429 DRYSIST by OPP Group & Castañe (Industry Innovation)

 

 

429 Industry Innovation – DRYSIST by OPP Group & Castañe

429 Industry Innovation
DRYSIST by OPP Group & Castañe
In Significant Impact Groups: Biosecurity \External biosecurity; Vehicles; Pathogen management
Species targeted: Pigs; Poultry; Dairy; Beef; Sheep;
Age: Not stated;
Summary:
Drysist is a thermal disinfection system for animal transport vehicles that allows the programming of the minimum temperatures to be reached inside the truck and the effective disinfection time. The thermal disinfection is complemented by a disinfectant mist in the lower parts of the truck and by a manual disinfection of the truck cabin
Where to find the original material: http://oppgroup.com/productos-y-servicios/drysist/;
Country: ES

423 – Comparing Farm Biosecurity and Antimicrobial Use in H (Research paper – Caekebeke – 2020)

 

 

423 Research paper – Caekebeke – 2020 – Comparing Farm Biosecurity and Antimicrobial Use in H

423 Research paper
Comparing Farm Biosecurity and Antimicrobial Use in High-Antimicrobial-Consuming Broiler and Pig Farms in the Belgian–Dutch Border Region by Caekebeke, N., Jonquiere, F. J., Ringenier, M., Tobias, T. J., Postma, M., van den Hoogen, A., Houben, M. A. M., Velkers, F. C., Sleeckx, N., 2020 Veterinary Science 7: 11-Jan
In Significant Impact Groups: Biosecurity \Internal biosecurity; Animal
Species targeted: Pigs; Poultry;
Age: Young;
Summary:
On average, more biosecurity measures were implemented on Dutch farms, compared to Belgian farms in both animal species. In addition, more opportunities were found to increase the level of internal biosecurity compared to external biosecurity in both countries. There was a substantial difference in AMU between farms from both countries. In both poultry and pig production, the majority of antimicrobials used were extended-spectrum penicillins. Compared to Belgian farms, Dutch poultry farms used high amounts of (fluoro)quinolones (1 and 15% of total AMU, respectively). None of the production parameters between broiler farms differed significantly, but in pig production, weaning age in Belgian farms (median: 23) was lower than in Dutch farms (median: 27). These results indicate considerable room for improvement in both countries and animal species. Farm-specific preventive strategies can contribute to lowering the risk for animal disease and hence the need for AMU.
423 Research paper – Caekebeke – 2020 – Comparing Farm Biosecurity and Antimicrobial Use in H
Where to find the original material: https://www.researchgate.net/publication/345942229_Comparing_Farm_Biosecurity_and_Antimicrobial_Use_in_High-Antimicrobial-Consuming_Broiler_and_Pig_Farms_in_the_Belgian-Dutch_Border_Region; Frontiers in Veterinary Science
Country: Belgium; Netherlands

420 – The use of inulin in poultry feeding – A review (Research paper – Bucław – 2016)

 

 

420 Research paper – Bucław – 2016 – The use of inulin in poultry feeding_ a review

420 Research paper
The use of inulin in poultry feeding: a review. by Bucław M. 2016 Animal Physiology and Animal Nutrition 100: 1015-1022
In Significant Impact Groups: Feed / gut health \ Feed additives and supplements
Species targeted: Poultry;
Age: Adult;
Summary:
Since the European Union enforced the ban on antibiotic growth promoters in 2006, the research has been focused on natural feed additives which would have a proven positive impact on both production and animal health. Inulin is both the most commonly used and the most effective probiotic additive. The mechanism of inulin interactions with the avian body is complex, multidirectional and not fully understood. Despite a number of unresolved issues, many authors have demonstrated the positive impact of inulin on the host organism. The reports on inulin effects on the body and performance of poultry are often contradictory, as the effectiveness of this prebiotic is strongly dependent on the type and dose used, and the duration of its administration.
420 Research paper – Bucław – 2016 – The use of inulin in poultry feeding_ a review
Where to find the original material: https://onlinelibrary.wiley.com/doi/full/10.1111/jpn.12484; https://doi.org/10.1111/jpn.12484
Country: PL

419 – Effects of a protected inclusion of organic acids and essential oils as antibiotic growth promoter alternative on growth performance, intestinal morphology and gut microflora in broilers(Research paper – Yanli – 2017)

 

 

419 Research paper – Yanli – 2017 – Effects of a protected inclusion of organic acids and essential oils as antibiotic growth promoter alternative on growth performance in

419 Research paper
Effects of a protected inclusion of organic acids and essential oils as antibiotic growth promoter alternative on growth performance, intestinal morphology and gut microflora in broilers by Yanli Liu, Xin Yang, Hongliang Xin , Si Chen, Chengbo Yang, Yulan Duan, Xiaojun Yang, 2017 Animal Science Journal 88: 1414-1424.
In Significant Impact Groups: Feed / gut health \ Feed additives and supplements
Species targeted: Poultry;
Age: Adult; Young;
Summary:
This experiment was conducted to investigate the effects of protected essential oils and organic acids mixture on poultry feeding. Product supplementation improved spleen index, villus height and crypt depth of the jejunum at 42 days when compared with the control (P < 0.05). In addition, secretory immunoglobulin A level of ileal mucosa and trypsin and chymotrypsin activities of intestinal tract were higher in the P treatment. Bacterial sequence analysis of the intestinal tract revealed that protected essential oils and organic acids mixture supplementation changed gut microflora mainly in Lactobacillus. These data suggested that dietary mixture of organic acids and essential oils addition could be used in the poultry industry as an antibiotic growth promoter alternative.
419 Research paper – Yanli – 2017 – Effects of a protected inclusion of organic acids and essential oils as antibiotic growth promoter alternative on growth performance in
Where to find the original material: https://onlinelibrary.wiley.com/doi/abs/10.1111/asj.12782; https://doi.org/10.1111/asj.12782
Country: CN

418 – Biochemical proximates of pumpkin Cucurbitaeae spp and their beneficial effects on the general well‐being of poultry species (Research paper – Achilonu – 2017)

 

 

418 Research paper – Achilonu – 2017 – Biochemical proximates of pumpkin Cucurbitaeae spp and their beneficial effects on the general well‐being of poultry species

418 Research paper
Biochemical proximates of pumpkin (Cucurbitaeae spp.) and their beneficial effects on the general well‐being of poultry species by M. C. Achilonu I. C. Nwafor D. O. Umesiobi M. M. Sedibe. 2017 Animal Physiology and Animal Nutrition 102: 16-May
In Significant Impact Groups: Feed / gut health \ Feed additives and supplements
Species targeted: Poultry;
Age: Adult;
Summary:
There is a growing need to increase productivity in poultry. The growth‐promoting antibiotics are administered to poultry to improve the general performance of the chicken. However, the use of the xenobiotic drugs in food‐producing animals has been a concern and a sensitive issue of debate for several decades in the EU and many other regional blocks of the world. Pumpkin seed extract is reported to be useful for immunomodulation, reproductive health, therapeutics over a wide range of disease conditions and stimulates metabolism of accumulated fats. Studies have also shown that pumpkin seeds are a valuable source of protein and fat. Their complexity and extent of bioactivity offers sustainable prospects for natural control of pathogenic/parasitic organisms, stimulate nutrition or enhance resistance to disease infections, and reduce abdominal fat and serum levels of harmful lipids, while increasing serum levels of beneficial lipids.
418 Research paper – Achilonu – 2017 – Biochemical proximates of pumpkin Cucurbitaeae spp and their beneficial effects on the general well‐being of poultry species
Where to find the original material: https://onlinelibrary.wiley.com/doi/full/10.1111/jpn.12654; https://doi.org/10.1111/jpn.12654
Country: ZA

411 – Passive immunisation an old idea revisited – Basic principles and application to modern animal production systems (Research paper – Hedegaard – 2016)

 

 

411 Research paper – Hedegaard – 2016 – Passive immunisation an old idea revisited_ Basic principles and application to modern animal production systems

411 Research paper
Passive immunisation, an old idea revisited: Basic principles and application to modern animal production systems by Hedegaard C.J. and P.M.H. Heegaard
2016 Veterinary Immunology and Immunopathology Volume 174: 50-63
In Significant Impact Groups: Prudent use AB \ Veterinarian
Species targeted: Pigs; Poultry; Dairy; Beef; Sheep;
Age: Adult;
Summary:
Immunisation by administration of antibodies (immunoglobulins) has been known for more than one hundred years as a very efficient means of obtaining immediate, short-lived protection against infection and/or against the disease-causing effects of toxins from microbial pathogens and from other sources. This review highlights a number of examples on the use of passive immunisation for the control of infectious disease in the modern production of a range of animals, including pigs, cattle, sheep, goat, poultry and fish. It is concluded that provided highly efficient, relatively low-price immunoglobulin products are available, passive immunisation has a clear role in the modern animal production sector as a means of controlling infectious diseases, importantly with a very low risk of causing development of bacterial resistance, thus constituting a real and widely applicable alternative to antibiotics.
411 Research paper – Hedegaard – 2016 – Passive immunisation an old idea revisited_ Basic principles and application to modern animal production systems

Where to find the original material: https://www.sciencedirect.com/science/article/abs/pii/S0165242716300642?via%3Dihub; https://doi.org/10.1016/j.vetimm.2016.04.007
Country: Denmark

410 – Finding alternatives to antibiotics (Research paper – Allen – 2014)

 

 

410 Research paper – Allen – 2014 – Finding alternatives to antibiotics

410 Research paper
Finding alternatives to antibiotics by Allen, H.K., Trachsel, J., Looft, T. and T.A. Casey 2014 Annals of the New York Academy of Sciences 1323: 91-100
In Significant Impact Groups: Prudent use AB \ Veterinarian
Species targeted: Pigs; Poultry; Dairy; Beef; Sheep;
Age: Adult;
Summary:
The spread of antibiotic-resistant pathogens requires new treatments. As the rate of development of new antibiotics has severely declined, alternatives to antibiotics must be considered in both animal agriculture and human medicine. Products for disease prevention are different from those for disease treatment, and examples of both are discussed here. For example, modulating the gut microbial community, either through feed additives or fecal transplantation, could be a promising way to prevent certain diseases; for disease treatment, non-antibiotic approaches include phage therapy, phage lysins, bacteriocins, and predatory bacteria. Interestingly, several of these methods augment antibiotic efficacy by improving bacterial killing and decreasing antibiotic resistance selection. Because bacteria can ultimately evolve resistance to almost any therapeutic agent, it is important to continue to use both antibiotics and their alternatives judiciously.
410 Research paper – Allen – 2014 – Finding alternatives to antibiotics
Where to find the original material: https://pubmed.ncbi.nlm.nih.gov/24953233/; DOI: 10.1111/nyas.12468
Country: USA

409 – Antibiotic use and resistance in animals – Belgian initiatives (Research paper – Daeseleire – 2016)

 

 

409 Research paper – Daeseleire – 2016 – Antibiotic use and resistance in animals_ Belgian initiatives

409 Research paper
Antibiotic use and resistance in animals: Belgian initiatives by Daeseleire, E. De Graef, E., Rasschaert, G., De Mulder, T., Van den Meersche, T., Van Coillie, E., Jeroen Dewulf, J. and M. Heyndrickx 2016 Drug Testing and Analysis 8: 549–555
In Significant Impact Groups: Prudent use AB \ Veterinarian
Species targeted: Pigs; Poultry; Dairy; Beef; Sheep;
Age: Not stated;
Summary:
The widespread use of antibiotics in animals is causing concerns about the growing risk for development and the spread of antibiotic-resistant bacteria. Antibiotic consumption is higher in animals than in humans as reported in a joint publication of EFSA (European Food Safety Agency), ECDC (European Centre for Disease Prevention and Control), and EMA (European Medicines Agency) using data from 2011 and 2012. Both in humans and animals, positive associations between the consumption of antibiotics and resistant bacteria are observed. Responsible use of antibiotics in humans and animals should therefore be promoted. In this paper some general aspects of antibiotic resistance such as microbiological versus clinical resistance, intrinsic versus acquired resistance, resistance mechanisms, and transfer of resistance are briefly introduced.
409 Research paper – Daeseleire – 2016 – Antibiotic use and resistance in animals_ Belgian initiatives
Where to find the original material: https://onlinelibrary.wiley.com/doi/full/10.1002/dta.2010; https://doi.org/10.1002/dta.2010
Country: Belgium

405 – Code of Good Practice Regarding the Responsible Prescribing and Use of Antibiotics in Farm Animals by Irish Farmers IFA and Veterinary Practitioners (Tools & Checklists)

 

 

405 ToolsChecklists – Code of Good Practice Regarding the Responsible Prescribing and Use of Antibiotics in Farm Animals by Irish Farmers IFA and Veterinary Practitioners

405 Tools & Checklists
Code of Good Practice Regarding the Responsible Prescribing and Use of Antibiotics in Farm Animals by Irish Farmers (IFA) and Veterinary Practitioners (Veterinary Ireland)
In Significant Impact Groups:
Species targeted: Pigs; Poultry; Dairy; Beef; Sheep;
Age:
Summary:
Responsible use of antibiotics means aiming to use “as little as possible and as much as necessary”. A „Code of Good Practice Regarding the Responsible Prescribing and Use of Antibiotics in Farm Animals‟ was launched in November 2018. These Guidelines have been developed by Irish Farmers and Veterinary Practitioners to guide good practice in the responsible prescribing and use of antibiotics in farm animals, in response to the global societal challenge of antimicrobial resistance (AMR). The development of and spread of AMR is a challenge for public and animal health into the future. Farmers have a key role to play by working to keep antibiotics effective for future generations through improving animal health and reducing levels of use on farms.
Where to find the original material: https://www.gov.ie/pdf/?file=https://assets.gov.ie/94001/550a156d-4ccb-40fe-97c1-ecb860263a0b.pdf#page=1
Country: Ireland

403 – Selective breeding for high natural antibody level increases resistance to avian pathogenic Escherichia coli APEC in chickens (Research paper – Berghof – 2019)

 

 

403 Research paper – Berghof – 2019 – Selective breeding for high natural antibody level increases resistance to avian pathogenic Escherichia coli APEC in chickens

Selective breeding for high natural antibody level increases resistance to avian pathogenic Escherichia coli (APEC) in chickens by Berghof, T.V.L., Matthijs, M.G.R., Arts, J.A.J., Bovenhuis H., Dwars, R.M., J.J. van der Poel, Visker, M.H.P.W., and H.K. Parmentier 2019 Developmental and Comparative Immunology 93: 45-57
In Significant Impact Groups: Breeding for disease resistance or robustness
Species targeted: Poultry;
Age: Not stated;
Summary:
Chickens bred for higher levels of ‘natural antibodies’ have a better Escherichia coli disease resistance, researcher of Wageningen University & Research and Utrecht University report. Breeding chickens for an improved general disease resistance is thereby a step closer. This can ultimately result in reduced antibiotics use and improved welfare for animals. Animals have so-called ‘natural antibodies’, which are a part of the immune system. Natural antibodies recognize pathogens in healthy animals, without (a previous) exposure of the animal to this pathogen. The antibodies slow down and prevent spreading of the pathogen from in the body. In addition, they warn and activate other parts of the immune system.

Where to find the original material: https://www.sciencedirect.com/science/article/pii/S0145305X18304816; https://doi.org/10.1016/j.dci.2018.12.007
Country: NL