INTRODUCTION

Establishment of baseline concentration levels for blood constituents is a prerequisite for accurate interpretation of clinical pathological data.These are however often subject to variation due to factors such as age, sex, physiological status and animal husbandry practices, and ecological factors such as geographical location. Paucity of information on the ostrich (Struthio came/us) makes the need for this knowledge even more urgent in countries where ostrich farming is in its infancy.

Concentrations of biochemical variables are used to diagnose illness not only in domestic animals (Bruguere-Picoux, Bruguere, Basset, Sayad, Vaast & Michaux 1987; Kaneko 1989), but also birds (Woerpel & Rosskopf 1984). Comparative values of ostrich blood chemistry have been presented by various authors (Stoskopf, Beall, Ensley & Neely 1982; Van Heerden, Dauth, Jarvis, Keffen, Denny, Dreyer & Kriek 1985; Levy, Perelman, Waner, Grevenbroek, Van Creveld &Yagil 1989; Palomeque, Pinto & Viscor 1991; Okotie-Eboh, Bailey, Hicks & Kubena 1992).

The main objective of this paper was to present baseline levels of some blood constituents of clinically normal adult ostriches aged about 2 years.

MATERIALS AND METHODS

Blood samples were obtained from 126 clinically normal, farmed adult ostriches of either sex, aged about 2 years, just before the breeding seasons of the hens started. The bids were kept in fenced pens and were fed ad libitum on a commercial ostrich feed ration. The feed contained:

These ostriches were hatched from eggs laid on an ostrich farm in Lobatse District, Botswana. They were placed in a crush in order to restrain them for the bleeding operation. Prior to bleeding, the birds were blindfolded with a sock made out of semi-transparent material to minimize the stress of handling. The brachial vein-the preferred site for venipuncture in ostriches-was exposed, cleansed with a cotton swab, moistened with an aqueous solution of Savlon (a disinfectant containing chlorhexidine gluconate (Johnson & Johnson, East London, South Africa), followed by another swab moistened with 70% alcohol. Blood was collected into vacutainer tubes without anticoagulant at the same hour (10:00-11:00) in order to reduce possible variations associated with diurnal changes. It was allowed to clot for 1 h at room temperature and the serum was immediately harvested to prevent the diffusion of potassium from the clot into the serum. Serum samples from each bird were kept in 1 ml aliquots at 4 deg C for a maximum of 4 h being analyzed. The sampling exercise was done during the course of 1 month in order to avoid introducing seasonal effects which usually influence the diet and the physiology of the birds.

Serum samples were analyzed for copper and zinc colorimetrically on a UV spectrophotometer (Shimadzu 1601) using commercial kits (Boehringer Mannheim Diagnostics, Germany) for copper and (Wako Chemicals GmH, Germany) for zinc, respectively. Serum zinc levels were quantitated using an in vitro colorimetric method involving deproteinization with tricloroacetic acid. Thereafter, the zinc that is released binds to a chromogenic component forming a reddish violet chelate whose absorbance, when measured at a wavelength of 560 nm, is directly proportional to the amount of zinc in the serum. Serum copper was determined using diethyldithiocarbamate as the chromogen with the resulting golden yellow complex which is read at a transmission wavelength of 440 nm.The detailed protocols for the methodologies for both copper and zinc were as stipulated by the manufacturers of the kits who also provided the control serum samples for the tests.

The manganese (Mn) content of the serum samples was determined using Atomic absorption spectrometry (Model-Varian Techtron). Samples were read using a hollow cathode lamp current of 4 mA, the slit width was 0,5 nm and the wavelength optimized at about 279,5 nm. Average absorption was determined over a period of 5 s. The concentration of Mn in the sample was determined using a linear calibration curve of three prepared standards (Clinical Science Diagnostics, South Africa).

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The analytes shown in Table 4: phosphorus, calcium and magnesium including enzyme activities, were determined from serum using a chemical analyzer (Vitalab Selectra, Merck Instruments) fitted with an isoselective electrode (ISE) for the determination of electrolytes-sodium, potassium and chloride. This chemical analyzer has a built-in automatic calibration system using commercial calibrators (SMT calibrator, Merck) supplied with the reagent with the kits.

Parametric means (means +/- s.d.) and reference ranges including outlying figures, were determined.

RESULTS AND DISCUSSION

Mean values and reference ranges of some ostrich blood analytes are presented in Tables 1-4. The present study showed that the mean value of the serum electrolyte sodium was higher than that reported by other authors, Levy etal. (1989) and Van Heerden et al. (1985). While the chloride value was comparable to the values given by these authors, the potassium value was significantly higher than that given by Van Heerden et al. (1985) and almost twice that obtained by Levy et al. (1989). This may probably be attributed to fast diffusion of potassium from the erythrocytes during blood clotting at room temperature.

The serum mineral levels of calcium, phosphorus and magnesium were also elevated compared to the values obtained by the other authors. Calcium metabolism is important in laying birds and bone mineralization (Mori & George 1978; Kenny 1986). Furthermore, Gandini, Burroughs & Ebedes (1986) demonstrated dietary calcium-responsive tarsometatarsal bone deviations. Deficient formation or poor mineralization of the osteoid matrix has also been associated with deficiencies in the microminerals zinc, copper, calcium, phosphorus, magnesium and manganese (Gandini et al. 1986). Compensatory elevations in the serum levels of these minerals may account for the disparity between results of the present study and those reported by Van Heerden et al. (1985); Levy et al. (1989); Okotie-Eboh et al. (1992) and Bezuidenhout, Burger, Reyers & Soley (1994). Physiological factors such as age and sex are also known to influence these parameters (Mori & George 1978). It should be pointed out that the level of manganese was at the lower end of the detection limit and as such they may not be consistently accurate.

Activity due to serum AP was comparable to that reported by Levy et al. (1989) and Van Heerden et al. (1985), but was twice as high as that obtained by Okotie-Eboh et al. (1992). Elevations may be due to physiological increase in osteoclastic activity typical of normal bone growth.

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TABLE 1

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TABLE 2 TABLE 3 TABLE 4

The range of enzyme activity due to creatinine kinase was comparable to the values reported by all the authors, except Okotie-Eboh et al. (1992).

The discrepancies in the levels of the CK could be attributed to increased muscular activity as a result of the birds' struggling while being restrained during the bleeding process (Spano, Pedersoli, Kemppainen, Krista & Young 987). This enzyme, in addition to GT, is found in high concentration in skeletal for the high levels of GT were obtained even in the repeat determinations.

Levels of the total protein, as well as albumin, were higher in this study than the values mentioned by Levy et al. (1989); Van Heerden et al. (1985); Palomeque et al. (1991) and Okotie-Eboh et al. (1992) in contrast to levels of uric acid, total bilirubin, glucose and cholesterol which were lower in this study.

Palomeque etal. (1991) reported urea values higher than those in the present study although they were within the same general range. According to Sturkie (1965), high blood urea in ostriches and birds in general may result if they ingest large quantities of animal protein. Also catabolism of body protein as in dietary deficiency in essential amino acids may elevate levels of urea. Considering that free-living ostriches are herbivores and these ostriches were not fed animal protein, elevation in urea levels was paradoxical.

Birds are uricotelic and produce uric acid as the major nitrogenous end-product of the metabolism of protein (Lewandowski, Campbell & Harrison 1986). It has been suggested that blood levels of uric acid increase in animals fed on a high animal protein diet (Bell & Sturkie 1965). Low uric acid levels were anticipated in this study since ostriches are herbivores and the ostrich feed did not contain any animal protein.

Cholesterol levels in this study were 50% lower than those reported in other studies. This variation can be attributed to variations caused by circadian rhythms as described for certain other bird species (GarciaRodriguez, Ferrer & Recio, Castroviejo 1987) or diet (Mori & George 1978) for it is known that higher levels of fat and low protein may result in high serum cholesterol and vice-versa (Perry, Obrecht, Williams & Kunzel 1986).

Low plasma glucose levels could have been as a result of rapid utilization by the erythrocytes (Dolnik 1973). In birds, variation in the level of this metabolite may also be a consequence of the absorptive rate of the bird. Seasonal variations of glucose have also been described in the songbird, Silvia borin (Bairelein 1983). Ostriches might possibly follow a similar trend.

While the serum creatinine figures obtained were comparable to those given by Levy et al. (1989), they were lower than values reported by Van Heerden et al. (1985); Okotie-Eboh etal. (1992) and Palomeque et al. (1991). Variations in the concentrations of creatinine, an indicator of renal integrity can be explained in terms of its relation with diet (Woerpel & Rosskopf, 1984). Various bird species fed on a diet containing animal protein had higher levels of creatinine than those not receiving such protein.

The mean levels of triglycerides in the present study were comparable to those reported for ostriches by Levy et al. (1989). It is suggested that this discrepancy can be attributed to differences in the diet of ostrich populations under different animal husbandry practices.

The concentrations of the various analytes presented in this study may be used as a guideline for baseline values of adult farmed ostriches in Botswana, irrespective of sex and animal husbandry practices. The results can also form a basis for future investigations pertaining to these analytes.

ACKNOWLEDGEMENTS

This study was financially supported by the Research and Publications Committee of the Botswana College of Agriculture. We thank the staff of the National Veterinary Laboratory for their technical assistance.