Non-invasive Antibody Production in the Chicken

Mayo, Susan L

January 2009

The production of antibodies for analytical purposes using invasive procedures on small mammals is common practice in biomedical research. The aim of this study was to develop an efficient method for non-invasive antibody production in the chicken. This thesis presents an alternative method that eliminates the discomfort, pain and distress invoked by traditional immunization procedures on mammals by instead harvesting antibodies (IgY) from the yolk of eggs laid by orally immunized hens. An efficient oral immunization regime was developed by first trying out a suitable non-aggressive oral adjuvant with Bovine Serum Albumine (BSA) as the model antigen. It was found that the pegylated mono/diglyceride RhinoVax® (Softigen®) at a concentration of 20% (v/v) produced a good humoral antibody response in chickens as well as development of IgY antibodies in the egg yolk. The age of the chicken is important in order to have a proper humoral immune response. We found that chicken older than 22 days produced circulating immunospecific anti BSA-antibodies of of IgG, IgM and IgA class when orally immunized with BSA alone, whereas chickens 15 days old only produced IgM and IgA antibodies. This is the first report of oral immunizations with a high dose (250–300mg) of BSA in 20% RhinoVax® consisting of 3 or 5 consecutive daily doses resulting in high concentrations of immunospecific IgY antibodies in the yolk. Using this technique of three consecutive daily doses repeated after 7 weeks and after 18 weeks, a booster effect was induced after the third immunization. This is the first demonstration of a clear anamnestic immune response in orally immunized chickens. The results suggest that it may be possible to further increase the concentration of immunospecific IgY antibodies by modifying the immunization regime. It seems plausible to develop a procedure where the immunogen can be fed to the chickens as in an ordinary egg producing farm thus making antibody production not classified as an animal experiment.

Laboratory animal science

Försöksdjursvetenskap

Acetylcholine in Spinal Pain Modulation : An in vivo Study in the Rat

Abelson, Klas

January 2005

The spinal cord is an important component in the processing and modulation of painful stimuli. Nerve signals from the periphery are relayed and further conducted to the brain (nociception) in the spinal cord, and the most essential modulation of painful information (antinociception) occurs here. Several neurotransmitters are involved in spinal pain modulation, among them acetylcholine. However, the role of acetylcholine has previously been little investigated. In the present thesis, the acetylcholine release in the spinal cord was studied in vivo. By using spinal microdialysis on anaesthetised rats, the effects on the intraspinal acetylcholine release of various receptor ligands and analgesic agents were examined. This, together with pain behavioural tests and in vitro pharmacological assays, was used to evaluate the role of acetylcholine in spinal pain modulation. The four studies in this thesis resulted in the following conclusions: An increased release of spinal acetylcholine is associated with an elevated pain threshold, while a decreased acetylcholine release is associated with hyperalgesia, as seen after systemic treatment with a muscarinic agonist and an antagonist. Lidocaine is a potent analgesic when given systemically. It was found to produce an increase of intraspinal acetylcholine after intravenous injection of analgesic doses. This effect was attenuated after muscarinic, and abolished after nicotinic, receptor blockade. Various a2-adrenergic ligands, associated with nociceptive or antinociceptive effects, were found to affect intraspinal acetylcholine release via action on nicotinic receptors. Finally, the involvement of spinal acetylcholine in the analgesic effects of aspirin and paracetamol was examined. It was found that spinal acetylcholine could participate in the analgesic effects of aspirin, but not of paracetamol. The present thesis provides data that clearly demonstrate a relationship between intraspinal acetylcholine and antinociception, and elucidate interactions between acetylcholine and other mechanisms that mediate antinociception in the spinal cord.

Laboratory animals

Pain

Nociception

Antinociception

Acetylcholine

Muscarinic

Nicotinic

Spinal cord

Microdialysis

Försöksdjursvetenskap

Laboratory animal science

Försöksdjursvetenskap

Food Intake and Body Weight Gain in Male and Female Mice

Root, Callie Leah

12 April 2019

Traditional dogma is that men have a higher metabolism compared to women. Because of an increased obesity rate in women, the purpose of this study was to test the hypothesis that compared to males, females will gain more body weight per gram of food consumed. Methods: To test our hypothesis male and female mice were fed either a high or low-fat diet for 20-weeks, while monitoring food intake and body weight. At the end of the 20 week feeding plan, a final weight on the mice was taken, as well as a measurement from the nose to rump of the mouse in order to calculate a BMI. Results: Male mice consistently consumed more food than female mice, regardless of the diet. As expected mice on the high-fat diet gained more weight than mice on the low-fat diet. Further, on the low-fat diet male mice gained more weight than the female mice. Interestingly, there was no difference between the amount of weight gain between male and female mice on the high fat. However, within the same diet, male mice gained more weight per gram of food consumed. On average, male mice gained approximately double the body weight per gram of food consumed compared with female mice (51 vs. 27 mg of body weight per gram of food consumed). Conclusions: We had hypothesized that increased food intake in male mice would primarily account for the differences in body weight between male and female mice. However, contrary to our hypothesis, the data shows that male mice gained more body weight per gram of food consumed. This finding provides a novel hypothesis to explain the mechanism by which, at least in rodents, females are more resistant to obesity. Future studies comparing metabolic rate and physical activity levels will need to be performed to explore this finding further.

Weight gain

Food intake

Laboratory Animal Science

Metabolic Biology

Biological Diversity