcium, Magnesium and Phosphorus content of hair from two populations of Rhesus Monkeys. Biol. Trace. Elem. Res. 53: 147-165. http://dx.doi.org/10.1007/BF02784552
  • Bower TR, Curry K (1983). Use of ruller press to obtain cuticular impressions of guard hairs on acetate strips. J. Mammal. 64: 531-532. http://dx.doi.org/10.2307/1380377
  • Brauner P, Reshef A, Goriski A (2001). DNA profiling to trace evidence - migrating evidence in a dog biting case. J. Forensic. Sci. 46: 1232-1234. http://dx.doi.org/10.1520/JFS15127J
  • Brunner H, Coman BJ (1974). The identification of mammalian hair. Inkata Press, Melbourn, Australia, 1-176.
  • Chernova OF (2002). Architectonic and Diagnostic Significance of Hair Cuticle. J. Biol. Bull. 29(3): 238- 247. http://dx.doi.org/10.1023/A:1015482430438
  • Deedrick DW, Koch SL (2004). Microscopy of hair Part I: A practical guide and manual for human hairs. J. Forensic Sci. Comm. 6(1): 1-50.
  • Dobb MG, Johnston FR, Nott JA, Oster I, Sikorski J, Simpon WS (1996). Morphology of the cuticle layer in wool fibers and other animal hairs. J. Text. Inst. 52: 153-170. http://dx.doi.org/10.1080/19447027.1961.10750482
  • Farag MR, Abou-Hadeed AH, Ghoniem MH, Alagawany M, Laudadio V, Tufarelli V (2015). Chemical composition and mineral contents differentiation in hairs of some wild animal species. Pak. J. Zool. 47(4): 1189-1191.
  • Farah S, Tsach T, Bentolila A, Domb AJ (2014). Morphological, spectral and chromatography analysis and forensic comparison of PET fibers. Talanta. 123: 54–62. http://dx.doi.org/10.1016/j.talanta.2014.01.041
  • Gaudette BD (1999). Comparison significance of hair evidence. Identification of human and animal hair. Encyclopedia of forensic science, hair academic press, San Diego. 3: 999-1041.
  • Hess WM, J erran TF, Clyde LP, James VA (1985). Characterization of hair morphology in fsamilies tayassuidae and suidae with scanning electron microscopy. J. Mammal. 66(1): 75-84. http://dx.doi.org/10.2307/1380958
  • Inagaki H, Tsukahara T (1993). A method of identifying chimpanzee hairs in lion feces. J. Primates. 34(1): 233-235. http://dx.doi.org/10.1007/bf02381288
  • Jones LN, Horr TJ, Kaplin IJ (2001). Formation of surface membranes in developing mammalian hair fiber. J. Micron. 25: 589-595. http://dx.doi.org/10.1016/0968-4328(94)90021-3
  • Jones LN, Rivett DE (1997). The role of 18-methyle icosanoic acid in the structure and formation of mammalian hair fibers. Micron. 28: 469-485. http://dx.doi.org/10.1016/S0968-4328(97)00039-5
  • Meyer W, Schnapper A, Hulmann G (2002). The hair cuticle of mammals and its relationship to functions of the hair coat. J. Zool. 256: 489-494. http://dx.doi.org/10.1017/S0952836902000535
  • Monica B, Peric T, Ajuda I, Vieira A, Grosso L, SARA B, Stilwell G, Prandi A, Comin A, Tubaro F, Mattiello S (2015). Hair coat condition: A valid and reliable indicator for on-farm welfare assessment in adult dairy goats. Small Rumin. Res. 123(2–3): 197-203.
  • Nadia IM (2012). Simple modified freezing technique for identification of human scalp and pubic hairs. Egypt. J. Forensic Sci. 2(2): 69-72.
  • Nowak B (1998). Contents and relationship of elements in human hair for a non-industrialized population in Poland. Sci. Total. Environ. 209(1): 59-68. http://dx.doi.org/10.1016/S0048-9697(97)00298-2
  • Oli MK (1993). A key for the identification of the hair of mammals of a snow leopard (pantheraunica) habiat in Nepal. J. Zool. 231(1): 71-93. http://dx.doi.org/10.1111/j.1469-7998.1993.tb05354.x
  • Sato H, Matsuda H, Kubota S, Kawano K (2006). Statistical comparison of dog and cat guard hairs using numerical morphology. J. Forensic. Sci. Int. 185: 94 -103. http://dx.doi.org/10.1016/j.forsciint.2005.04.041
  • Sato H (2002). Statistical evaluation of morphological data of Japanese head hair and the screening of evidential hair samples by cluster analysis. J. Legal. Med. 4: 90-102. http://dx.doi.org/10.1016/S1344-6223(02)00010-X
  • Taru P, Backwell L (2013). Identification of fossil hairs in Parahyaena brunnea coprolites from Middle Pleistocene deposits at Gladysvale cave, South Africa. J. Archaeol. Sci. 40(10): 3674-3685. http://dx.doi.org/10.1016/j.jas.2013.04.031
  • Tonin C, Biancheto M, Vineis C (2002). Differentiating fine hairs from wild and domestic species: Investigations of shahtoosh, yangir and cashmere fibers. J. Textile. Res. 72(8): 701-775. http://dx.doi.org/10.1177/004051750207200809
  • Tridico SR, Houck MM, Paul K, Smith ME, Yates BC (2014). Morphological identification of animal hairs: Myths and misconceptions, possibilities and pitfalls. Forensic Sci. Int. 238: 101-107. http://dx.doi.org/10.1016/j.forsciint.2014.02.023
  • Valente A (1983). Hair structure of wooly mammoth, Mammuthus primigenius and the modern elephants, Eiphas maximus and Loxodont. Africa. J. Zool. 199(2): 271-274. http://dx.doi.org/10.1111/j.1469-7998.1983.tb02095.x
  • Wallis RL (1993). A key for the identification of some Ontariomammals. Can. J. Zool. 71(3): 587-591.
  • Zafarina Z, Panneerchelvam S (2009). Analysis of hair samples using microscopical and molecular techniques to ascertain claims of rare animal species. Malays. J. Med. Sci. 16(3): 37-42.
  •