Simple method of blood sampling  
from Indian freshwater turtles for genetic studies

Manoj Singh Rohilla, Pramod Kumar Tiwari

School of Studies in Zoology, Jiwaji University, Gwalior 474 011, India. Corresponding author.  
E-mail: pktiwari.ju@gmail.com

Submitted on 2007, 12th November; revised on 2007, 17th December; accepted 2008, 31th January.

Abstract. Biological material is now commonly employed during the characterization 
of species. Superficial blood vessels are the most appropriate sites in reptiles for blood 
sampling. In this study we describe a method of blood collection from various spe-
cies of Indian freshwater turtles for genetic characterization and discuss its advantages 
over the previously described techniques. The method proved most suitable, easy, and 
less harmful. The quantity of blood samples obtained is enough for different appli-
cations such as karyotyping, cytological examinations of cell types, isozyme analysis 
from RBCs and plasma, DNA isolation for PCR-RAPD and mitochondrial gene spe-
cific amplification. We conclude that the femoral vein is probably the most suitable 
site for blood collection from Indian freshwater turtles for various experimental pro-
cedure and methodologies related to genetic characterization.

Keywords. Femoral vein, blood sampling, Indian freshwater turtles.

Genetic characterization of endangered species is essential for proper genetic conser-
vation and management in their respective habitat. Studies on various aspects of genome 
characterization require blood or tissue samples. For this purpose, sampling from sub-
stantial number of individuals is required, but the classical methods of hematological, 
biochemical (e.g., allozyme) cytogenetic, or DNA analysis use materials from blood cells, 
spleen, liver, muscle, kidney, intestine or cell cultures of heart and skin fibroblast (Baker et 
al., 1971; Bickham, 1975; Frye, 1991; Mader, 2000). All the above methods involve killing 
or surgery, and this is generally not feasible in the case of endangered species, where the 
source as well as number of animals, both is limited.

Under such conditions, the development of new and simple methods becomes high-
ly desirable. Thus, we have optimized a safe, sterile and efficient blood sampling method, 
which is equally applicable to a variety of reptilian species, including Indian freshwater 
chelonian species.

A variety of sites in the chelonian body have been used to obtain blood, including 
heart, veins (e.g., jugular, brachial, ventral coccygeal or scapular), brachial artery, orbit-

Acta Herpetologica 3(1): 65-69, 2008 
ISSN 1827-9643 (online)  © 2008 Firenze University Press



66 M. Singh Rohilla and P. Kumar Tiwari

al sinus, cervical sinus, sub-carapacial venipuncture site and trimmed toe-nails, (Gandal, 
1958; Dessauer, 1970; McDonald, 1976; Maxwell, 1979; Owens and Ruiz, 1980; Taylor and 
Jacobson, 1981; Stephens and Creekmore, 1983; Avery and Vitt, 1984; Jacobson, 1987; 
Ulsh et al., 2000; Hernandez-Divers et al., 2002; Rogers and Booth, 2004; Gregory and 
Gabriel, 2006). Each sampling method has certain advantages and disadvantages. Some 
methods have even higher risk of infection (Gandal, 1958; Nicole et al., 2007). In turtles 
and tortoises, orbital sinus sampling method has been used for collecting small volumes 
of blood through capillary tubes (Nagy and Medica, 1986). This method, however, results 
in the dilution of blood sample with extra cellular fluids and secretions, which may alter 
the composition of plasma and affect percent volume of cellular components. Since lym-
phatics are well developed in chelonian forelimbs (Ottaviani and Tazzi, 1977), obtaining 
blood samples from veins and arteries may result in hemodilution with lymph. Sub-cara-
pacial venipuncture site is located at the angle where cervical vertebrae join the shell and 
is formed by the junction of the common intercostals and the caudal cervical branch of 
the external jugular veins. Blood is readily obtained from a post occipital venous plexus, 
that is located dorsally to the cervical vertebrae, behind the occipital protuberance of the 
skull of tortoises (Gottdenker and Jacobson, 1995). 

Most of the published techniques have been applied in adult turtles and hatchlings 
of long-tailed species such as Graptemys geographica, Trachemys scripta and marine turtle 
species (Gregory and Gabriel, 2006; Wibbels et al., 1998; Bennett, 1986; Ulsh et al., 2000). 
However, the tail is very short in Indian freshwater turtle species like Asperidetes gangeti-
cus, Geoclemys hamiltoni, Kachuga sp., Lissemys punctata, and thus, blood collection from 
the coccygeal vein is very difficult. The tail cannot be held firmly by any recommended 
device as described for Trachemys scripta (Ulsh et al., 2000). In addition, the amount of 
blood obtained from such species is very low, not enough for lymphocyte separation and 
culture for cytogenetic characterization. We collected blood samples from juveniles (less 
than 20 g body mass) and adults (weighing up to 5 kg) of both, hard shell K. dhongoka 
(n = 5) and G. hamiltoni (n = 1) and soft shell turtle species L. punctata (n = 10) and A. 
gangeticus (n = 1). 

Adult individuals of soft shell turtles were collected from ponds and dams located in 
the Gwalior-Chambal region with the help of local fishermen and also purchased from 
local fish markets. The animals were reared in an artificial pond of dimension 5×2×1 m 
near the animal house of the Department of Zoology. Animals were fed on freshwater fro-
zen fishes, live earthworms, snails, and aquatic weeds. The animal care procedures followed 
in this study were as recommended by ethical committee of Jiwaji University and as per 
guide lines of the Forest Department of Madhya Pradesh Government (Rohilla et al., 2006).

The hind limbs were cleaned with distilled water-soaked cotton and after complete 
drying swabbed twice with absolute ethanol. The femoral vein site was identified for accu-
rate vein puncture for collection of blood. It is located in the midventral part of the femur 
above the knee joint. A small muscle depression appears which was identified as the cor-
rect site for venipuncture (Fig. 1). Before inserting the needle in the skin, 50-100 μl of 
anticoagulant was taken into the syringe. The plunger of the syringe was withdrawn gently 
(up to the 0.1 to 0.3 ml mark) to create a vacuum for easy withdrawal of blood. A 2-6 mm 
deep insertion of the needle is required, which, however, depends on the musculature and 
age of the animal, generally being 2-3mm in hatchling or juvenile. The correct insertion 



67Simple method of blood sampling from Indian freshwater turtles for genetic studies

of needle requires a 30o-40° angle downward, between the thigh and the needle. If blood 
does not appear in the syringe immediately, the syringe is gently rotated and the angle is 
slowly decreased until blood enters into the syringe. 

From a healthy 5 kg animal, we could easily withdraw about 4-5 ml blood through the 
femoral vein with the help of 5 ml syringe equipped with 25G, 5/8-inch needle pre-flushed 
with sodium heparin, but keeping 250 μl heparin saved in the syringe to prevent immedi-
ate clotting. Similarly, about 0.2-0.3 ml of blood was collected from one month old juve-
niles of three Kachuga species with the use of a 13 mm insulin or tuberculin syringe. After 
blood collection the skin was again swabbed with absolute ethanol and medicated with 
Betadine solution (Tincture Iodine) or Sofaramycin cream to prevent microbial infection. 
Finally the turtle was left on the sand to recover for about one to two hours before trans-
ferring to water. None of the adults, hatchling and juvenile turtles used to collect blood 
showed any sign of diseases or health related problems, even after three months. 

Our procedure on soft shell turtle species of Lissemys and Kachuga allows to collect 
enough blood for cytology (see Mader, 2000), genetic characterization, including identifi-
cation of cell types for cell culture, gene-specific PCR amplification, RAPD fingerprinting 
and allozyme analyses from RBCs or whole blood. This method appeared more appropri-
ate, effective and easy with several advantages. The femoral vein is located in the periph-
eral part of the body, hence, there is no chance of injury to vital organs of the body and 

Fig. 1. Position and site (femoral vein) of blood collection from the hind leg of adult freshwater soft shell 
turtle L. punctata (Inset: enlarged view to locate the exact position).



68 M. Singh Rohilla and P. Kumar Tiwari

sufficient amount of blood can easily be withdrawn from both large and small-sized ani-
mals. The method demonstrated an easy mode of holding the animal, expected to be less 
painful, does not require anesthesia and provides sterile conditions. This method can be 
adopted for several other reptilians also with some modifications (see Frye, 1991). On a 
wild lizard, Varanus bengalensis, it proved to be equally effective (our unpublished obser-
vation). However, this technique may not be equally applicable for Indian tortoise species 
(i.e., Geochelone sp.) due to hard scales on the legs, which can damage the tip of the needle 
and unlike freshwater turtles, the leg protrusion is difficult to obtain easily.

ACKNOWLEDGEMENTS

We gratefully acknowledge the Department of Science & Technology (DST), and University 
Grants Commission (UGC), Govt. of India, New Delhi for providing financial support through a 
research project to PKT and DRS-SAP programme to School of Studies in Zoology, Jiwaji University. 

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