Antibiotic Residue Test Kits Market 2022 Global Industry Extensive Competitive Landscape on Size, Volume, Trends, Share and Revenue| Regional Forecast By 2028

Antibiotic Residue Test Kits Market 2022 Global Industry Extensive Competitive Landscape on Size, Volume, Trends, Share and Revenue| Regional Forecast By 2028

This report studies the Antibiotic Residue Test Kits Market with many aspects of the industry like the market size, market status, market trends and forecast, the report also provides brief information of the competitors and the specific growth opportunities with key market drivers. Find the complete Antibiotic Residue Test Kits Market analysis segmented by companies, region, type and…

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Antibiotic Residue Test Kits Market: Global Industry Analysis, Market Size, and Forecasts up to 2030

The report on the global antibiotic residue test kits market provides qualitative and quantitative analysis for the period from 2017 to 2025. The report predicts the global antibiotic residue test kits market to grow with a CAGR of 6.67% over the forecast period from 2019-2025. The study on antibiotic residue test kits market covers the analysis of the leading geographies such as North America, Europe, Asia-Pacific, and RoW for the period of 2017 to 2025. The report on antibiotic residue test kits market is a comprehensive study and presentation of drivers, restraints, opportunities, demand factors, market size, forecasts, and trends in the global antibiotic residue test kits market over the period of 2017 to 2025. Moreover, the report is a collective presentation of primary and secondary research findings.

Get More Information Here: https://www.sdki.jp/sample-request-103959 Porter's five forces model in the report provides insights into the competitive rivalry, supplier and buyer positions in the market and opportunities for the new entrants in the global antibiotic residue test kits market over the period of 2017 to 2025. Further, IGR- Growth Matrix gave in the report brings an insight into the investment areas that existing or new market players can consider. Report Findings 1) Drivers • Advanced technology in the antibiotic residue test kits can control or inhibit the microorganism’s growth in food • Rising awareness for the benefits and essentiality of antibiotic residual test kits in the food & beverages as well as dairy industry 2) Restraints • Less awareness about antibiotic residue test kit and its tests 3) Opportunities • Rising the health consciousness and health benefits of antibiotic residue test kits and increasing demand from dairy and food & beverages industry Research Methodology A) Primary Research Our primary research involves extensive interviews and analysis of the opinions provided by the primary respondents. The primary research starts with identifying and approaching the primary respondents, the primary respondents are approached include 1. Key Opinion Leaders associated with Infinium Global Research 2. Internal and External subject matter experts 3. Professionals and participants from the industry Our primary research respondents typically include 1. Executives working with leading companies in the market under review 2. Product/brand/marketing managers 3. CXO level executives 4. Regional/zonal/ country managers 5. Vice President level executives. B) Secondary Research Secondary research involves extensive exploring through the secondary sources of information available in both the public domain and paid sources. At Infinium Global Research, each research study is based on over 500 hours of secondary research accompanied by primary research. The information obtained through the secondary sources is validated through the crosscheck on various data sources. The secondary sources of the data typically include 1. Company reports and publications 2. Government/institutional publications 3. Trade and associations journals 4. Databases such as WTO, OECD, World Bank, and among others. 5. Websites and publications by research agencies Segment Covered The global antibiotic residue test kits market is segmented on the basis of product type, and end user. The Global Antibiotic Residue Test Kits Market by Product Type • Tetracycline • Macrolides • Beta-lactams • Aminoglycosides • Amphenicols • Sulfonamides The Global Antibiotic Residue Test Kits Market by End User • Food and Beverages Industry • Veterinary • Independent Laboratories • Other End Users Company Profiles The companies covered in the report include • Thermo Fischer Scientific • Eurofins Scientific • Labtek Services Ltd. • Charm Sciences • DSM • NEOGEN Food Safety • R-Biopharm AG • Sciex • IDEXX Labs • Perkin Elmer (BioScientific Corp.) What does this report deliver? 1. Comprehensive analysis of the global as well as regional markets of the antibiotic residue test kits market. 2. Complete coverage of all the segments in the antibiotic residue test kits market to analyze the trends, developments in the global market and forecast of market size up to 2025. 3. Comprehensive analysis of the companies operating in the global antibiotic residue test kits market. The company profile includes analysis of product portfolio, revenue, SWOT analysis and latest developments of the company. 4. IGR- Growth Matrix presents an analysis of the product segments and geographies that market players should focus to invest, consolidate, expand and/or diversify.

The dynamic nature of business environment in the current global economy is raising the need amongst business professionals to update themselves with current situations in the market. To cater such needs, Shibuya Data Count provides market research reports to various business professionals across different industry verticals, such as healthcare & pharmaceutical, IT & telecom, chemicals and advanced materials, consumer goods & food, energy & power, manufacturing & construction, industrial automation & equipment and agriculture & allied activities amongst others.

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Toxopathological Studies on Some Antimicrobial Drugs in Nile Tilapia (Oreochromis Niloticus) and Catfish (Clarias Gariepinus)

Introduction

 Fish consider one of the healthiest food as it is low in fat and rich in protein and omega 3 Fayet-Moore [1] & Yipel [2]. The fish farming industry is rapidly expanding in Egypt, as well as in other countries, it has been associated with recurrent bacterial infectious diseases. Farmed Nile tilapia represents more than 58.45, while catfish production is about 3.08% of the total aquaculture harvest in Egypt Gafrd [3]. Antimicrobial medications are used extensively in aquacultures for prophylactic or therapeutic purposes during microbial infections which may result in environmental pollution, development of resistant bacteria and my induce toxicity to human and animals Aly [4] & Khalil [5]. The availability of adequate data on the pharmacokinetics of antimicrobial agents in farmed fish is very important in order to minimize the environmental impacts of the drugs used in aquaculture. Since the excess amount of drugs can do harm to people, the European Union (EU) and the U.S. Food and Drug Administration (FDA) prescribed a Maximum Residue Limits (MRLs) for these drugs. The EU MRLs of CPX and SDM in fish were established at 100μg/kg Rezk [6] and 6-8μg/kg for quinolens in the edible tissues of fish Victoria [7].  

 Quinolones are effective antibacterial drugs widely used in human and veterinary medicine because of their potential therapeutic efficacy Plakas [8], Guo [9], Victoria [7] & Koc [10]. Ciprofloxacin is one of the most potent quinolones used to treat infections with gram negative bacteria as Escherichia coli, Pseudomonas aeruginosa, Salmonella spp., Shigella spp. and Haemophilus spp., and is also effective against some grampositive bacteria such as Staphylococcus aureus Davis [11] & Van Bambeke [12]. Oxytetracycline (OTC) is an antibacterial agent of tetracycline family that is extensively used for treatment of certain bacterial diseases in aquaculture all over the world Ambili [13]. The withdrawal time for edible tissue is differing according to the water temperature and the type of aquatic system Jeffry [14]. Because of the wide spread and long-time use of OTC, many residue studies have been recorded Rigos [15-16] & Julie [17].

 Sulfonamides are the oldest antimicrobial agents and still play an important role in aquaculture treatments. Sulfamethazine (SMZ) is the most used antimicrobial drug in Veterinary field. Sulfonamides residues have been repeatedly detected in the aquatic environment Kolpin [18] & Batt [19]. Moreover sulphamethoxazole residues have been reported in shrimp by Wang [20]. Sulfamethoxazole is an effective bacteriostatic against gram positive as well as gram negative bacteria; it affects bacteria by inhibiting folic acid synthesis Baran [21]. Antimicrobial drug residues may be transferred through food-chain to human and induce antibiotic resistance. To our knowledge, however, very few data are available about residues of ciprofloxacin, oxytetracycline and SDM in farmed Nile tilapia (O. niloticus) and catfish (C. gariepinus) reared under field conditions. However, this study aimed to investigate serum concentration peaks of ciprofloxacin, oxytetracycline and SDM post-treatment and their residues in liver, kidney and muscles together with serum biochemical estimation and histopathological examinations.

Materials and Methods

Animals and diet

Three hundred and sixty fish from each of Nile tilapia (O. niloticus), and catfish (C.gariepinus) (weight, about 50 and 75g for tilapia and catfish, respectively) were supplied from Central Lab for Aquaculture Research (CLAR), Egypt and used in this experiment that was performed in triplicates, following the Universal Directive on the protection of animals used for scientific purposes. Four different basal diets (control, CIP, oxytetracycline and sulfadimethoxine) were prepared in the form of pellets to use in the study. Basal diets were prepared by grinding the corn to granules using 0.5mm mesh (Thomes-Willey Laboratory Mill Model 4). Ingredients were mixed mechanically by horizontal mixture (Hobarts model D300T) at a low speed for 30 minutes. Oil (vegetable & cod liver) was added gradually to assure the homogeneity of the ingredients, the mixing speed increased for 5 minutes during the addition of water (600ml water) until the mixture began to clump. Pellets were then prepared using a pellet machine (CPM California pellet mill Co.) with 0.5cm diameter, and pellets were left to dry in air for 24 hrs (Table 1).

Fish with a history of no previous medication, were divided into 4 groups (each of three replicates, 30 fish each) and held in floating cages placed in fish farm ponds and group 1 fed a basal diet while groups 2-4 fed a medicated diet containing 1g CIP, 7.5g OTC and 25mg SDM/kg ration; respectively on a daily bases for five successive days. The temperature was recorded every 12h and adjusted to (26-30°C). The treatment was carried out once daily at 9 a.m. for 5 successive days at a rate of 1 .0% biomass using automatic feeders. Salinity, pH and total hardness were adjusted to, 3±1.1%, 8.21±0.21 and 38.9±1.9mg/L; respectively.

Sampling of the fish

The first sampling day was the 5th day of medication (0 day post treatment), and on the 1st, 3rd, 7th, 14th, and 21st days after the end of treatment with the antimicrobials. At each time of sampling, 15 fish from each group (5fish/replicate) were netted. Fish were anesthetized by immersion in water containing 0.1ppm MS-222 and blood samples were collected. Serum samples and muscle, liver and kidney specimens were collected from all groups. Muscle samples were taken from the dorso-lateral body area just posterior to the operculum. Each specimen was placed in a polyethylene bag and stored at -80°C until they were analyzed. CIP, OTC and SDM concentrations were estimated by ELISA.

Biochemical Studies

The activities of Asparate Aminotransferase (AST), Alanine Aminotransferase (ALT), Alkaline Phosphatase (AP), creatinine and urea, were estimated using commercial diagnostic Kits (Human Diagnostics, Germany). Methods were carried out according to the company directions.

Histopathological examinations

Tissues specimens from the muscles, liver and kidneys were collected at 5th day post-treatment and processed routinely according to Drury and Wallington (1980). Sections were stained with hematoxylin and eosin (H&E) and examined by light microscope.

Statistical analysis:

Statistical analysis was performed using the one way analysis of variance (ANOVA) followed by Duncan’s multiple range test to determine the differences among the six fish groups (mean at significance level of P<0.05). All analyses were run on the computer using SAS program Chris Hemedinger [2].

Results

Drug residues

Mean concentrations of the drugs (mean ± SE) vs. time in the serum, liver, kidney and musculature were recorded in (Table 1-3). The peak concentrations of the three drugs in serum were at 0 day. The lowest drug residues were seen in the muscles throughout the entire experiment.

Ciprofloxacine: Results obtained after oral dose of 1 g CIP/kg ration for 5 successive days were shown in (Table 2). The highest recorded concentrations of CIP in sera of Nile tilapia and Catfish were (1.91±0.38ug/ml) and (1.78±0.36ug/ml), respectively at 0 day. CIP concentrations were identified all over the experiment in kidneys with the highest concentrations (2.1±0.65ug/g) at 1st day in Nile tilapia and (1.80±0.64ug/g) at 0 day in kidneys in catfish. CIP neither detected in muscles of Nile tilapia nor of Catfish at 14th and 21st days post-treatment while, were not detect in livers of both kinds of fish at 21st days post-treatment.

Oxytetracycline: (Table 3) shows the serum, liver, kidney and muscle concentrations of OTC versus time in Tilapia and Catfish after oral administration of 75mg OTC/kg ration for 5 successive days. Peaks of OTC in serum were (2.15±0.41ug/ ml) and (2.02±0.31ug/ml) at 0 day in Nile tilapia and Catfish; respectively while, it was not detect in sera of both fish species after 14th and 21st days but detected only in one Catfish (0.03μg / ml) at 7th day post treatment. The highest tissue residues of OTC were (6.1±1.21ug/g) and (7.4±1.35ug/g) in liver of Nile tilapia and Catfish; respectively at 0 day of the treatment. In Nile tilapia and Catfish the OCT concentrations in kidneys were 0.08±0.04 and 0.05±0.02 (μg /g); respectively at 21st day post treatment. The lowest drug residues were in muscles throughout the entire experiment. OCT concentrations were detected in muscles of Nile tilapia and Catfish at (0.10±0.03ug/g) and (0.14±0.02ug/g); respectively after 21 days post treatment

Sulphadimethoxine: (Table 4) showed the mean concentrations of SDM in Nile tilapia and Catfish sera and tissues versus time profile after oral administration of 25mg SDM/kg ration for 5 successive days. The highest serum concentrations of SDM were (3.12±0.32ug/ml) and (2.98±0.46ug/ml) at 0 day in Nile tilapia and Catfish; respectively while it was detected in only one Tilapia fish (0.04μg /ml) at 7th day of treatment and not thereafter was detected. SDM was detected in kidneys of both Tilapia and catfish all over the experiment. SDM highest concentrations in kidney were at 0 day post-treatment (44.2±5.1ug/g) and (31.2±4.6ug/g) in Nile tilapia and Catfish; respectively. At 21st day of treatment; SDM was not detected in muscles and liver of Catfish but detected only in one Tilapia fish (0.11ug/g and 0.03ug/g in liver and muscles; respectively).

Biochemical results

(Figure 1,2) represented the biochemical results at 5th day of oral administration of CIP, OTC and SDM in both Nile tilapia and Catfish. ALT was significantly increased in both fish species after 5 days of oral administration of the three drugs compared with control. In Tilapia fish AST was significantly increased after administration of the three tested drugs while, in Catfish AST was significantly increased after administration of OTC and SDM in comparison with control. Creatinine was significantly increased in Nile tilapia with all three drugs but in Catfish it was significantly increased with OTC and SDM whereas not increased with CIP. Urea was significantly increased in Tilapia fish after administration of all drugs except OTC while, in Catfish urea was significantly increased in both OTC and SDM but not significantly changed in case of CIP compared with control.

Histopathological results

The oral administration of 1g CIP/kg ration for 5 successive days in Nile tilapia and Catfish at 5th days post-treatment, revealed minimal histopatholoigical alterations in comparison with the other treated groups. The musculature exhibited hyaline degeneration in few muscle bundles (Figure 3), the liver displayed nuclear pyknosis of some hepatocytes with mild parenchymal edema (Figure 4) while the kidneys showed proliferation of melanomachrophage cells and mild tubular nephrosis in the renal epithelium (Figure 5). The oral administration of 75mg OTC/kg ration, for 5 successive days in Tilapia and Catfish at 5th day posttreatment, revealed edema and focal hyaline degeneration in the musculature (Figure 6). Focal proliferation of melanomoacrophage cells was observed in the liver and kidney parenchyma. Wide spread vacuolar degeneration in the hepatocytes (Figure 7) and tubular nephroses in the renal tubular epithelium (Figure 8) were evident.

The oral administration of 25mg SDM/kg ration, for 5 successive days in both Nile tilapia and Catfish at 5th days posttreatment, revealed edema and hyaline degeneration as well as focal Zenker’s necrosis in the musculature with focal of mononuclear leukocytic infiltration (Figure 9). The liver exhibited wide spread vacuolar degeneration as well as coagulative necrosis in the hepatocytes with some mononuclear cells infiltration and melanomacrophages (Figure 10). The kidney showed tubular nephrosis mainly vacuolar degeneration with few cells exhibited coagulative necrosis, hyaline casts and few mononuclear cells infiltrations were evident (Figure 11).

Discussion:

Using of antimicrobial drugs in aquaculture production is one of the main sources of environmental pollution Pruden [23]; Rico & Van den Brink [24]. During the past years there was increase in the occurrence of antibiotic resistant bacteria and this is of critical implications on public health Gouvêa [25] & Rezk [6]. Quesada [26] & Guidi [27] mentioned that tetracycline, oxytetracycline (tetracyclines), enrofloxacin (quinolones), and sulfadimethoxine (sulfonamide) are most commonly used antibiotics in aquaculture worldwide and the presence of their residues in food could resulted in health hazards and toxic effects. Therefore, understanding the depletion of drugs from different tissues of fish is of extreme importance and the drug residues must be assessed in order to determine the time needed before the antimicrobials disappear from the tissues and to judge when the treated fish can be safely consumed. There are limited data about the occurrence of drugresidues in intensive culture of freshwater fishes in Egypt, hence the goal of this study was to estimate tissue distribution and residue depletion after oral administration of CIP, OTC and SDM in Nile tilapia (O. niloticus) and catfish (C. gariepinus).

The elimination and residues of antimicrobials depend upon dose, duration, fish species, and aquaculture conditions He [28]. Nile tilapia and catfish are kinds of tropical fish and the appropriate temperature for survival is ranging between 24– 32°C. The water temperature in this study was 26-30°C and the research was conducted on healthy fish in conditions those are quite close to actual aquaculture. In this study the withdrawal time of CIP from serum in both O. niloticus and C. gariepinus was almost 7days. Guo [9] concluded that CIP in eels eliminated from plasma for about 298h, after oral gavage of a single dose (10μg / kg). Wu [30] reported that, elimination half life of enrofloxacine and its metabolite ciprofloxacin were 15.61, 16.83, and 17.19h in muscle, liver, and plasma of Tilapia; respectively. Ciprofloxacin concentration was 0.3 and 0.1μg/g in liver and muscle of Chinese mitten-handed crab after single intramuscular injection of 5.0mg enrofloxacin/kg body weight Guanghong [31]. The maximum enrofloxacin concentrations in the muscle, liver and plasma of O. niloticus were 3.61μg/g, 5.96μg/g and 1.25μg/ml; respectively after oral dose of enrofloxacine (50mg/kg) for 7 days and the predicted withdrawal time was 22 days Weihai [32]. Withdrawal

time of CIP from muscle and liver under our experimental conditions was 14 days in both O. niloticus and C. gariepinus. Enrofloxacin metabolized into ciprofloxacin therefore, extended withdrawal time for enrofloxacin is recommended. Renal CIP concentrations in both O. niloticus and C. gariepinus were 0.12μg/g and 0.10μg/g; respectively at 21 days post-treatment. The main target organ for CIP metabolism is kidney Ole [33]. Our results showed that, serum OTC concentrations at 0 day posttreatment (5th day of medication) in Nile tilapia and catfish were 2.15 and 2.02μg/mL; respectively. Food and Drug Administration (FDA) regulations specify OTC treatment in finfish culture at 55 to 83mg/kg fish per day for 10 days with a 21-day withdrawal prior introducing for food. After 21 days, OTC concentrations must be below the tolerance of 2ppm (μg/g). The mean peak concentrations of OTC at 0 day post-treatment in fish muscle of O. niloticus and C. gariepinus were 0.94 and 0.99μg/g; respectively. Comparable to other studies carried out in farmed fish; Bjorklund & Bylund [34] found peak OTC concentrations of 0.6-1.5ug/g in farmed rainbow trout and salmon. Our study showed that, OCT concentration in muscle was 0.10μg/g and 0.14μg/g in O. niloticus and C. gariepinus at 21 day post-treatment. Rigos [16] recorded plasma and muscle concentrations of OCT were 0.9±0.2μg/ml and 3.0 ±1.1 μg/g in seabream 150 hours post single intravascular injection (40mg/kg) while, at 24h post-oral dosing (75mg/kg) muscle and liver concentrations of OCT were 0.008 and 6.2±1.8 (μg/g); respectively. Julie [17] observed that OCT concentrations in muscles of adult rainbow trout were below 2ug/g by 21 days after withdrawal of OTC medicated feed for 10 days. Bjorklund & Bylund [34] reported OCT concentration in muscle of rainbow trout (Salmo gairdneri ) to be below 1ug/g by 14 days after drug withdrawal. Josè [35] concluded OTC concentrations in sea bream muscle were lower than in all the other tissues and declined under 0.1ug/g 20 days after treatment ceased. Meanwhile, Rigos [17] concluded poor intestinal absorption of OCT and that oral administration was unsuccessful in sharp snout sea bream. Reda [36] found that, the OTC residues in O. niloticus muscles were 0.05ug/g after a withdrawal period of 15 days when supplemented in diet at 100mg/kg diet for 12 weeks, this level was lower than the MRLs of OTC (0.1ug/g) that established by commission regulations, EU [37]. The differences between these species are likely the result of physiological differences between species and/ or differences in experimental design. Hepatic accumulation of OCT in our work was observed in both O. niloticus & C.s gariepinus (0.51 and 0.98μg/g) 21 day post-treatment, respectively. Hepatic metabolism is the major route for OCT metabolism in different fish species. Rigos [17] and Bjorklund & Bylund [34] recorded OTC hepatic accumulation. Ole [38] recorded the highest average concentrations of SDM in plasma and muscles of Atlantic salmon (14.30μg/ml and 17.72μg/g, respectively) after oral administration in feed for 5 consecutive days as well as the withdrawal time was 288, 300 and 350 hrs in muscle, liver and kidney; respectively. The elimination half-life of SDM from blood of rainbow trout was 24.5 hours after a single oral administration (200mg/kg), at a water temperature of 15°C Kauzauki [39]. Our work showed that, the highest average concentration of SDM in liver, kidney and muscle were 8.95, 44.2 and 2.15μg/g; respectively in Nile tilapia at 0 day post-treatment. The corresponding values in catfish were 6.14, 31.2 and 2.02μg/g; respectively. SDM was not detectible at the 21th day post-treatment in muscle of C. gariepinus and detected only in one O. niloticus.

Conclusion

The antimicrobial drugs based on dose and type may negatively impact the liver and kidney functions with significant changes in enzymatic parameters and histopathological picture [48-55]. Also, the three tested medications had residues in the liver, kidney and muscles of Nile tilapia and catfish, the lowest drug residues were in muscles. CIP is considered as the safest one with the least residues. For the control of fish bacterial diseases, preventive measures should be applied and during urgent need, the selection of correct antimicrobial agent is very important through frequent antimicrobial sensitivity testing. An antimicrobial with minimal residue limit should be selected to protect animal and human health from potential hazards caused by contaminated fish. However, further studies are needed to estimate the toxicity of therapies in the aquatic creatures and environment.

Ethical approval

All the animals were maintained in accordance with the National and International Institutional Guidelines for the Care and Use of Animals for Scientific purposes.

Competing interest

The authors declare that they have no significant competing financial, professional or personal interests that might have influenced the performance or presentation of the work described in this manuscript.

THE DIFFERENCE BETWEEN ORGANIC AND NON ORGANIC FOODS

We all live as the purpose to provide our families with the safest and most nutrient healthy food and reduce the toxins we are consuming. Purchasing food can be healthy and non-harmful, particularly if we are constantly concerned about buying organic vs. Non-organic foods.

In food testing services, food content processing is an important part of manufacturing safe, useful goods more efficiently. Current food industry certainly needs monitoring, and testing is about maintaining high quality and protecting the public health. As consumption is prevalent in the food industry, the requirement for food testing thus has an important role to play.

Food processing takes place in laboratories and it can be achieved with the help of food testing kits as well. Food test kits are the tool that helps to establish whether or not a food item contains bacteria which may or may not cause diseases carried by food. These products can usually be used on food, water, and hard surfaces, and are mostly intended for rapid and easy use at home and company.

Nabl and fssai food standard

Nabl accredited food safety and quality testing laboratory formulate the standards to regulate the food testing laboratories to achieve the reliable results on food safety testing. The labs must be equipped with well-trained scientific and technical staff to give consumers precise, reliable and traceable analytical tests. Fssai recognition testing labs are improvised with innovative ideological methods to ensure food safety.

 Scientific Food Testing Services (SFTS)

Sfts stands as one of the well-equipped

fssai notified nabl accredited labs

in Chennai. Physico-chemical properties and nutrient marking are performed as per NABL standard in SFTS.  Sfts laboratories test food safety with modern technological methods and equipment for food industries such as rice production, pulse manufacturing, edible oil industries, exporters, importers, pharmaceutical and biotech industries, self-help organizations, small-scale food companies, food business owners. Following methods performed for food safety testing like physico-chemical analysis, pesticide residues, antibiotics, veterinary drugs, food adulterants, food additives, contaminants and naturally occurring toxic substances.

Antibiotic Residue Test Kits Market is estimated to value over USD xx billion by 2027 end and register a CAGR of xx% during the forecast period 2020 to 2027.

The report initiates from the outline of business surroundings and explains the commercial summary of chain structure. Moreover, it analyses forecast by product type, by application and by region and Antibiotic Residue Test Kits Market Trends.

Antibiotic Residue Test Kits Market Research Investigates World Market Analysis 2026

Global Antibiotic Residue Test Kits Market - A report by Fact.MR

Fact.MR, in its latest business intelligence study, depicts the nuts and bolts of the global antibiotic residue test kits market. The antibiotic residue test kits market report presents detailed information regarding the drivers, restraints, opportunities and trends affecting market growth. Each segment along with its sub-segment is analyzed in terms of value and volume. Further, the keyword report elaborates the market behavior of each vendor operating in the antibiotic residue test kits market.

The antibiotic residue test kits market report considers the following years to present the overall market growth:

History Year: 2012-2016

Base Year: 2012

Estimated Year: 2026

Forecast Year: 2017 – 2026

Key findings of the antibiotic residue test kits market study:

Regional breakdown of the antibiotic residue test kits market based on predefined taxonomy.

Innovative manufacturing processes implemented by antibiotic residue test kits market vendors in detail.

Region-wise and country-wise fragmentation of the antibiotic residue test kits market to grasp the revenue, and growth outlook in these areas.

Changing preferences among consumers across various regions and countries.

Factors (Positive and Negative) impacting the growth of the global antibiotic residue test kits market.

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On the basis of Test Type, the antibiotic residue test kits market study consists of:

Beta-lactams

Macrolides

Tetracycline

Aminoglycosides

Amphenicols

Sulfonamides

On the basis of end use, the antibiotic residue test kits market study incorporates:

Food and Beverage Industry

Veterinary

Independent Laboratory

On the basis of region, the antibiotic residue test kits market study contains:

North America (U.S., Canada)

Latin America (Brazil , Mexico)

APEJ (Australia, Singapore)

MEA (South Africa, Nigeria)

Key players analyzed in the antibiotic residue test kits market study:

Thermo Fisher Scientific

Koninklijke DSM N.V.

Charm Sciences

Perkin Elmer

Labtek Services Ltd.

Neogen Corporation

IDEXX Labs

R-Biopharm AG

Eurofins Scientific

Danaher Corporation

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Queries addressed in the antibiotic residue test kits market report:

How has the global antibiotic residue test kits market grown over the historic period of 2012-2016?

Why are the antibiotic residue test kits market players targeting region for increased product sales?

What patented technologies are the players utilizing in the global antibiotic residue test kits market ?

Which regions are displaying the fastest growth in the antibiotic residue test kits market ?

What are the underlying micro- macroeconomic factors affecting the global antibiotic residue test kits market?

Why choose Fact.MR?

Reports published by Fact.MR are a result of the combination of our experts and digital technologies. We thrive to provide innovative business solutions to the clients as well as tailor the reports aligning with the clients’ requisites. Our analysts perform comprehensive research to offer ins and outs of the current market situation. Clients across various time zones tend to utilize our 24/7 service availability.

Antibiotic Residue Test Kits Market Gain Impetus due to the Growing Demand over 2017 to 2026

Key role of simple diagnostic tests in detecting the presence of antibiotic residues in foods derived from animals will continue to propel the demand for antibiotic residue test kits. These tests ensure the food is safe for human consumption. Findings from these tests are of great value in increasing the nutritional index of animal-based foods. Moreover, stringent food safety measures continue to necessitate the need for adopting antibiotic residue test kits in the food & beverage industry.

Fact.MR’s recent report estimates the expansion of the global market for antibiotic residue test kits for the period, 2017-2026. During this forecast period, the global antibiotic residue test kits market is expected to witness growth at 6.2% CAGR in terms of value. By the end of 2026, around US$ 295 Mn worth of antibiotic residue test kits are expected to be sold globally.

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4 Key Highlights from the Report

According to the report, the adoption of beta-lactams tests will be the highest across the global antibiotic residue test kits market. The report observes that throughout the forecast period, sales of beta-lactams tests will account for approximately one-third share of global market revenues. By the end of 2026, nearly US$ 95 Mn worth of beta-lactams test kits will be sold globally. The demand for tetracycline tests will also gain traction in the upcoming years, bringing in around US$ 50 Mn in global revenues by the end of 2026. Meanwhile, sulfonamides tests will register fastest revenue growth at a CAGR of 7.1% over the forecast period.

Food and beverage industry will represent the largest end-user of antibiotic residue test kits. More than 65% of the global antibiotic residue test kits market value will be accounted by the end-use of these kits in ensuring the safety of food items and beverages, particularly for dairy products. The report also observes a rampant end-use of antibiotic residue test kits in veterinary purposes.

In 2017, North America registered highest sales of antibiotic residue test kits. The consumer marketplaces in the US and Canada will continue to promote the use of antibiotic residue test kits in food safety measures. By the end of 2026, North America will be dubbed as the largest market for antibiotic residue test kits, surpassing an estimated valuation of US$ 100 Mn.

Europe and the Asia-Pacific excluding Japan (APEJ) regions are also expected to be at the forefront of global antibiotic residue test kits market expansion. These two region will register fast revenue growth in their antibiotic residue test kits markets, particularly due to high presence of dairy product manufacturers.

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The report has profiled key companies developing antibiotic residue test kits across the globe. Companies namely, are observed as Thermo Fisher Scientific, Charm Sciences, DSM, Labtek Services Ltd., Perkin Elmer (Bio Scientific Corp.), IDEXX Labs, Neogen Food Safety, R-Biopharm AG, Sciex, and Eurofins are observed as key players in the global antibiotic residue test kits market. Majority of these players will be incorporating the advancements in the diagnostics of antibiotic residues. Extending the application of antibiotic residue test kits beyond measuring the safety of animal-based foods will also be prioritized by these companies in the near future.

Antibiotic Residue Test Kits Market Trend Share Opportunities And Forecast To 2025

The global antibiotic residue test kits market is foreseen to show advancement in terms of growth due to the rise of deadly animal diseases affecting humans. Antibiotic residue test kits are not only used to measure the safety level of animal-based food but also plant-based food. The need to effectively tackle agro-terrorism that involves the use of bioweapons is predicted to increase the demand for antibiotic residue test kits. Manufacturers are expected to launch products that can provide fast results. They could also add technologically sophisticated features to their products to increase their functionality.

In May 2019, Ringbio, a Chinese manufacturer of rapid tests for food and animal safety, launched a new test kit to detect antibiotic residue in meat products in a simple, sensitive, and quick way. In June 2019, Labtek Services, a UK-based provider of instrumentation and support services to the food and beverage, dairy processing, and farming industries, introduced new adenosine triphosphate (ATP) hygiene monitoring device ENSURE TOUCH. The ATP luminometer can be used for food and beverage and healthcare applications.

Rising Preference for Food Tested for Antibiotic Residue to Increase Sales Growth

High consumer preference for food products that clear antibiotic residue tests is predicted to increase the adoption of antibiotic residue test kits in future. Increasing need to maintain the safety of food products to avoid diseases could push the demand for antibiotic residue test kits even more. Advancement in technology that has allowed manufacturers to develop multidisciplinary products is anticipated to add to the growth of the global antibiotic residue test kits market. Antibiotic residue test kits are increasingly used in veterinary applications apart from food and beverage. This could create additional revenue opportunities for manufacturers.

Manufacturers to Launch Multipurpose Products for Range of Applications

Some of the leading companies competing in the global antibiotic residue test kits market are Thermo Fischer Scientific, DSM, Charm Sciences, PerkinElmer, Labtek Services Ltd., NEOGEN Food Safety, IDEXX Labs, R-Biopharm, Eurofins, and Sciex. In the coming years, manufacturers are anticipated to launch multipurpose products for better antibiotic residue diagnostics. They could also focus on introducing more advanced antibiotic residue test kits for applications beyond examining the safety of animal-based food.

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Important Points to Remember

●   Growing need to ensure food safety to augment the demand for antibiotic residue test kits

●   Beta-lactams test to account for a substantial market share during the forecast period

●   Global antibiotic residue test kits market to show higher growth in the food and beverage industry

●   The US and Canada to support North America in collecting a remarkable market share

By Type

●   Beta-lactams

●   Tetracyclines

●   Macrolides

●   Aminoglycosides

●   Sulfonamides

●   Amphenicols

By Application

●   Food and Beverage

●   Veterinary

●   Independent Laboratory

●   Others

Among type segments, beta-lactams are forecast to collect a sizable share of the global antibiotic residue test kits market. These tests are largely conducted in the food and beverage industry to detect antibiotic residues in products. They are prognosticated to account for a significant sales share of the global market. Among application segments, food and beverage is foretold to become more prominent during the forecast period. This could be due to the need to ensure the safety of consumers of milk and other dairy products.

By Region

Asia Pacific and Europe are prophesied to exhibit faster growth in the global antibiotic residue test kits market because of heavy presence of dairy companies. North America is likely to secure a commanding market share in the coming years due to high demand in key countries such as the US and Canada. It is also expected to record substantial sales growth in the global market.

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Global Antibiotic Residue Test Kits Market 2018- Eurofins, Thermo Fisher, DSM, Bioo Scientific, IDEXX Labs, Sciex, NEOGEN, R-Biopharm and Charm

Global Antibiotic Residue Test Kits Market 2018- Eurofins, Thermo Fisher, DSM, Bioo Scientific, IDEXX Labs, Sciex, NEOGEN, R-Biopharm and Charm

eReportsMarket has recently added a new Antibiotic Residue Test Kits research report to its huge database of research studies. New Report Presents 2013-2018 Review, 2025 Forecasts of Global Antibiotic Residue Test Kits Market. The research report, titled “Global Antibiotic Residue Test Kits Market 2018 Industry Research Report,”provides a comprehensive analysis of the industry, including an…

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Laboratory Chemical Reagents Market Growth, Trends and Forecast up to 2020

Chemical reagent is a substance or a compound that is used in a chemical reaction to detect, examine, measure or produce other chemical substance. The global market for laboratory chemical reagents is expected to witness significant growth due to increased usage of chemical reagents in the large scale commercial applications and basic research activities. Additionally, continuous technological advancements in the field of bio-therapeutics, recombinant DNA and cell culture have enhanced the scientific ability to identify and produce human therapeutics for ages. Hence, this has also contributed in robust growth of the market.

The Global Market For Laboratory Chemical Reagents can be segmented on the basis of products segments and end users. The product segments category can be subdivided into molecular biology (gene expression, gene synthesis, vectors, monoclonal & polycolonal antibodies, extraction kits, enzymes, cloning & sequencing, PCR reagents, and others), cytokine and chemokine testing, carbohydrate analysis, immunochemistry, cell/tissue culture, environmental testing (pesticide residue & others) and biochemistry. Of these microbiology currently holds the largest share of the market whereas, cytokine and chemokine testing is expected to emerge as the fastest growing segment in near future. Biotechnology, academic segment, non-academic segment and corporate segment, are some of the end users of laboratory chemical reagents. Field of molecular biology witnessed plethora of new opportunities with the conclusion of human genome project which has expanded the usage of polymerase chain reaction. At present, PCR technologies are being used in wide range of applications such as paternity testing, forensic finger printing, gene expression and DNA sequencing. The market for PCR is growing on account of rising awareness and increased acceptance of real-time PCR. The reagents used in real time PCR offer instant and quality results as compared to conventional PCR which is consequently expected to increase the sales of PCR reagents.

Furthermore, the market for laboratory chemical reagents would be fuelled by increasing launch of monoclonal antibody therapeutics products and growth in cell culture manufacturing. Monoclonal antibodies are being used for effective treatment for inflammatory disease, cardiovascular disease and cancer treatment. Physicians are turning towards prescription of monoclonal antibodies due to effectiveness of the antibiotics. Hence, increasing demand of monoclonal antibodies would also benefit the market for laboratory chemical reagents.

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 Geographically, North America is witnessed to be the largest market share holder of the global laboratory chemical reagents market. The dominance of this region is estimated on the basis of innovations in the nucleic acid testing procedures, technological advancements and improvements in cell and tissue culture technology. Additionally, advancements in molecular pathology assays is another major factor cited to drive the growth of this market. Asia-Pacific region is anticipated to emerge as the fastest growing region due to establishment of new academic centers across the region especially in the areas of chemical and biological sciences. Similarly, entry of new pharmaceutical companies in the region will increase investment in more research and development activities consequently enabling more test analysis. Similarly, increasing clinical research outsourcing activities in the Asian region will accentuate the demand for chemical lab for measuring drug quality or testing the quality of products in the chemical industry, food industry or biological areas of research and development.

BD Biosciences, bioMérieux, Beckman Coulter Inc., CALTAG Laboratories, GE Healthcare, EMD Chemicals Inc., Life Technologies Corporation, Meridian Life Science Inc., Lonza Biologics Ltd., PerkinElmer Inc., QIAGEN, Promega Corporation, Sigma-Aldrich Corp., Shimadzu Biotech, Takara Bio Inc., Wako Pure Chemical Industries and others are some of the major players operating in laboratory chemical reagents market.

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Laboratory Chemical Reagents Market; Latest Developments, Growth & Demand Future Outlook 2020

Chemical reagent is a substance or a compound that is used in a chemical reaction to detect, examine, measure or produce other chemical substance. The global market for laboratory chemical reagents is expected to witness significant growth due to increased usage of chemical reagents in the large scale commercial applications and basic research activities. Additionally, continuous technological advancements in the field of bio-therapeutics, recombinant DNA and cell culture have enhanced the scientific ability to identify and produce human therapeutics for ages. Hence, this has also contributed in robust growth of the market. The global market for laboratory chemical reagents can be segmented on the basis of products segments and end users. The product segments category can be subdivided into molecular biology (gene expression, gene synthesis, vectors, monoclonal & polycolonal antibodies, extraction kits, enzymes, cloning & sequencing, PCR reagents, and others), cytokine and chemokine testing, carbohydrate analysis, immunochemistry, cell/tissue culture, environmental testing (pesticide residue & others) and biochemistry. Of these microbiology currently holds the largest share of the market whereas, cytokine and chemokine testing is expected to emerge as the fastest growing segment in near future. Biotechnology, academic segment, non-academic segment and corporate segment, are some of the end users of laboratory chemical reagents.

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Field of molecular biology witnessed plethora of new opportunities with the conclusion of human genome project which has expanded the usage of polymerase chain reaction. At present, PCR technologies are being used in wide range of applications such as paternity testing, forensic finger printing, gene expression and DNA sequencing. The market for PCR is growing on account of rising awareness and increased acceptance of real-time PCR. The reagents used in real time PCR offer instant and quality results as compared to conventional PCR which is consequently expected to increase the sales of PCR reagents. Furthermore, the market for laboratory chemical reagents would be fuelled by increasing launch of monoclonal antibody therapeutics products and growth in cell culture manufacturing. Monoclonal antibodies are being used for effective treatment for inflammatory disease, cardiovascular disease and cancer treatment. Physicians are turning towards prescription of monoclonal antibodies due to effectiveness of the antibiotics. Hence, increasing demand of monoclonal antibodies would also benefit the market for laboratory chemical reagents.

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Geographically, North America is witnessed to be the largest market share holder of the global laboratory chemical reagents market. The dominance of this region is estimated on the basis of innovations in the nucleic acid testing procedures, technological advancements and improvements in cell and tissue culture technology. Additionally, advancements in molecular pathology assays is another major factor cited to drive the growth of this market. Asia-Pacific region is anticipated to emerge as the fastest growing region due to establishment of new academic centers across the region especially in the areas of chemical and biological sciences.

Similarly, entry of new pharmaceutical companies in the region will increase investment in more research and development activities consequently enabling more test analysis. Similarly, increasing clinical research outsourcing activities in the Asian region will accentuate the demand for chemical lab for measuring drug quality or testing the quality of products in the chemical industry, food industry or biological areas of research and development. BD Biosciences, bioMérieux, Beckman Coulter Inc., CALTAG Laboratories, GE Healthcare, EMD Chemicals Inc., Life Technologies Corporation, Meridian Life Science Inc., Lonza Biologics Ltd., PerkinElmer Inc., QIAGEN, Promega Corporation, Sigma-Aldrich Corp., Shimadzu Biotech, Takara Bio Inc., Wako Pure Chemical Industries and others are some of the major players operating in laboratory chemical reagents market.

About Us Transparency Market Research (TMR) is a global market intelligence company providing business information reports and services. The company’s exclusive blend of quantitative forecasting and trend analysis provides forward-looking insight for thousands of decision makers. TMR’s experienced team of analysts, researchers, and consultants use proprietary data sources and various tools and techniques to gather and analyze information. Transparency Market Research 90 State Street, Suite 700, Albany, NY - 12207 United States Tel: +1-518-618-1030 USA - Canada Toll Free 866-552-3453 Email: [email protected] Website: www.transparencymarketresearch.com

Antibiotic Residue Test Kits United States Industry Market Report 2017

Antibiotic Residue Test Kits United States Industry Market Report 2017

ReportsMonitor.ComAddsAntibiotic Residue Test Kits United States Industry Market Size, Industry Analysis & Forecast Report 2017” To Its Database.

In this report, the United States Antibiotic Residue Test Kits market is valued at USD XX million in 2016 and is expected to reach USD XX million by the end of 2022, growing at a CAGR of XX% between 2016 and 2022.

Geographically, this report splits the…

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