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Antimicrobial resistance (AMR)
The position paper of the European Association of Hospital Pharmacists (EAHP) highlights the importance of the prudent use of antimicrobial drugs through antibiotic stewardship to ensure efficient therapy for patients with life-threatening infections. EAHP calls on national governments and health system managers to utilise the specialised background and knowledge of the hospital pharmacist in multi-professional antibiotic stewardship teams. In addition, the paper recommends the universal application of infection prevention and control measures among healthcare professionals. Due to the lack of funding, EAHP urges increased investment to support the development of innovative proposals and the encouragement of practice-based research projects to investigate new fields of infectious disease control such as immunotherapy and to optimise the cost-effectiveness of systems for surveillance on antibiotic use and resistance. In relation to the 'One Health approach' of the European Commission, EAHP strongly supports regulatory oversight and proper implementation of measures in the veterinary and agriculture sectors at European, national and local level.
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Antimicrobial resistance in equine reproduction
Bacteria develop resistance to antibiotics following low-level "background" exposure to antimicrobial agents as well as from exposure at therapeutic levels during treatment for bacterial infections. In this review, we look specifically at antimicrobial resistance (AMR) in the equine reproductive tract and its possible origin, focusing particularly on antibiotics in semen extenders used in preparing semen doses for artificial insemination. Our review of the literature indicated that AMR in the equine uterus and vagina were reported worldwide in the last 20 years, in locations as diverse as Europe, India, and the United States. Bacteria colonizing the mucosa of the reproductive tract are transferred to semen during collection; further contamination of the semen may occur during processing, despite strict attention to hygiene at critical control points. These bacteria compete with spermatozoa for nutrients in the semen extender, producing metabolic byproducts and toxins that have a detrimental effect on sperm quality. Potential pathogens such as Klebsiella pneumoniae, Escherichia coli, and Pseudomonas aeruginosa may occasionally cause fertility issues in inseminated mares. Antibiotics are added during semen processing, according to legislation, to impede the growth of these microorganisms but may have a detrimental effect on sperm quality, depending on the antimicrobial agent and concentration used. However, this addition of antibiotics is counter to current recommendations on the prudent use of antibiotics, which recommend that antibiotics should be used only for therapeutic purposes and after establishing bacterial sensitivity. There is some evidence of resistance among bacteria found in semen samples. Potential alternatives to the addition of antibiotics are considered, especially physical removal separation of spermatozoa from bacteria. Suggestions for further research with colloid centrifugation are provided.
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Antimicrobial Resistance in Equine Reproduction
Bacteria develop resistance to antibiotics following low-level "background" exposure to antimicrobial agents as well as from exposure at therapeutic levels during treatment for bacterial infections. In this review, we look specifically at antimicrobial resistance (AMR) in the equine reproductive tract and its possible origin, focusing particularly on antibiotics in semen extenders used in preparing semen doses for artificial insemination. Our review of the literature indicated that AMR in the equine uterus and vagina were reported worldwide in the last 20 years, in locations as diverse as Europe, India, and the United States. Bacteria colonizing the mucosa of the reproductive tract are transferred to semen during collection ; further contamination of the semen may occur during processing, despite strict attention to hygiene at critical control points. These bacteria compete with spermatozoa for nutrients in the semen extender, producing metabolic byproducts and toxins that have a detrimental effect on sperm quality. Potential pathogens such as Klebsiella pneumoniae, Escherichia coli, and Pseudomonas aeruginosa may occasionally cause fertility issues in inseminated mares. Antibiotics are added during semen processing, according to legislation, to impede the growth of these microorganisms but may have a detrimental effect on sperm quality, depending on the antimicrobial agent and concentration used. However, this addition of antibiotics is counter to current recommendations on the prudent use of antibiotics, which recommend that antibiotics should be used only for therapeutic purposes and after establishing bacterial sensitivity. There is some evidence of resistance among bacteria found in semen samples. Potential alternatives to the addition of antibiotics are considered, especially physical removal separation of spermatozoa from bacteria. Suggestions for further research with colloid centrifugation are provided.
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Antimicrobial Resistance in Equine Reproduction
Simple SummaryBacteria can develop resistance to antibiotics, resulting in the appearance of infections that are difficult or impossible to treat. This ability enables bacteria to survive in hostile environments and can result from exposure to even small amounts of antibiotic substances. Bacteria are present in the reproductive tract of the horse; they can develop resistance to antibiotics, because the animal has been treated for an infection, or due to insemination with a semen dose that contains antibiotics. Bacteria colonize the membrane lining the male reproductive tract and are transferred to the semen during collection. They can cause sperm quality to deteriorate during storage or may cause an infection in the mare. Therefore, antibiotics are added to the semen dose, according to legislation. However, these antibiotics may contribute to the development of resistance. Current recommendations are that antibiotics should only be used to treat bacterial infections and where the sensitivity of the bacterium to the antibiotic has first been established. Therefore, adding antibiotics to semen extenders does not fit these recommendations. In this review, we examine the effects of bacteria in semen and in the inseminated mare, and possible alternatives to their use.Bacteria develop resistance to antibiotics following low-level "background " exposure to antimicrobial agents as well as from exposure at therapeutic levels during treatment for bacterial infections. In this review, we look specifically at antimicrobial resistance (AMR) in the equine reproductive tract and its possible origin, focusing particularly on antibiotics in semen extenders used in preparing semen doses for artificial insemination. Our review of the literature indicated that AMR in the equine uterus and vagina were reported worldwide in the last 20 years, in locations as diverse as Europe, India, and the United States. Bacteria colonizing the mucosa of the reproductive tract are transferred to semen during collection; further contamination of the semen may occur during processing, despite strict attention to hygiene at critical control points. These bacteria compete with spermatozoa for nutrients in the semen extender, producing metabolic byproducts and toxins that have a detrimental effect on sperm quality. Potential pathogens such as Klebsiella pneumoniae, Escherichia coli, and Pseudomonas aeruginosa may occasionally cause fertility issues in inseminated mares. Antibiotics are added during semen processing, according to legislation, to impede the growth of these microorganisms but may have a detrimental effect on sperm quality, depending on the antimicrobial agent and concentration used. However, this addition of antibiotics is counter to current recommendations on the prudent use of antibiotics, which recommend that antibiotics should be used only for therapeutic purposes and after establishing bacterial sensitivity. There is some evidence of resistance among bacteria found in semen samples. Potential alternatives to the addition of antibiotics are considered, especially physical removal separation of spermatozoa from bacteria. Suggestions for further research with colloid centrifugation are provided.
BASE
Antimicrobial resistance in equine reproduction
Bacteria develop resistance to antibiotics following low-level "background" exposure to antimicrobial agents as well as from exposure at therapeutic levels during treatment for bacterial infections. In this review, we look specifically at antimicrobial resistance (AMR) in the equine reproductive tract and its possible origin, focusing particularly on antibiotics in semen extenders used in preparing semen doses for artificial insemination. Our review of the literature indicated that AMR in the equine uterus and vagina were reported worldwide in the last 20 years, in locations as diverse as Europe, India, and the United States. Bacteria colonizing the mucosa of the reproductive tract are transferred to semen during collection; further contamination of the semen may occur during processing, despite strict attention to hygiene at critical control points. These bacteria compete with spermatozoa for nutrients in the semen extender, producing metabolic byproducts and toxins that have a detrimental effect on sperm quality. Potential pathogens such as Klebsiella pneumoniae, Escherichia coli, and Pseudomonas aeruginosa may occasionally cause fertility issues in inseminated mares. Antibiotics are added during semen processing, according to legislation, to impede the growth of these microorganisms but may have a detrimental effect on sperm quality, depending on the antimicrobial agent and concentration used. However, this addition of antibiotics is counter to current recommendations on the prudent use of antibiotics, which recommend that antibiotics should be used only for therapeutic purposes and after establishing bacterial sensitivity. There is some evidence of resistance among bacteria found in semen samples. Potential alternatives to the addition of antibiotics are considered, especially physical removal separation of spermatozoa from bacteria. Suggestions for further research with colloid centrifugation are provided.
BASE
Antimicrobial Resistance in Equine Reproduction
SIMPLE SUMMARY: Bacteria can develop resistance to antibiotics, resulting in the appearance of infections that are difficult or impossible to treat. This ability enables bacteria to survive in hostile environments and can result from exposure to even small amounts of antibiotic substances. Bacteria are present in the reproductive tract of the horse; they can develop resistance to antibiotics, because the animal has been treated for an infection, or due to insemination with a semen dose that contains antibiotics. Bacteria colonize the membrane lining the male reproductive tract and are transferred to the semen during collection. They can cause sperm quality to deteriorate during storage or may cause an infection in the mare. Therefore, antibiotics are added to the semen dose, according to legislation. However, these antibiotics may contribute to the development of resistance. Current recommendations are that antibiotics should only be used to treat bacterial infections and where the sensitivity of the bacterium to the antibiotic has first been established. Therefore, adding antibiotics to semen extenders does not fit these recommendations. In this review, we examine the effects of bacteria in semen and in the inseminated mare, and possible alternatives to their use. ABSTRACT: Bacteria develop resistance to antibiotics following low-level "background" exposure to antimicrobial agents as well as from exposure at therapeutic levels during treatment for bacterial infections. In this review, we look specifically at antimicrobial resistance (AMR) in the equine reproductive tract and its possible origin, focusing particularly on antibiotics in semen extenders used in preparing semen doses for artificial insemination. Our review of the literature indicated that AMR in the equine uterus and vagina were reported worldwide in the last 20 years, in locations as diverse as Europe, India, and the United States. Bacteria colonizing the mucosa of the reproductive tract are transferred to semen during collection; further ...
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The Macrosecuritization of Antimicrobial Resistance in China
In: Lo , C & Thomas , N 2020 , ' The Macrosecuritization of Antimicrobial Resistance in China ' , Journal of Global Security Studies , vol. 5 , no. 2 , pp. 361-378 . https://doi.org/10.1093/jogss/ogz038
The global spread of antimicrobial resistance (AMR) is an existential threat to humanity, one that has generated a macrosecuritizing response by states and international organizations. Since the turn of the century, China has been a source of numerous infectious disease outbreaks. It is also the origin of the MCR-1 gene that confers resistance to colistin, a 'last line' antibiotic deployed against multidrug resistant infections. With the largest population and its status as a major supplier of produce, evaluating Chinese responses to AMR is critical to understanding the efficacy of the global response. Combining both knowledge of Chinese politics and health security, this paper analyses how Chinese actors have responded to the threat in the public and animal health sectors as well as the domestic and international implications of these responses. Based on interviews with key Chinese and international officials, scientists, and public health specialists as well as farmers and consumers, we argue that the securitization of AMR in China is currently more concerned with domestic policy and resource competition than with addressing the existential health threat. Without a greater alignment of AMR strategies within China, macrosecuritizing efforts to address the threat globally cannot succeed.
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The Macrosecuritization of Antimicrobial Resistance in Asia
In: Lo , C & Thomas , N 2018 , ' The Macrosecuritization of Antimicrobial Resistance in Asia ' , Australian Journal of International Affairs , vol. 72 , no. 6 , pp. 567-583 . https://doi.org/10.1080/10357718.2018.1534939
This article has two objectives. Drawing on the framework provided by macrosecuritization, this article first explores global responses to AMR. Secondly, in shifting the analytical lens to Asia, the article then evaluates how successful this process has been in a regional context. Considering the two objectives, two inter-related arguments are proposed. First, even though AMR can be considered a quintessential and successful macrosecuritization case at the global level, within Asia the operationalisation of AMR strategies is limited by power and resource politics within the states. Second, the anthropocentric nature of health security is limited when it comes to address the threat posed by AMR. Overcoming this limitation requires a One Health approach. However, the successful articulation of this approach has proven challenging in Asia where middle-level actors pull away from the process in pursuit of other agendas. As a result, while macrosecuritization provides a useful tool for understanding how AMR and similar health threats are addressed, it is necessary to understand the local realities within which the process is embedded.
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Antimicrobial resistance surveillance in Europe 2016: annual report of the European Antimicrobial Resistance Surveillance Network (EARS-Net)
National institutions/organisations participating in EARS-Net - Portugal: National Institute of Health Doutor Ricardo Jorge (Caniça, M., Fernandes, P.A., Manageiro, V.) ; The results presented in this report are based on antimicrobial resistance data from invasive isolates reported to EARS-Net by 30 European Union (EU) and European Economic Area (EEA) countries in 2017 (data referring to 2016), and on trend analyses of data reported by the participating countries for the period 2013 to 2016. As in previous years, the antimicrobial resistance situation in Europe displays wide variations depending on the bacterial species, antimicrobial group and geographical region. For several bacterial species–antimicrobial group combinations, a north-to-south and a west-to-east gradient is evident in Europe. In general, lower resistance percentages were reported by countries in the north while higher percentages were reported in the south and east of Europe. These differences are most likely related to variations in antimicrobial use, infection prevention and control practices, and dissimilarities in diagnostic and healthcare utilisation patterns in the countries. ; info:eu-repo/semantics/publishedVersion
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ANTIMICROBIAL RESISTANCE- AN ONGOING CATASTROPHE IN INDIAN CONTEXT
The medical sector has seen numerous discoveries, innovation and research in last 100 years from penicillin to Remdesivir & HCQ, all have saved precious human life, but now several researches has highlighted the grim situation of antimicrobial resistance across the globe causing infectious disease at soaring rate. Unchecked and uncontrolled sale and usage of antimicrobials encompassing all sectors be it food production, hospitals etc. has further aggrieved the situation. This has further come to the limelight during ongoing COVID pandemic creating a fear in the mind, of the treatments getting failed owing to the cases of AMR which might bring a new catastrophe instead of curbing the menace of all types of pandemic. This article tries to answer and figure out the problems related to microbial resistance and the initiatives taken by Government of India to control it.
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Antimicrobial Resistance in Farm Animals in Brazil: An Update Overview
In animal husbandry, antimicrobial agents have been administered as supplements to increase production over the last 60 years. Large-scale animal production has increased the importance of antibiotic management because it may favor the evolution of antimicrobial resistance and select resistant strains. Brazil is a significant producer and exporter of animal-derived food. Although Brazil is still preparing a national surveillance plan, several changes in legislation and timely programs have been implemented. Thus, Brazilian data on antimicrobial resistance in bacteria associated with animals come from official programs and the scientific community. This review aims to update and discuss the available Brazilian data on this topic, emphasizing legal aspects, incidence, and genetics of the resistance reported by studies published since 2009, focusing on farm animals and derived foods with the most global public health impact. Studies are related to poultry, cattle, and pigs, and mainly concentrate on non-typhoid Salmonella, Escherichia coli, and Staphylococcus aureus. We also describe legal aspects of antimicrobial use in this context ; and the current occurrence of genetic elements associated with resistance to beta-lactams, colistin, and fluoroquinolones, among other antimicrobial agents. Data here presented may be useful to provide a better understanding of the Brazilian status on antimicrobial resistance related to farm animals and animal-derived food products.
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A Public health action plan to combat antimicrobial resistance
In: http://stacks.cdc.gov/view/cdc/12015/
In 2001, the Task Force developed an initial Action Plan, outlining specific issues, goals, and actions important for addressing the problem of AR. This document, entitled A Public Health Action Plan to Combat Antimicrobial Resistance, Part I: Domestic Issues, reflected a broad- based consensus of participating federal agencies, which was reached with individual input from state and local health agencies, universities, professional societies, pharmaceutical companies, healthcare delivery organizations, agricultural producers, consumer groups, and other members of the public. Continued collaboration with these partners has been vital to achieving successful implementation of the Action Plan. This revised Action Plan is based in part on individual input obtained at a consultants' meeting held in Atlanta, Georgia, in December 2007. Present at the public meeting were consultants with wide-ranging expertise in areas such as human and veterinary medicine, pharmaceutical and diagnostics manufacturing, animal husbandry, clinical microbiology, epidemiology, infectious diseases and infection control, and state and local public health officials. The Action Plan includes action items organized into four focus areas: Surveillance, Prevention and Control, Research, and Product Development. ; Executive summary -- Introduction and overview -- The Focus Areas -- Focus Area I: Surveillance -- Focus Area II: Prevention and Control -- Focus Area III: Research -- Focus Area IV: Product Development -- Acronyms and abbreviations ; Interagency Task Force on Antimicrobial Resistance ; co-chairs: Centers for Disease Control and Prevention, Food and Drug Administration. ; Title from caption (viewed on October 1, 2012). ; The Interagency Task Force on Antimicrobial Resistance (hereafter referred to as the Task Force) was created in 1999 to coordinate the activities of federal agencies in addressing antimicrobiala resistance (AR) in recognition of the increasing importance of AR as a public health threat. The Task Force is co-chaired by the Centers for Disease Control and Prevention (CDC), the Food and Drug Administration (FDA), and the National Institutes of Health (NIH) and also includes the Agency for Healthcare Research and Quality (AHRQ), the Centers for Medicare and Medicaid Services (CMS), the Department of Agriculture (USDA), the Department of Defense (DoD), the Department of Veterans Affairs (VA), the Environmental Protection Agency (EPA), the Health Resources and Services Administration (HRSA), and the Department of Health and Human Services Office of the Assistant Secretary for Preparedness and Response (HHS/ASPR). ; Mode of access: Internet; PDF reader (Acrobat .pdf file: 300 KB, 34 p.). ; Text (electronic publication)
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Surveillance for control of antimicrobial resistance
Antimicrobial resistance poses a growing threat to public health and the provision of health care. Its surveillance should provide up-to-date and relevant information to monitor the appropriateness of therapy guidelines, antibiotic formulary, antibiotic stewardship programmes, public health interventions, infection control policies, and antimicrobial development. In Europe, although the European Antimicrobial Resistance Surveillance Network provides annual reports on monitored resistant bacteria, national surveillance efforts are still fragmented and heterogeneous, and have substantial structural problems and issues with laboratory data. Most incidence and prevalence data cannot be linked with relevant epidemiological, clinical, or outcome data. Genetic typing, to establish whether trends of antimicrobial resistance are caused by spread of resistant strains or by transfer of resistance determinants among different strains and species, is not routinely done. Furthermore, laboratory-based surveillance using only clinical samples is not likely to be useful as an early warning system for emerging pathogens and resistance mechanisms. Insufficient coordination of surveillance systems of human antimicrobial resistance with animal surveillance systems is even more concerning. Because results from food surveillance are considered commercially sensitive, they are rarely released publicly by regulators. Inaccurate or incomplete surveillance data delay a translational approach to the threat of antimicrobial resistance and inhibit the identification of relevant target microorganisms and populations for research and the revitalisation of dormant drug-discovery programmes. High-quality, comprehensive, and real-time surveillance data are essential to reduce the burden of antimicrobial resistance. Improvement of national antimicrobial resistance surveillance systems and better alignment between human and veterinary surveillance systems in Europe must become a scientific and political priority, coordinated with international ...
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Antimicrobial resistance surveillance in Europe 2010. Annual Report of the European Antimicrobial Resistance Surveillance Network (EARS-Net)
National institutions/organisations participating in EARS-Net: Portugal - National Institute of Health Dr. Ricardo Jorge: Manuela Caniça; Vera Manageiro ; Antimicrobial resistance data reported to EARS-Net by 28 countries in 2010 and trend analyses including EARSS data from previous years, show that the Europewide increase of antimicrobial resistance observed in Escherichia coli during recent years is continuing unimpeded. The highest resistance proportions in E. coli were reported for aminopenicillins ranging up to 83 %. Despite the already high level of resistance the increase continues even in countries presenting resistance well above 50 %. The percentage of third-generation cephalosporin resistance reported among E. coli isolates has increased significantly over the last four years in half of the reporting countries, while a decreasing trend was observed in only one country. This resistance is directly linked to the high proportions (65–100 %) of ESBL-positives among cephalosporin-resistant E. coli isolates reported in 2010. A high frequency of multi-drug resistant Klebsiella pneumoniae was observed in southern, central and eastern Europe. In half of the reporting countries, the proportion of multiresistant K. pneumoniae isolates (combined resistance to third-generation cephalosporins, fluoroquinolones and aminoglycosides) was above 10 % and five countries show an increasing trend of carbapenem resistant K. pneumoniae. Carbapenems have been widely used in many countries due to the increasing rate of extended-spectrum beta-lactamase (ESBL) producing Enterobacteriaceae with a consequent impact on the emergence of carbapenemase production (VIM, KPC and NDM-1). Other trends in the occurrence of resistance reported to EARS-Net bring hope that national efforts on infection control and efforts targeted at containment of resistance may in some cases bring the development of resistance to a halt, or even reverse undesirable resistance trends, as exemplified by the development for meticillin-resistant Staphylococcus aureus (MRSA). Even though the proportion of MRSA among S. aureus is still above 25 % in eight out of 28 countries, the occurrence of MRSA is stabilising or decreasing in some countries and a sustained decrease has been observed in Austria, France, Ireland, Latvia, the UK and Cyprus. Furthermore, the United Kingdom has shown a consistent reduction of resistant proportions in K. pneumoniae for all antimicrobial classes under surveillance, and in a few countries (Germany, Greece, Italy and the UK) the efforts to control glycopeptide resistance in Enterococcus faecium seem to be successful and resulting in a continuous decrease of proportions of resistant isolates. Meanwhile, high-level aminoglycoside resistance in Enterococcus faecalis is stabilising in Europe at a level of 25–50%. For Streptococcus pneumoniae, non-susceptibility to penicillin remains generally stable in Europe and non-susceptibility to macrolides has declined in five countries while an increasing trend was observed in only one country. For Pseudomonas aeruginosa, high proportions of resistance to fluoroquinolones, carbapenems and combined resistance have been reported by many countries, especially in southern and eastern Europe. For several antimicrobial and pathogen combinations, e.g. fluoroquinolone resistance in E. coli, K. pneumoniae, P. aeruginosa and for MRSA, a north to south gradient is evident in Europe. In general, lower resistance proportions are reported in the north and higher proportions in the south of Europe. This is likely to be a reflection of differences in infection control practices, presence or absence of legislation regarding prescription of antimicrobial drugs. However, for K. pneumoniae, increasing trends of resistance to specific antimicrobial classes and of multiresistance have also been observed in northern European countries, like Denmark and Norway, which traditionally have a prudent approach to antimicrobial use. In addition to the regular trend analysis and situation overview, this 2010 EARS-Net report contains a focus chapter providing in-depth analysis for carbapenem resistant K. pneumoniae and P. aeruginosa. Results from susceptibility testing to carbapenems for these two pathogens reported since 2005, reveal a significant decrease of susceptibility to carbapenems in invasive K. pneumoniae over the period 2005–2010. Carbapenems are some of the few effective antimicrobials for the treatment of infections caused by bacteria that produce extended-spectrum beta-lactamases and thus resistance to carbapenems leaves very few therapeutic options available. Based on EARS-Net data, the antimicrobial resistance situation in Europe displays large variation depending on pathogen type, antimicrobial substance and geographical region. Besides evidence of stabilisation of the situation for some pathogens (e.g. MRSA) in a number of countries, the data show the unimpeded decline of antimicrobial susceptibility in other major pathogens (e.g. E. coli) and the alarming emergence of carbapenem resistance in K. pneumonia, leading to an unfortunate loss of antimicrobial treatment options.
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