Antibiotics In Agriculture Research Articles

Efficient photocatalytic degradation of tetracycline and its derivatives by green recyclable PAN/Bi2WO6/Cu2O nanofiber membrane

The use of tetracycline antibiotics in industry, healthcare, animal husbandry, agriculture, and aquaculture has resulted in excessive concentrations in a variety of aquatic environments. In this work, PAN/Bi2WO6/Cu2O nanofibrous membranes (PBC ENMs) with photocatalytic degradation performance were successfully prepared using electrostatic spinning technique, and the morphology of catalysts and PBC ENMs were characterised by SEM, BET and UV–Vis. The results demonstrated that the prepared nanofibrous membranes could achieve 97.05 % photocatalytic degradation of TC under visible light, and the degradation efficiencies of its derivatives, chlortetracycline (CTC) and oxytetracycline (OTC), reached 90.87 % and 85.12 %, respectively. Free radical trapping experiments and mechanistic analyses showed that·O2– is the main active factor in the degradation process. The highest degradation rate of 97.05 % was achieved at initial pH = 7.2.PBC ENMs adsorbed above 87.5 % after six cycles of the experiment. The highest degradation rate of 97.05 % was achieved at initial pH = 7.2 PBC ENMs adsorbed above 87.5 % after six cycles of the experiment. Based on the above advantages, the preparation process of PBC ENMs is simple, low-cost and has good catalytic effect, which provides a simple and efficient treatment means for the treatment of TC wastewater and has a broad application prospect.

Alternatives of Antibiotics in Animal Agriculture: One Health Perspective

Due to the increasing trend of antimicrobial resistance bacteria and the increase of antimicrobial resistance genes, there is an urgent need to develop alternatives to antibiotics. This review evaluates the advances and perceptions of alternatives to antibiotics. The mode of action, application and perspective of alternatives such as clay minerals, probiotics, prebiotics, inhibitors such as quorum sensing inhibitors, biofilms inhibitors, bacterial virulence inhibitors, antimicrobial peptides, phytogenic compounds like organic acids, essential oil and herbs, bacteriophages, nanoparticles, vaccines, fecal microbiota transplant, immunity modulating stimulants and bacteriocins are discussed in this review. If used with proper strategies, these alternatives can replace antibiotics in livestock. These alternatives not only better cope with antimicrobial resistance but also can help in efficient animal growth, production and disease control. However, till now, none of the alternatives has been proven to efficiently replace antibiotics on a large scale, though, they appeared to be a partial replacement to antibiotics. These natural alternatives are promising to improve the overall health of the environment, animals and humans. Lastly, the idea of one health was adopted in recognition of the fact that animals and people share many infectious diseases and are connected in addition to existing in the same environment. Using one health concept, the World Health Organization (WHO), Food and Agriculture Organization (FAO), and World Organization for Animal Health (OIE) developed several action plans to tackle antibiotic resistance.

Use of Antibiotics in Animal Agriculture: Implications for Pediatrics: Technical Report.

Antimicrobial resistance is a global public health threat. Antimicrobial-resistant infections are on the rise and are associated with increased morbidity, mortality, and health care costs. Infants and children are affected by transmission of antimicrobial-resistant zoonotic pathogens through the food supply, direct contact with animals, environmental pathways, and contact with infected or colonized humans. Although the judicious use of antimicrobial agents is necessary for maintaining the health and welfare of humans and animals, it must be recognized that all use of antimicrobial agents exerts selective pressure that increases the risk of development of resistance. This report describes historical and recent use of antibiotics in animal agriculture, reviews the mechanisms of how such use contributes to development of resistance and can adversely affect child health, and discusses US initiatives to curb unnecessary use of antimicrobial agents in agriculture.

Escherichia coli from healthy farm animals: Antimicrobial resistance, resistance genes andmobile genetic elements.

The use of antibiotics in agriculture and subsequent environmental pollution are associated with the emergence and spread of multidrug-resistant (MDR) bacteria including Escherichia coli. The aim of this study was to detect antimicrobial resistance, resistance genes and mobile genetic elements of 72 E. coli strains isolated from faeces of healthy farm animals. Disk diffusion test showed resistance to ampicillin (59.7%), tetracycline (48.6%), chloramphenicol (16.7%), cefoperazone and ceftriaxone (13.9%), cefepime and aztreonam (12.5%), norfloxacin and ciprofloxacin (8.3%), levofloxacin (6.9%), gentamicin and amikacin (2.8%) among the studied strains. Antibiotic resistance genes (ARGs) were detected by polymerase chain reaction: the prevalence of blaTEM was the highest (59.7% of all strains), followed by tetA (30.6%), blaCTX-M (11.1%), catA1 (9.7%), less than 5% strains contained blaSHV, cmlA, floR, qnrB, qnrS, tetM. 26.4% of E. coli strains had a MDR phenotype. MDR E. coli more often contained class 1 integrons, bacteriophages, conjugative F-like plasmids, than non-MDR strains. ARGs were successfully transferred from faecalE. colistrains into theE. coliNissle 1917 N4i strain by conjugation. Conjugation frequencies varied from (1.0 ± 0.1) * 10-5 to (7.9 ± 2.6) * 10-4 per recipient. Monitoring mobile genetic elements of E. coli for antibiotic resistance is important for farm animal health, as well as for public health and food safety.

Dual Antibiotic Approach: Synthesis and Antibacterial Activity of Antibiotic-Antimicrobial Peptide Conjugates.

In recent years, bacterial resistance to conventional antibiotics has become a major concern in the medical field. The global misuse of antibiotics in clinics, personal use, and agriculture has accelerated this resistance, making infections increasingly difficult to treat and rendering new antibiotics ineffective more quickly. Finding new antibiotics is challenging due to the complexity of bacterial mechanisms, high costs and low financial incentives for the development of new molecular scaffolds, and stringent regulatory requirements. Additionally, innovation has slowed, with many new antibiotics being modifications of existing drugs rather than entirely new classes. Antimicrobial peptides (AMPs) are a valid alternative to small-molecule antibiotics offering several advantages, including broad-spectrum activity and a lower likelihood of inducing resistance due to their multifaceted mechanisms of action. However, AMPs face challenges such as stability issues in physiological conditions, potential toxicity to human cells, high production costs, and difficulties in large-scale manufacturing. A reliable strategy to overcome the drawbacks associated with the use of small-molecule antibiotics and AMPs is combination therapy, namely the simultaneous co-administration of two or more antibiotics or the synthesis of covalently linked conjugates. This review aims to provide a comprehensive overview of the literature on the development of antibiotic-AMP conjugates, with a particular emphasis on critically analyzing the design and synthetic strategies employed in their creation. In addition to the synthesis, the review will also explore the reported antibacterial activity of these conjugates and, where available, examine any data concerning their cytotoxicity.

Antibiotic resistome dynamics in agricultural river systems: Elucidating transmission mechanisms and associated risk to water security

Usage of antibiotics in agriculture has increased dramatically recently, significantly raising the influx of antibiotic resistance genes (ARGs) into river systems through organic manure runoff, seriously threatening water security. However, the dynamics, transmission mechanisms, and potential water security risk of ARGs, as well as their response to land use spatial scale and seasonal variations in agricultural river systems remain unclear. To address these challenges, this work employed metagenomic technique to systematically evaluate the pollution and dissemination of ARGs in overlying water and sediment within a typical agricultural catchment in China. The results demonstrated significant differences between overlying water and sediment ARGs. Overlying water dominated by multidrug ARGs exhibited higher diversity, whereas sediment predominantly containing sulfonamide ARGs had higher abundance. The dynamics of ARGs in overlying water were more responsive to seasonal variations compared to sediment due to greater changes in hydrodynamics and nutrient conditions. The profiles of ARGs in overlying water were largely regulated by microbiota, whereas mobile genetic elements (MGEs) were the main forces driving the dissemination of ARGs in sediment. The variation in dissemination mechanisms led to different resistance risks, with sediment presenting a higher resistance risk than overlying water. Furthermore, Mantel test was applied to discover the impact of land use spatial scale and composition on the transmission of ARGs in river systems. The findings showed that cultivated land within 5 km of the riverbank was the key influencing factor. Cultivated land exacerbated ARGs spread by increasing MGEs abundance and nutrient concentrations, resulting in the abundance of ARGs in high-cultivated sites being twice that in low-cultivated sites, and raising the regional water security risk, with a more pronounced effect in sediment. These findings contribute to a better understanding of ARGs dissemination in agricultural watersheds, providing a basis for implementing effective resistance control measures and ensuring water security.

Electrochemical Detection of Ornidazole Using a WS2 /CNFs Sensor

In recent decades, pharmaceutical compounds, notably antibiotics, have played a significant role in preventing infections and illnesses that affect both animals and humans. However, the utilization of antibiotics in the pharmaceutical industry, farming and other applications has led to environmental concerns 1. Nitroimidazole, an oral drug, is commonly used as an antibacterial agent. An example of a drug in nitroimidazole family is ornidazole (ORZ, (1-(3-chloro-2-hydroxy) propyl-2-methyl- 5-nitroimidazole)), and it is used in treating and preventing various infections, including genitourinary tract, intestinal and protozoal infections. Ornidazole has a heterocyclic structure comprising of an imidazole-based nucleus with a nitro group (NO2)1 and have become a well-established group of antiprotozoan and antibacterial agents. Beyond immediate therapeutic benefits, ornidazole could persist in the environment, posing long-term risks such as potential mutagenic and carcinogenic effects. Moreover, excessive antibiotics such as antibiotics such as ORZ in the environment can lead to the development of antibiotic-resistant pathogens. The widespread use of antibiotics in medical treatment and agriculture contributes to water contamination as these substances find their way into water bodies through various pathways. There is escalating concern over pharmaceutical contaminants therefore highlighting the importance of monitoring and regulating antibiotic levels in the environment. This requires significant research and electrochemical methods portray possibilities for drug detection due to their advantages of high sensitivity, low cost, simplicity and selectivity.Recent developments have brought to the spotlight, two dimensional materials as promising candidates for environmental sensing, due to their unique characteristics and wide-ranging applications. In particular, Transition-metal dichalcogenides (TMDs), comprising of MX2 , with M a transition metal atom e.g. Mo, W etc. and X, a chalcogen atom S, Se or Te 2, have garnered attention for their exceptional features. These materials consist of M atoms closely sandwiched between two layers of X atoms, linked by strong in-plane covalent bonds, and further bonded by weak van der Waals forces between the layers. Among the TMDs, tungsten disulfide (WS2) exhibits exceptional properties, including high electronic conductivity, good chemical stability, large capacitance and surface area. Those inherent properties of WS2, make it a suitable material for various applications, especially in environmental sensing 3.This study explores the detection of ornidazole using a composite material of WS2 with functionalized carbon nanofibers (CNFs). Carbon nanofibers (CNFs) are featured for their equally outstanding electrical and mechanical properties that make them promising candidates for sensor applications. CNFs also provide a unique platform for developing sensitive and selective sensors. Their versatility allows for functionalization, enhancing chemical properties and enabling tailored interactions with target analytes. The study emphasizes how CNFs, with their notable properties, complement WS2 in the creation of innovative sensor structures to create composites with improved sensing capabilities for drug compounds. In this study, the WS2/CNF nanocomposite was synthesized using hydrothermal synthesis and subsequently dispersed in ethanol and water, and then drop casted on a glassy carbon electrode. Prior to synthesis, the CNFs were functionalized using a low cost, environmental friendly method, thus enhancing their chemical properties. Herein, the resulting WS2/CNF composite demonstrates its efficacy in detecting ornidazole, and shows excellent potential for the development of electrochemical sensors. Overall, the work here aims to highlight the ongoing progress of electrochemical sensor technology, emphasizing its crucial role in addressing the growing challenges associated with drug contamination in the environment.References(1) Ettadili, F. E.; Azriouil, M.; Matrouf, M.; Tahiri Alaoui, O.; Laghrib, F.; Farahi, A.; Bakasse, M.; Saqrane, S.; Lahrich, S.; El Mhammedi, M. A. Materials Framework Based Bio/Sensors for the Detection of Ornidazole and Metronidazole Antibiotics in Environment and Foodstuffs. Inorganic Chemistry Communications. 2022. https://doi.org/10.1016/j.inoche.2022.109416.(2) Manzeli, S.; Ovchinnikov, D.; Pasquier, D.; Yazyev, O. V.; Kis, A. 2D Transition Metal Dichalcogenides. Nature Reviews Materials. 2017. https://doi.org/10.1038/natrevmats.2017.33.(3) Santos, B. G.; Gonçalves, J. M.; Rocha, D. P.; Higino, G. S.; Yadav, T. P.; Pedrotti, J. J.; Ajayan, P. M.; Angnes, L. Electrochemical Sensor for Isoniazid Detection by Using a WS2/CNTs Nanocomposite. Sensors and Actuators Reports 2022, 4. https://doi.org/10.1016/j.snr.2021.100073.

A WS2/CNF Nanocomposite for Electrochemical Sensing Applications

Successful environmental monitoring is crucial to safeguarding humans and the natural world. The presence of antibiotics in aquatic environments has become a pressing global concern, posing potential risks to both ecosystems and public health. Extensive use of antibiotics in medical treatment and agriculture has led to their release into water bodies through various pathways, contributing to water contamination. Detecting and monitoring antibiotic residues in water is crucial to understanding the extent of contamination and mitigating its adverse effects. Furthermore, the escalating concern over pharmaceutical contaminants in the environment has prompted significant research efforts towards the development of advanced sensing technologies.Recently, 2D materials have emerged as promising candidates for environmental sensing, due to their unique properties and potential applications. Transition-metal dichalcogenides or TMDs, are two-dimensional (2D) materials comprising of MX2, with M a transition metal atom e.g. Mo, W etc. and X, a chalcogen atom S, Se or Te1. The M atoms are sandwiched between two layers of X atoms with robust in-plane covalent bonds, and weak van der Waals forces between the planes. Among the TMDs, tungsten disulfide (WS2) exhibits outstanding properties, such as high electronic conductivity, large capacitance, high surface area, and chemical stability. This study explores the promising characteristics of WS2 and its synergistic potential of combining it with carbon materials to develop hybrid structures2. Carbon nanofibers (CNFs) exhibit exceptional properties that make them promising candidates for sensor applications. With their large surface area, and excellent electrical conductivity, CNFs offer a unique platform for the development of sensitive and selective sensors. In addition, CNFs versatility allows for functionalization, enhancing their chemical properties and facilitating tailored interactions with target analytes. Furthermore, owing to these notable properties, carbon nanofibers complement WS2 in the development of innovative sensor structures. Here, WS2 was combined with functionalized carbon nanofibers, to create a composite structure that was employed to detect ornidazole (ORZ), an antibiotic drug.Ornidazole, belonging to the nitroimidazole class of antibiotics, is commonly employed in the treatment of various genitourinary tract and protozoal infections3. Beyond the immediate therapeutic benefits, antibiotics such as ornidazole can persist in the environment, posing long-term risks. Moreover, excess ORZ in the environment has potential mutagenic & carcinogenic effects, and can lead to the development of antibiotic resistant pathogens. In this study, the WS2 /CNF nanocomposite was synthesized using hydrothermal synthesis and subsequently dispersed in ethanol and water, and then drop casted on a glassy carbon electrode. Prior to synthesis, the CNFs were functionalized using a low cost, environmental friendly method, thus enhancing their chemical properties. Herein, the resulting WS2/CNF composite demonstrates its efficacy in detecting ornidazole (ORZ), and shows excellent potential for the development of electrochemical sensors. Overall, the work here aims to underscore the continuous development of electrochemical sensor technology, emphasizing its pivotal role in addressing the growing challenges associated with drug contamination in the environment.(1) Manzeli, S.; Ovchinnikov, D.; Pasquier, D.; Yazyev, O. V.; Kis, A. 2D Transition Metal Dichalcogenides. Nature Reviews Materials. 2017. https://doi.org/10.1038/natrevmats.2017.33.(2) Santos, B. G.; Gonçalves, J. M.; Rocha, D. P.; Higino, G. S.; Yadav, T. P.; Pedrotti, J. J.; Ajayan, P. M.; Angnes, L. Electrochemical Sensor for Isoniazid Detection by Using a WS2/CNTs Nanocomposite. Sensors and Actuators Reports 2022, 4. https://doi.org/10.1016/j.snr.2021.100073.(3) Koventhan, C.; Vinothkumar, V.; Chen, S. M. Development of an Electrochemical Sensor Based on a Cobalt Oxide/Tin Oxide Composite for Determination of Antibiotic Drug Ornidazole. New Journal of Chemistry 2021, 45 (28). https://doi.org/10.1039/d1nj01345a

Isolation and characterization of mercury and multidrug-resistant Citrobacter freundii strains from tannery effluents in Kolkata, India.

Mercury (Hg) is one of the most potent toxic heavy metals that distresses livestock, humans, and ecological health. Owing to uncontrolled exposure to untreated tannery industrial effluents, metals such as Hg are increasing in nature and are, therefore, becoming a global concern. As a result, understanding the thriving microflora in that severe condition and their characteristics becomes immensely important. During the course of this study, two Hg-resistant bacteria were isolated from tannery wastewater effluents from leather factories in Kolkata, India, which were able to tolerate 2.211 × 10- 3 M (600µg/ml) Hg. 16S rDNA analysis revealed strong sequence homology with Citrobacter freundii, were named as BNC22A and BNC22C for this study. In addition they showed high tolerance to nickel (Ni) and Chromium (Cr) at 6.31 × 10- 3 M (1500µg/ml) and 6.792 × 10- 3 M (2000µg/ml) respectively. However, both the isolates were sensitive to arsenic (As) and cadmium (Cd). Furthermore, their antibiotic sensitivity profiles reveal a concerning trend towards resistance to multiple drugs. Overuse and misuse of antibiotics in healthcare systems and agriculture has been identified as two of the main reasons for the decline in efficacy of antibiotics. Though their ability to produce lipase makes them industrially potent organisms, their competence to resist several antibiotics and metals that are toxic makes this study immensely relevant. In addition, their ability to negate heavy metal toxicity makes them potential candidates for bioremediation. Finally, the green mung bean seed germination test showed a significant favourable effect of BNC22A and BNC22C against Hg-stimulated toxicity.

A novel genus of Pectobacterium bacteriophages display broad host range by targeting several species of Danish soft rot isolates

The bacterial diseases black leg and soft rot in potatoes cause heavy losses of potatoes worldwide. Bacteria within the genus Pectobacteriaceae are the causative agents of black leg and soft rot. The use of antibiotics in agriculture is heavily regulated and no other effective treatment currently exists, but bacteriophages (phages) have shown promise as potential biocontrol agents. In this study we isolated soft rot bacteria from potato tubers and plant tissue displaying soft rot or black leg symptoms collected in Danish fields. We then used the isolated bacterial strains as hosts for phage isolation. Using organic waste, we isolated phages targeting different species within Pectobacterium. Here we focus on seven of these phages representing a new genus primarily targeting P. brasiliense; phage Ymer, Amona, Sabo, Abuela, Koroua, Taid and Pappous. TEM image of phage Ymer showed siphovirus morphotype, and the proposed Ymer genus belongs to the class Caudoviricetes, with double-stranded DNA genomes varying from 39 kb to 43 kb. In silico host range prediction using a CRISPR-Cas spacer database suggested both P. brasiliense, P. polaris and P. versatile as natural hosts for phages within the proposed Ymer genus. A following host range experiment, using 47 bacterial isolates from Danish tubers and plants symptomatic with soft rot or black leg disease verified the in silico host range prediction, as the genus as a group were able to infect all three Pectobacterium species. Phages did, however, primarily target P. brasiliense isolates and displayed differences in host range even within the species level. Two of the phages were able to infect two or more Pectobacterium species. Despite no nucleotide similarity with any phages in the NCBI database, the proposed Ymer genus did share some similarity at the protein level, as well as gene synteny, with currently known phages. None of the phages encoded integrases or other genes typically associated with lysogeny. Similarly, no virulence factors nor antimicrobial resistance genes were found, and combined with their ability to infect several soft rot-causing Pectobacterium species from Danish fields, demonstrates their potential as biocontrol agents against soft rot and black leg diseases in potatoes.

Intra-species differences shape differences of enrofloxacin residues and its degradation products in tilapia: A precise risk assessment

The increasing use and abuse of antibiotics in agriculture and aquaculture necessitates a more thorough risk assessment. We first advocate a precise assessment that subdivides the assessment scope from interspecies to intraspecific levels. Differences in ENR residues and degradation within the intraspecific category were simultaneously explored. This study chose red and GIFT tilapia, both belonging to the intra-specific category of tilapia, for an enrofloxacin (ENR) exposure experiment. Red tilapia had a lower area under the curve (AUC) representing drug accumulation, indicating a notably shorter withdrawal period (7 days) compared to GIFT tilapia (31.4 days) in the edible parts. While four potential transformation pathways were proposed for ENR in tilapia, red tilapia had fewer detected degradation products (6 items) than GIFT tilapia (10 items), indicating a simpler transformation pathway in red tilapia. Predictive assessments using the Toxtree model revealed that of the four extra degradation products in GIFT tilapia, two may possess carcinogenic and mutagenic properties. Overall, differences were observed in ENR residues and degradation within the intraspecific category, with red tilapia presenting lower risks than GIFT tilapia. This work suggests a new strategy to perfect the methodology for antibiotic risk assessment and facilitate systematic antibiotic administration management in the future.

Antimicrobial Resistance: Challenges in Wartime - Ukrainian Perspective

The excessive and uncontrolled use of antibiotics in healthcare and agriculture has become the main cause of antibiotic resistance and the spread of antibiotic-resistant microorganisms in the environment. Every year, antibiotic resistance continues to grow worldwide, posing a significant challenge for humanity. The World Health Organization recognizes antibiotic resistance as one of the top 10 global threats to public health, jeopardizing the achievement of the United Nations Sustainable Development Goal. The consequences of antimicrobial resistance extend beyond the effective treatment of infections; it is a public health issue with global consequences. Socioeconomic losses and environmental threats are closely linked to this problem. Moreover, antibiotic resistance has long-term and unpredictable consequences related to wars and military conflicts. The impact of the war and a clear understanding of the global scope of antibiotic resistance as a result of hostilities can be seen through the outcome of russia's invasion of Ukraine on February 24, 2022. This military conflict not only highlighted the importance of preserving human life and promoting peaceful development at both national and global levels but also revealed potential risks for various global environmental issues, particularly the increasing spread of antibiotic resistance. The disruption caused by the war has transformed the issue of antibiotic resistance in Ukraine from a national concern to a powerful factor that affects the global scale of this problem, transcending borders. During the war, resources and priorities have shifted toward military needs, relegating human health and environmental protection to secondary importance. Migration and loss of highly qualified medical specialists and biologists, deterioration of the environmental situation, sanitary, hygienic conditions, lack of food resources and medicines, and other factors directly and indirectly contribute to the emergence and spread of antibiotic resistance globally. This review demonstrates the relevance of the issue of antibiotic resistance, the main mechanisms of the development and spread of antibiotic resistance, the global scale and consequences of antibiotic resistance due to the war in Ukraine and aims to provide an overview of international initiatives to reduce antibiotic resistance, in particular the “One Health” concept and strategies, which are currently being implemented. Solving the issue of antibiotic resistance globally and at the level of the country affected by war requires a comprehensive approach, which includes mandatory systematic surveillance of antibiotic resistance, control of the use of antimicrobial drugs, informing all segments of society about the use of antimicrobial drugs and the consequences of antibiotic resistance, the introduction of educational programs to prevent an improper use of antibiotics, environmentally safe methods of waste disposal in medical, food, and other enterprises that produce or use antibiotics, safe disposal of antibiotics, etc.

Enterococcus faecium: evolution, adaptation, pathogenesis and emerging therapeutics.

The opportunistic pathogen Enterococcus faecium colonizes humans and a wide range of animals, endures numerous stresses, resists antibiotic treatment and stubbornly persists in clinical environments. The widespread application of antibiotics in hospitals and agriculture has contributed to the emergence of vancomycin-resistant E. faecium, which causes many hospital-acquired infections. In this Review, we explore recent discoveries about the evolutionary history, the environmental adaptation and the colonization and dissemination mechanisms of E. faecium and vancomycin-resistant E. faecium. These studies provide critical insights necessary for developing novel preventive and therapeutic approaches against vancomycin-resistant E. faecium and also reveal the intricate interrelationships between the environment, the microorganism and the host, providing knowledge that is broadly relevant to how antibiotic-resistant pathogens emerge and endure.

Risk Assessment of Antibiotics in Agricultural Environment

Antibiotics are widely used in animal husbandry, planting, and aquaculture in agricultural industries. A large amount of the parent antibiotics used are released into the environment through discharge via feces and urine, posing potential risks to human health and ecosystems. It is thus very important to understand how antibiotics in the agricultural environment threaten the ecological environment and human health. Accordingly, risk assessment of antibiotics in the environment has become the research focus in recent years. The aim of this study was to review the risk assessment methods of antibiotics. The results showed that the ecological environment risk has mainly been assessed by the risk quotient (RQ). Predicted no-impact concentrations (PNECs) are an important indicator for ecological environment risk assessment, but a definite value is still controversial. The hazard quotient (HQ) is generally used to assess health risks. At present, it is necessary to clarify the selection of antibiotic exposure pathways and toxicological thresholds. However, neither of these two methods have currently considered either mixed pollution or the risk of antibiotic metabolites. Further analysis indicated that the ecological risks of antibiotics in the water environment and feces/manure/soil environment were widespread, which had an impact on both the soil and water environment. The types of antibiotics with high risk were different for various cultivated types. The factors including test species, testing conditions, calculation methods, and soil types all affected the detection of PNECs. Human health risk caused by dietary intake of antibiotics was minimal, but it cannot be ignored given the seafood consumption in coastal areas. Moreover, quinolones have both high ecological and human health risks in the agricultural environment. Based on the amount of antibiotics in agriculture and the residual concentration or toxicity of antibiotics in the related environment, this study proposed a priority-control list of antibiotics in the agricultural environment and summarized the main problems in the current antibiotic risk assessment. It will provide helpful support for the scientific optimization of antibiotic risk assessment and the effective control of antibiotics in agricultural environments.

The Use and Impact of Antibiotics in Plant Agriculture: A Review.

Growers have depended on the specificity and efficacy of streptomycin and oxytetracycline as a part of their plant disease arsenal since the middle of the 20th century. With climate change intensifying plant bacterial epidemics, the established success of these antibiotics remains threatened. Our strong reliance on certain antibiotics for devastating diseases eventually gave way to resistance development. Although antibiotics in plant agriculture equal to less than 0.5% of overall antibiotic use in the United States, it is still imperative for humans to continue to monitor usage, environmental residues, and resistance in bacterial populations. This review provides an overview of the history and use, resistance and mitigation, regulation, environmental impact, and economics of antibiotics in plant agriculture. Bacterial issues, such as the ongoing Huanglongbing (citrus greening) epidemic in Florida citrus production, may need antibiotics for adequate control. Therefore, preserving the efficacy of our current antibiotics by utilizing more targeted application methods, such as trunk injection, should be a major focus. [Formula: see text] Copyright © 2024 The Author(s). This is an open access article distributed under the CC BY 4.0 International license.

CATH-2-derived antimicrobial peptide inhibits multidrug-resistant Escherichia coli infection in chickens.

Avian colibacillosis (AC), caused by infection with Escherichia coli (E. coli), is a major threat to poultry health, food safety and public health, and results in high mortality and significant economic losses. Currently, new drugs are urgently needed to replace antibiotics due to the continuous emergence and increasing resistance of multidrug-resistant (MDR) strains of E. coli caused by the irrational use of antibiotics in agriculture and animal husbandry. In recent years, antimicrobial peptides (AMPs), which uniquely evolved to protect the host, have emerged as a leading alternative to antibiotics in clinical settings. CATH-2, a member of the antimicrobial cathelicidin peptide family, has been reported to have antibacterial activity. To enhance the antimicrobial potency and reduce the adverse effects on animals, we designed five novel AMPs, named C2-1, C2-2, C2-3, C2-4 and C2-5, based on chicken CATH-2, the secondary structures of these AMPs were consistently α-helical and had an altered net charge and hydrophobicity compared to those of the CATH-2 (1-15) sequences. Subsequently, the antimicrobial activities of CATH-2 (1-15) and five designed peptides against MDR E. coli were evaluated in vitro. Specifically, C2-2 showed excellent antimicrobial activity against either the ATCC standard strain or veterinary clinical isolates of MDR E. coli, with concentrations ranging from 2-8 μg/mL. Furthermore, C2-2 maintained its strong antibacterial efficacy under high temperature and saline conditions, demonstrating significant stability. Similarly, C2-2 retained a high level of safety with no significant hemolytic activity on chicken mature red blood cells or cytotoxicity on chicken kidney cells over the concentration range of 0-64 μg/mL. Moreover, the administration of C2-2 improved the survival rate and reduced the bacterial load in the heart, liver and spleen during MDR E. coli infection in chickens. Additionally, pathological damage to the heart, liver and intestine was prevented when MDR E. coli infected chickens were treated with C2-2. Together, our study showed that C2-2 may be a promising novel therapeutic agent for the treatment of MDR E. coli infections and AC.

Microencapsulated essential oils alleviate diarrhea in weaned piglets by modulating the intestinal microbial barrier as well as not inducing antibiotic resistance: a field research.

Microencapsulated essential oils (MEO)have been used as antibiotic alternatives that can be applied to alleviate diarrhea in weaning piglet. We examined a large group of weaned piglets and incorporated essential oil containing thymol (2%), carvacrol (5%) and cinnamaldehyde (3%) in the feed of weaned piglets on an intensive production farm. The piglets were divided into four groups; Control (no additions) and chlortetracycline (Chl), essential oil (EO) and microencapsulated essential oil (MEO) were fed ad libitum over a 28-day trial period. We found MEO significantly reduced the incidence of diarrhea in the piglets that was also accompanied by increased average daily weight gains from days 14-28 (p < 0.05). MEO enhanced the antioxidant capacity in the piglets and serum total antioxidant capacity (T-AOC) and glutathione peroxidase (GSH-px) levels were significantly increased (p < 0.05). MEO also significantly reduced expression of genes related to ileal inflammation (IL-6, TNF-α and TGF-β1) (p < 0.05) and significantly (p < 0.05) increased in sIgA antibody levels. MEO influenced the composition of the intestinal microbiome and reduced Bacteroidota (p < 0.05) and thus altered the Firmicutes/Bacteroidota ratio. However, none of the treatments produced significant changes in the most common tetracycline resistance genes (p > 0.05). Metagenomic analysis indicated that MEO impacted DNA expression, virulence factors, antioxidant activity and antimicrobial activity. Metabolomic analysis of the intestinal content also indicated that MEO impacted tyrosine metabolism and primary bile acid biosynthesis suggesting improved intestinal health and nutrient absorption. This study paves the way for further research into the development and optimization of MEO-based interventions aimed at improving piglet health and performance while also providing a reference for reducing reliance on antibiotics in animal agriculture.

Research status and rapid detection methods of antibiotic residues in agricultural products

Antibiotics are widely utilized in agriculture for the prevention and treatment of animal diseases. How-ever, the abuse and overuse of antibiotics progressively increase the risks of antibiotic residues and antibiotic resis-tance. The bioaccumulation and biomagnification of antibiotics through food chains will negatively affect ecological safety, and finally threaten human health. There are many shortages of traditional antibiotic detection techniques, such as complex procedures, complicated operation and time consuming, and thus are difficult to meet the demand of instant, efficient and accurate on-site detection. Therefore, it is crucial to develop rapid detection techniques of antibiotics to manage the application of antibiotics in agriculture. We reviewed the utilization, and management of antibiotics in animal husbandry, residual characteristics, and potential hazards of antibiotics in agricultural products, summarized the advancements in rapid detection techniques of antibiotics in agricultural products over the past five years, compared the advantages and disadvantages of different rapid detection techniques, and prospected the future development in this area. This review would provide a valuable reference to the control and point-of-care test of antibiotics in agricultural products.

Antibiotic Resistance Mechanisms and Strategies for Combating Resistance in Germany

Purpose: The aim of the study was to explore antibiotic resistance mechanisms and strategies for combating resistance in Germany Methodology: This study adopted a desk methodology. A desk study research design is commonly known as secondary data collection. This is basically collecting data from existing resources preferably because of its low cost advantage as compared to a field research. Our current study looked into already published studies and reports as the data was easily accessed through online journals and libraries. Findings: antibiotic resistance represents a complex and evolving challenge to public health in Germany. Mechanisms such as efflux pumps, mobile genetic elements, and enzymatic degradation contribute to the resilience of bacteria against antibiotics. However, strategic interventions have been identified to combat resistance effectively. Exploration of alternative therapies like bacteriophage therapy offers promising avenues for addressing antibiotic-resistant infections, especially in light of increasing resistance rates. Unique Contribution to Theory, Practice and Policy: Evolutionary theory of antibiotic resistance &amp; Game Theory in Antibiotic Stewardship may be used to anchor future studies on antibiotic resistance mechanisms and strategies for combating resistance in Germany. Implement antimicrobial stewardship programs across healthcare settings to optimize antibiotic use. These programs should involve prescriber education, antibiotic guidelines, and regular audits to promote appropriate prescribing practices and minimize unnecessary antibiotic exposure. Prioritize infection prevention measures, including hand hygiene, environmental cleaning, and infection control protocols, to reduce the spread of resistant pathogens within healthcare facilities and communities. Enact policies to regulate the use of antibiotics in human health, veterinary medicine, and agriculture. This includes restrictions on antibiotic use in food production, bans on over-the-counter antibiotic sales, and incentives for the development of new antibiotics.

Matrix effect on the Effectiveness of High Hydrostatic Pressure Treatment on Antibiotic Residues

The use of antibiotics in agriculture and livestock poses health risks to consumers. Treatments such as High Hydrostatic Pressure (HHP) have been shown to reduce antibiotic and pesticide residues in food. This study aims to investigate the matrix effect on the effectiveness of HHP on hydrochloride tetracycline (HTC) and sulfathiazole (STZ) residues in spiked food matrices. The effect of viscosity, as well as carbohydrate, protein, and fat content on the effectiveness of HHP on antibiotic residues, was investigated. The studied matrices were full-fat and fat-free bovine milk and model food systems consisting of aqueous solutions of sugars, aqueous solutions of proteins, and oil in water emulsions. Model food systems were also used to study the viscosity effect. These systems consisted of aqueous solutions of honey, aqueous solutions of apple puree, and aqueous solutions of glycerol. The HHP processing (580 MPa, 6 min, 25 °C) took place under industrial conditions. For both antibiotics, the concentration of sugars and proteins was found to affect the effectiveness of treatment. The concentration of oils affected treatment efficacy only for HTC. Reduction of antibiotics by HHP was also affected by the type of carbohydrate and the viscosity. In conclusion, the composition and the viscosity of the food matrix exert a variable effect on the studied antibiotic residues reduction by HHP indicating different underlying mechanisms of the interactions between food constituents and antibiotics under the same process conditions.