Short restraint time does not influence markers of serum oxidative stress in homing pigeons (Columba livia)

Restraint in a confined space, such as a cage or a box, may be perceived by birds as a stressful condition. Some concern has been expressed about restraining homing pigeons (Columba livia) in transport crates for sport or for scientific research. Therefore, this study sought to test whether short restraint time in a transport crate for 1, 2 or 18 (overnight) h causes oxidative stress in homing pigeons and whether it is more stressful than flying. To isolate the effect of crowding from that of transport per se, the pigeons were kept in an immobile crate, that is, without any movement. To quantify oxidative stress, we measured serum levels of oxidative damage (ROMs) and of antioxidant capacity (OXY). We found that pigeons restrained in transport crates showed no significant variation for both markers of oxidative stress, regardless of the duration of restraint. Conversely, pigeons which had flown around 200 km had increased levels of oxidative damage and decreased levels of serum OXY, both clear manifestations of oxidative stress. These results suggest that maintaining homing pigeons in transport crates for a short time (i.e. 1–18 h) does not cause oxidative stress.     

Chlamydial infections in feral pigeons in Europe: Review of data and focus on public health implications

Feral pigeons (Columba livia domestica), which thrive in most European towns and cities, are commonly infected with the zoonotic bacterium Chlamydophila psittaci, the agent of psittacosis (also known as ornithosis) in humans. A number of surveys carried out over the last thirty years across Europe have detected high seropositivity values and high percentages of infection in feral pigeon populations. Overall, when considering data from 11 European countries, seropositivity values to C. psittaci in the sampled populations ranged from 19.4% to 95.6%. In most surveys, the complement fixation test was used, and antibodies were detected in 19.4-66.3% of the samples, with a median of 46.1%. Indirect immunofluorescence and ELISA tests were employed less frequently, but led to the detection of higher percentages of seropositivity (23.7-67.7% and 35.9-95.6%, respectively). Attempts to grow C. psittaci in cell culture or embryonated chicken eggs were successful in 2-42.3% and 0-57.1% of samples, respectively, antigen detection methods were positive in 2.3-40% of samples, while conventional PCR and real-time PCR using different genomic targets detected the organism in 3.4-50% of samples. Twenty-five C. psittaci isolates from pigeons were typed as ompA genotype B (n=14), E (n=10) and E/B (n=1). The huge increase of feral pigeon populations in Europe is a major cause of concern for the detrimental effect of pigeon droppings on environmental hygiene, in addition to the extensive damage due to the fouling of buildings and monuments. The most important pathogenic organism transmissible from feral pigeons to humans is C. psittaci, with 101 cases of disease reported in the literature. Exposure to C. psittaci-contaminated dust, direct contact with pigeons through handling and, to a lesser extent, through pigeon feeding have been identified as hazardous exposures in more than half of the human cases, while loose or transient contacts with feral pigeons have been mentioned in about 40% of the cases. Education initiatives as to the communication of a health risk resulting from contact with pigeons and pigeon excreta should primarily be targeted at individuals who may be exposed to C. psittaci-contaminated dust, such as demolition/construction workers. Recommendations to this category of workers include wearing protective clothes with hoods, boots, gloves and air filter face masks when removing pigeon faeces from roofs, garrets and buildings, especially if working indoors. Monitoring for C. psittaci infections in these workers over time should also be considered. Children should be warned not to handle sick or dead pigeons, and immunocompromised individuals should be advised to carefully limit their contact to feral pigeons. Culling of pigeons by shooting or poisoning is both unethical and ineffective as the place of the killed birds in the population is quickly filled by new juveniles or immigrating birds from neighbouring areas. Pigeon-deterring systems, such as nets and plastic or metal spikes applied to buildings and monuments will prevent their fouling, and the administration of contraceptive drugs may allow size regulation of the pigeon populations. Nevertheless, the measure that will ultimately lead to permanent reduction and will establish healthy sustainable populations is the restriction of indiscriminate feeding by pigeon lovers. The erection of dovecotes and artificial breeding facilities should be considered for providing shelter and a balanced diet to the birds, as well as a chance of interaction for pigeon lovers in a hygienically controlled environment.     

Efficacy of toltrazuril and clazuril against experimental infections with Eimeria labbeana and E. columbarum in racing pigeons

The efficacy of toltrazuril in comparison with clazuril on heavy experimental Eimeria labbeana and E. columbarum infections in pigeons was investigated. The minimum required dose of toltrazuril to completely suppress oocyst excretion is 20 mg/kg body weight for 1 day. After treatment with toltrazuril, there was a dose-dependent period during which pigeons remained negative; at a dosage of 35 mg/kg or higher, this period was at least 4 weeks. Clazuril at the recommended dose of 2.5 mg/pigeon resulted in a rapid suppression of oocyst excretion, but oocysts were again observed in the feces 20 days after treatment. The fact that oocysts appeared again in the feces 3 to 5 weeks after treatment can probably be explained only by a persistence of endogenous stages, which are not affected during treatment, rather than by a reinfection. Reinfection of the previously medicated and infected pigeons 30 days after the first infection provided some data on possible induced immunity.     

Pigeon sport and animal rights

To begin, a short overview of the organization and the realization of the racing pigeon sport. Some physiological facts, relevant to racing pigeons, will be touched on. Lastly, a focus on the flights, their completion and the problems involved with the, in some cases, high number of lost pigeons.The German Club of Pigeon Breeders, has made improvements but, it is certainly not enough.The topic of "City Pigeons" will be briefed.The final part deals with pertinent animal rights issues, causes of mishaps, and some rectifying possibilities, which are available to the government veterinarian. Special emphasis will be placed on the international uniformity of this issue.The lecture should prove that there is a need for every government veterinarian to become actively involved, because the described problematic has a major effect on a very large number of animals.     

Evaluation of antibiotics for racing pigeons (Columba livia var. domestica) available in The Netherlands

Antibiotics and chemotherapeutics marketed for use in racing pigeons (Columba livia var. domestica) were evaluated by comparing the dosages and indications given by the manufacturers with the data obtained by pharmacokinetic, bacteriological and efficacy studies. This comparison showed that only three of the recommended dosages and indications of the 60 formulations marketed in The Netherlands are scientifically sound and in accordance with the literature. It is to be expected that the majority of the antimicrobials for pigeons will not satisfy the requirements for final registration as a pigeon therapeutic under the Dutch Veterinary Medicines Act of 1985. Several factors affecting drug availability are discussed, such as the different routes of administration and the influence of food. The public health aspects of the consumption of medicated pigeons is also discussed. Although there is no legislation with regard to this subject, a recommended withdrawal time of 10 days for the majority of the antimicrobials seems advisable.     

Newcastle disease.

Since 1926, there have been three epizootics of ND. The latter two have been directly linked with psittacine species and Racing Pigeons. The modern poultry industry is extremely vulnerable to the effects of NDV, once it gains entry to any facet of the industry. Consequently considerable expense and effort are expended to keep the virus at bay. The main threat continues to come from psittacine species and racing pigeons. The considerable international trade in these birds, together with rapid air transport, can allow virulent NDV to gain entry to a country while exotic birds are incubating the disease. It is hoped that quarantine barriers and requirements will prevent the virus from entering a country, but smuggling continues and constitutes the biggest risk. Domestic avian pets are also vulnerable to the virus. It is hoped that new in vitro testing procedures, such as monoclonal antibody and oligonucleotide fingerprinting techniques, may be used to identify rapidly and characterize emergent virulent strains, so that appropriate measures may be taken to prevent infection of commercial poultry and domestic pets.     

Viral infections in pigeons

This review provides a current update on the major viral diseases of the domestic pigeon (Columba livia domestica), based on scientific reports and clinical experience. Paramyxovirus 1, adenovirus, rotavirus, herpesvirus 1, poxvirus and circovirus infections are described according to common clinical signs and target tissues. Since pigeons are sometimes treated as if they were poultry, the review also summarises the common viral infections of poultry for which pigeons are considered resistant. It is hoped that the review will provide a useful reference for veterinarians and others and offer advice on the diagnosis, treatment and prevention of the major infectious diseases of pigeons.     

Infections of pigeons as a risk to the health of humans and animals

Both, domestic and feral pigeons may be carriers of hazardous agents for man and animals. Ectoparasites of pigeons can trouble humans. Feces of pigeons can serve as substrate for the agent of cryptococcosis of man and animals. The occurrence of avian tuberculosis, campylobacter infections, pseudotuberculosis and pasteurellosis in pigeons seems to be of less significance. Salmonella infections of man and animals are less likely attributable to pigeons as the source of infection. The agent of ornithosis may be distributed by pigeons, but humans are predominantly infected by psittacines. The role of doves in the epidemiology of German measles is not clear, but there is little evidence that they are involved in other harmful virus infections in Europe. A possible risk for the health of man can not be excluded if rooms are located directly in contact with dovecotes or garrets colonized with wild doves. An increased risk can be supposed for pigeon breeders and persons feeding feral doves.     

Occurrence of parasitic invasions in domestic pigeons (Columba livia domestica) in the Northern Poland

Considering the dynamic development of domestic pigeons breeding in Poland, working out preventive programs for this species of birds becomes necessary. Preventive programs should be elaborated based on epizootic situation in a particular area and should be adapted to it. The aim of the present study was to evaluate of the occurrence of parasitic invasions in domestic pigeons in the Northern Poland. In years 2005/2006, 55 lofts of carrier pigeons and 11 lofts of fancy pigeons were examined. One hundred and three individual dropping samples collected during pigeon exhibitions were also investigated. The study revealed that 56.4% of carrier pigeons lofts and 90.9% of fancy pigeons lofts were infected by coccidia. Ascaridia (A.) columbae was found in 5.5% lofts of carrier and 15.5% of fancy pigeons on the exhibitions. Eggs of Capillaria (C.) obsignata were found in 3.6% carrier pigeons and in 36.4% fancy pigeons lofts. Trichomonas columbae were observed in 61.8% of carrier pigeons and in 100% of fancy pigeons lofts.     

Limited susceptibility of pigeons experimentally inoculated with H5N1 highly pathogenic avian influenza viruses

An experimental infection study was performed using pigeons reared for racing or meat production in Japan and clade 2.2 and 2.3.2 isolates of H5N1 highly pathogenic avian influenza virus to evaluate the possible role of pigeons in virus transmission to poultry. In experiment 1, when 20 pigeons were intranasally inoculated with high or low viral doses, no inoculated pigeon exhibited clinical signs for 14 days. Drinking water and almost all swab samples were negative for virus isolation. Virus isolation was positive in 3 oral swab samples from 2 pigeons from day 2 through 4 postinoculation, but viral titers of positive samples were extremely low. Immunohistochemical analysis for virus detection was negative in all tissue samples. Along with seroconversion in a limited number of pigeons postinoculation, these results suggest that pigeons have limited susceptibility to the virus used for experimental infection. In experiment 2, when uninoculated chickens were housed with virus-inoculated pigeons, all pigeons and contact chickens survived for 14 days without exhibiting any clinical signs. According to serological analysis, the chickens did not exhibit seroconversion after close contact with inoculated pigeons. Our data suggest that the risk posed by pigeons with respect to the transmission of the H5N1 highly pathogenic avian influenza virus to poultry would be less than that for other susceptible avian species.     

On the importance of bacterial L-forms in pigeons

Following a definition of bacterial L-forms and a literature review on introduction and reversion of bacteria to and from L-forms, respectively, the results of a study comprising 587 samples (316 pigeons and 271 pigeon eggs) are reported. As a control 25 free living pigeons and 25 eggs of those pigeons were used, because antibiotic treatment of these could be excluded. From 79 samples (75 pigeons and 4 eggs) Salmonella typhimurium var. copenhagen (STMC) was isolated (none from the urban pigeons), of them 11 in the L-form from joints and organs and 3 from eggs. 325 of other bacterial isolates were found as L-forms (= approx. 40%). Out of 168 serum samples investigated, 33.9% showed antibodies against STMC. Corresponding antibodies could only be demonstrated in 73.4% of the pigeons with a STMC isolate. The occurrence of L-forms explains resistance to therapy and the failure of vaccines. The high frequency of L-forms is probably an indication of an inconsequential use of antibiotics in managing pigeon diseases.     

不同日龄乳鸽肠道CaBP-D28k基因表达的变化规律研究

为了解乳鸽肠道钙吸收规律,以满足乳鸽生产中钙的营养需要,试验将48对健康种鸽随机分为8个重复,每个重复6对,产蛋后由种鸽自然孵化和哺育乳鸽,在乳鸽7、14、21、28日龄时称量体重,平均体重分别为(120.27±31.37)g、(264.35±88.77)g、(399.22±75.04)g和(454.16±38.39)g,分别从每个重复选取1只体重适中的乳鸽,取其嗉囊内容物(鸽乳),并对其十二指肠和空肠肠段进行采样,测定鸽乳钙含量和肠道CaBP-D28k的相对表达量。结果表明:7日龄鸽乳钙含量显著低于21、28日龄鸽乳钙含量(P<0.01);7日龄时十二指肠和空肠中CaBP-D28k的表达量显著高于14、21、28日龄的表达量(P<0.01);且CaBP-D28k在7～28日龄乳鸽十二指肠的表达量显著高于在空肠的表达量(P<0.05)。由此可见:鸽乳的钙含量随着乳鸽日龄的增大而增加,乳鸽肠道CaBP-D28k基因表达量随着日龄增大而减少,十二指肠是鸽进行钙载体吸收的主要部位。     

Neurotropism of highly pathogenic avian influenza virus A/chicken/Indonesia/2003 (H5N1) in experimentally infected pigeons (Columbia livia f. domestica)

This investigation assessed the susceptibility of experimentally infected pigeons to the highly pathogenic avian influenza virus (HPAIV) H5N1 that caused recent outbreaks of avian influenza in birds and humans in several countries of Asia. For this purpose 14 pigeons were infected ocularly and nasally with 10(8) EID50 and clinical signs were recorded and compared with five chickens infected simultaneously as positive controls. The chickens demonstrated anorexia, depression, and 100% mortality within 2 days postinoculation. Three of the pigeons died after a history of depression and severe neurological signs consisting of paresis to paralysis, mild enteric hemorrhage, resulting in a mortality of 21%. Gross lesions in these pigeons were mild and inconsistent. Occasionally subcutaneous hyperemia and hemorrhage and cerebral malacia were observed. Microscopic lesions and detection of viral antigen were confined to the central nervous system of these pigeons. In the cerebrum and to a minor extent in the brain stem a lymphohistiocytic meningoencephalitis with disseminated neuronal and glial cell necrosis, perivascular cuffing, glial nodules, and in one bird focally extensive liquefactive necrosis could be observed. The remaining nine pigeons showed neither clinical signs nor gross or histological lesions associated with avian influenza, although seroconversion against H5 indicated that they had been infected. These results confirm that pigeons are susceptible to HPAIV A/chicken/Indonesia/2003 (H5N1) and that the disease is associated with the neurotropism of this virus. Although sentinel chickens and most pigeons did not develop disease, further experiments have to elucidate whether or not Columbiformes are involved in transmission and spread of highly pathogenic avian influenza.     

The detection of Salmonella typhimurium varatio copenhagen DT 2 in purebred pigeons

On the occasion of a large exhibition of pure-breed fancy pigeons 398 animals from 49 different dovecotes were examined for Salmonella shedding. Faecal samples were taken after caging of the birds for the exhibition and after 3 days, before the end of the exhibition. Salmonella were detected in faeces of 28 out of 398 pigeons (7.04%). 10 birds were Salmonella positive only after caging for the exhibition, 10 other animals only before the end of the exhibition, and 8 pigeons at both occasions. The Salmonella positive birds originated from 15 different dovecotes, i.e. in ca. 30% of the dovecotes at the exhibition at least 1 Salmonella positive pigeon was identified. The share of positive birds in these dovecotes varied between 5% and 83%. All Salmonella isolates belonged to the serovar Typhimurium variant copenhagen and were of phage type DT 2. The results of this study do not provide complete evidence on the spreading of Salmonella organisms from birds infected at time of caging to other pigeons during the exhibition, however, such transmission cannot be excluded. In only 18 dovecotes pigeons were immunised against Salmonella Typhimurium. However, in these dovecotes all breeder birds but only 13% of the young pigeons had been immunised. Among the vaccinated breeder pigeons the number of Salmonella positive birds was considerably lower (not significant) than among the non-vaccinated breeders. There is epidemiological evidence that vaccination of pigeons has a considerable protective effect against Salmonella exposure. However, in order to effectively reduce Salmonella findings in pure-breed fancy pigeons it is recommended to provide vaccination to pigeons in a greater number of dovecotes and to include the progeny, too.     

Review of the literature on avian influenza A viruses in pigeons and experimental studies on the susceptibility of domestic pigeons to influenza A viruses of the haemagglutinin subtype H7

The scientific literature of the past century is reviewed on fowl plague (presently termed highly pathogenic avian influenza, HPAI) in pigeons. HPAI viruses cause epidemic disease outbreaks with high rates of losses in many avian species, particularily in chickens and turkeys. Also susceptible to disease are quails, guinea fowl, ducks, geese, ostriches, passerine birds, and birds of prey whereas conflicting reports on the susceptibility of the domestic pigeon exist. Based on literature reports and on own experiments, and applying as criteria for judgements clinically overt forms of disease, virus multiplication plus shedding and seroconversion, it is concluded that domestic pigeons are only partially susceptible to influenza A viruses of the haemagglutinin subtype H7. Infection of pigeons with H7 viruses results only in some of them in signs, virus shedding and seroconversion. Using the same criteria, pigeons appear to be even less susceptible to infection with influenza A viruses of the H5 subtype. Only one of five publications describe in 1/19 pigeons exposed to H5 influenza A virus depression one day before death, and only 2/19 multiplied and excreted virus, and 1/19 developed circulating antibodies. Consequently, pigeons play only a minor role in the epidemiology of H5 influenza viruses. In contrast, following infection with influenza A virus of the subtype H7 clinical signs in pigeons consist of conjunctivitis, tremor, paresis of wings and legs, and wet droppings. H7-infected pigeons multiply and excrete H7 viruses and develop circulating antibodies. Albeit of the status of infection, free-flying domestic pigeons can act as mechanical vectors and vehicles for long-distance transmission of any influenza A virus if plumage or feet were contaminated.     

COMPARATIVE ULTRASONOGRAPHIC INVESTIGATIONS OF THE GASTROINTESTINAL TRACT AND THE LIVER IN HEALTHY AND DISEASED PIGEONS

The use of ultrasound as a diagnostic tool in birds has been documented for cardiac, urogenital, and liver disease. However, its use in gastrointestinal tract disease is not defined. Therefore, the purpose of this study was to compare the ultrasonographic findings of the intestine and liver of six healthy racing pigeons with those of six racing pigeons with gastrointestinal disease. The echogenicity of the liver was significantly different between the two groups. Pigeons with gastrointestinal disease had less homogeneous liver echogenicity with focal heterogeneous areas and the hepatic blood vessels were visible and dilated. The duodenum was visualized and its mean diameter of 7.2 +/- 0.3 mm in the diseased pigeons was significantly wider (P < or = 0.001) than the 5.7 +/- 0.2 mm in healthy birds. The thickness of the duodenal wall in healthy and diseased pigeons was 1.6 +/- 0.1 and 2.4 +/- 0.1 mm, respectively, and they were significantly different (P < or = 0.001). We defined baseline measurements for the duodenal loop in pigeons and provided evidence that ultrasound can be a useful diagnostic tool for investigating intestinal disease in pigeons.     

Plasma biochemistry in pigeons experimentally infected with Salmonella.

Ten pigeons were crop inoculated with 1 x 10(9) colony-forming units of Salmonella typhimurium var. Copenhagen and observed during 28 days. Ten sham-inoculated pigeons served as noninfected controls. Clinical signs after Salmonella infection consisted of polydipsia, polyuria, and diarrhea. Morbidity was 90%, but there was no mortality. All inoculated pigeons showed fecal excretion of Salmonella for at least 7 days. Biochemical analysis of plasma samples taken at 3-day intervals indicated decreased concentrations of creatine kinase (CK)-MM and CK-MB isoenzymes and elevated total protein and alpha- and gamma-globulin values. No consistent changes in the level of 17 other blood parameters were observed. After 28 days, all pigeons were necropsied. Gross lesions and bacteriologic and histologic examination indicated septicemia in all Salmonella-inoculated pigeons. Results indicate that Salmonella septicemia in pigeons induces only limited changes in biochemical blood parameters. Decreased CK concentration was a consistent finding, however, and may therefore be a useful aid in the diagnosis of salmonellosis in pigeons.     

鸽新城疫病毒的分离与鉴定

用SPF鸡胚从疑为鸽新城疫的浙江温州某肉鸽场分离到一株毒株。该毒株能凝集鸡红细胞,初代分离毒HA效价高达8 log2;且其凝集作用能被鸡新城疫标准阳性血清抑制;将分离毒回归鸽,复制出与自然病例相似的临床症状和病变,且感染后10d内全部死亡,说明为强毒株。试验结果表明该毒株为鸽新城疫病毒。     

Perspectives on veterinary infectious disease control in the European Economic Community

The internal market of EC from 1993 is a provocation for the veterinary services of the member states to prevent dangers by animal infectious diseases and zoonoses in a big territory without borders. The systems for the control of animal infectious diseases, transport and trade have to be adapted and the veterinary services, especially on the local basis, will have more responsibility, they will be in action more as in the past and more intensive too. Primary aim is to reach a high uniform animal health level in the whole community. This requires more burden, strong and consequent measures as till now in the concerned region or member state. The control of infectious diseases in EC will stay on three big column --uniform measures for protection against animal infectious diseases, --common system for the control within the EC, --common control system on outside borders of EC for import from third countries. The already accepted and applied principle of regionalization will get essential importance. EC will participate in financing the control of animal infectious diseases particularly of very dangerous diseases, but also in certain control- and surveillance-programs. The veterinary controls on the internal borders in EC up to now will be replaced by controls at the place of origin and the place of destination. Imports from third countries will be controlled on outside-borders of EC.(ABSTRACT TRUNCATED AT 250 WORDS)