Colorimetric detection of neomycin sulfate in serum based on ultra-small gold nanoparticles with peroxidase-like activity.

Neomycin sulfate (NEO) is a kind of aminoglycoside antibiotics. Because of its strong ototoxicity, nephrotoxicity and other side effects, its content in the body should be strictly monitored during use. In this paper, a rapid colorimetric detection method for NEO based on ultrasmall polyvinylpyrrolidone modified gold nanoparticles (PVP/Au NPs) with peroxidase-like activity was developed. Firstly, ultra small PVP/Au NPs with weak peroxidase-like activity were synthetized. When they were mixed with NEO, strong hydrogen bonds were formed between NEO and PVP, resulting in the aggregation of PVP/Au NPs, and the aggregated PVP/Au NPs showed stronger peroxidase-like activity. Therefore, rapid colorimetric detection of NEO was achieved by utilizing the enhanced peroxidase-like activity mechanism caused by the aggregation of ultra small PVP/Au NPs. The naked eye detection limit of this method is 50 nM. Within the range of 1 nM-300 nM, there was a good linear relationship between NEO concentration and the change in absorbance intensity of PVP/Au NPs-H2O2-TMB solution at 652 nm, with the regression curve of y = 0.0045x + 0.0525 (R2 = 0.998), and the detection limit is 1 nM. In addition, this method was successfully applied to the detection of NEO in mouse serum. The recoveries were 104.4 % -107.6 % compared with HPLC assay results, indicating that this method for NEO detection based on PVP/Au NPs has great potential in actual detection of NEO in serum.

Anti-proliferative, antimicrobial, DFT calculations, and molecular docking 3D scaffold based on sodium alginate, chitosan, neomycin sulfate and hydroxyapatite.

3D multifunctional scaffold has been designed based on Cs/SA/NS/NPHA. Nanoparticles hydroxyapatite (NPHA) was prepared via precipitation method of sodium dihydrogen phosphate in presence calcium chloride. Different ratios of Chitosan (CS)/Sodium Alginate (SA) were used to prepare Cs/SA scaffolds in presence of CaCl2 as a cross linker. NPHA was incorporated in CS/SA scaffold and neomycin sulfate (NS) was added as an antimicrobial agent. The structure and surface morphology of the scaffolds were investigated via infrared spectroscopy (FTIR), X-ray diffraction (XRD), scanning electron microscope (SEM) and thermal gravimetric analysis (TGA) techniques. Additionally, Antimicrobial activity of the scaffold has evaluated against Gram- negative and Gram- positive bacteria. The result showed promising antimicrobial activity against Bacillus subtilis, Staphylococcus aureus, Escherichia coli, Pseudomonas aeruginosa and Candida albicans. Furthermore, cytotoxicity against MG63 osteosarcoma cell and fibroblast normal cell line has investigated. The result showed anti-proliferative against MG63. DFT calculations and molecular docking were used to study the reactivity of the compounds. The results exhibited that Cs/SA/NS/NPHA is potent expected to be used in bone tissue regeneration.

Selective Sensing in Microbial Fuel Cell Biosensors: Insights from Toxicity-Adapted and Non-Adapted Biofilms for Pb(II) and Neomycin Sulfate Detection.

This study introduces the utilization of self-powered microbial fuel cell (MFC)-based biosensors for the detection of biotoxicity in wastewater. Current MFC-based biosensors lack specificity in distinguishing between different pollutants. To address this limitation, a novel approach is introduced, capitalizing on the adaptive capabilities of anodic biofilms. By acclimating these biofilms to specific pollutants, an enhancement in the selectivity of MFC biosensors is achieved. Notably, electrochemically active bacteria (EAB) were cultivated on 3D porous carbon felt with and without a model toxicant (target analyte), resulting in the development of toxicant-resistant anodic biofilms. The model toxicants, Pb2+ ions and the antibiotic neomycin sulfate (NS), were deployed at a concentration of 1 mg L-1 during MFC operation. The influence of toxicity on biofilm growth and power production was investigated through polarization and power density curves. Concurrently, the electrochemical activity of both non-adapted and toxicity-adapted biofilms was investigated using cyclic voltammetry. Upon maturation and attainment of peak powers, the MFC reactors were evaluated individually as self-powered biosensors for pollutant detection in fresh wastewater, employing the external resistor (ER) mode. The selected ER, corresponding to the maximum power output, was positioned between the cathode and anode of each MFC, enabling output signal tracking through a data logging system. Subsequent exposure of mature biofilm-based MFC biosensors to various concentrations of the targeted toxicants revealed that non-adapted mature biofilms generated similar current-time profiles for both toxicity models, whereas toxicity-adapted biofilms produced distinctive current-time profiles. Accordingly, these results suggested that merely by adapting the anodic biofilm to the targeted toxicity, distinct and identifiable current-time profiles can be created. Furthermore, these toxicity-adapted and non-adapted biofilms can be employed to selectively detect the pollutant via the differential measurement of electrical signals. This differentiation offers a promising avenue for selective pollutant detection. To the best of our current knowledge, this approach, which harnesses the natural adaptability of biofilms for enhanced sensor selectivity, represents a pioneering effort in the realm of MFC-based biosensing.

Study on the Quality Control Standard of Lvxintong Rugao / 药学实践杂志

Objective To establish a quality control method for Lvxintong Rugao. Methods Ketoconazole, Halcinonide and Neomycin sulfate were identified by TLC. The content of Ketoconazole and Halcinonide were determined by HPLC. The chromatographic column of Agilent ZORBAX SB-C18 (4.6 mm×150 mm, 5 μm) column was used. Methanol-phosphate buffer (pH=7.40, 75:25) was applied as the mobile phase. The detection wavelength was 235 nm. The flow rate was 1.0 ml/min and the column temperature was set at room temperature. Neomycin Sulfate was determined by polarimetric analysis. Results The identification and determination methods showed good specificity. Ketoconazole and Halcinonide displayed good linearity within the range of 1.999~39.98 μg (r=0.999 9) and 0.400 8~8.016 μg (r=0.999 9), respectively. The average recoveries were 97.75% (RSD 0.77%) and 97.57% (RSD 0.84%), respectively. For the determination of Neomycin Sulfate, r=0.999 6 (n=6) in the range of 130.4~2 608 U/ml (n=6). The precision and repeatability of RSD were 1.1% and 1.6%, respectively. The solutions were stable in 6 h and the average recovery was 98.8% (RSD 2.6%). Conclusion The method could be used as the quality control method for Lvxintong Rugao.

Optimization of process parameters for fabrication of electrospun nanofibers containing neomycin sulfate and Malva sylvestris extract for a better diabetic wound healing.

Diabetes mellitus is one of the most concerning conditions, and its chronic consequences are almost always accompanied by infection, oxidative stress, and inflammation. Reducing excessive reactive oxygen species and the wound's inflammatory response is a necessary treatment during the acute inflammatory phase of diabetic wound healing. Malva sylvestris extract (MS) containing nanofibers containing neomycin sulfate (NS) were synthesized for this investigation, and their impact on the healing process of diabetic wounds was assessed. Using Design Expert, the electrospinning process for the fabrication of NS nanofibers (NS-NF) was adjusted for applied voltage (X1), the distance between the needle's tip and the collector (X2), and the feed rate (X3) for attaining desired entrapment efficacy [EE] and average nanofiber diameter (ND). The optimal formulation can be prepared with 19.11 kV of voltage, 20 cm of distance, and a flow rate of 0.502 mL/h utilizing the desirability approach. All the selected parameters and responses have their impact on drug delivery from nanofibers. In addition, M. sylvestris extracts have been added into the optimal formulation [MS-NS-NF] and assessed for their surface morphology, tensile strength, water absorption potential, and in vitro drug release studies. The NS and MS delivery from MS-NS-NF has been extended for more than 60 h. M. sylvestris-loaded nanofibers demonstrated superior antibacterial activity compared to plain NS nanofibers. The scaffolds featured a broad aspect and a highly linked porous fibrous network structure. Histomorphometry study and the in vitro scratch assay demonstrate the formulation's efficacy in treating diabetic wound healing. The cells treated with MS-NS-NF in vivo demonstrated that wound dressings successfully reduced both acute and chronic inflammations. To improve the healing of diabetic wounds, MS-NS-NF may be regarded as an appropriate candidate for wound dressing.

Development, Characterization and In Vitro Antimicrobial Evaluation of Novel Flavonoids Entrapped Micellar Topical Formulations of Neomycin Sulfate.

Flavonoids are the secondary metabolites widely used in pharmaceutical industries due to their several health benefits. Quercetin and rutin, well known flavonoids possesses various pharmacological properties but the constraints of poor aqueous solubility and impermeability across cell membranes restricts their use in formulation development. Moreover, the rising problem of antimicrobial resistance has also caused a serious threat to human life, thus demanding the urgent need of developing more effective antimicrobial formulations. In view of this, the present research work is focused on utilizing the most feasible flavonoid-surfactant concentrations obtained from the already reported physico-chemical analysis in developing an improved neomycin topical formulation through drug combinatorial approach. The formulations were subjected for assessment of physical parameters such as determination of pH, viscosity and spreadability. The drug release profile of the formulations was studied through different mathematical models. After evaluation of all the parameters, two best formulations (NQ-T2 [HE] and NR-T1 [HE]) were selected for antimicrobial evaluation studies against different bacterial and fungal clinical isolates. Among the two formulations, NQ-T2 [HE] showed excellent antibacterial activity against the bacterial strains while NR-T1 [HE] also exhibited promising results when compared with the standard formulations. Overall, this study represents a possible solution to enhance the antimicrobial efficacy of neomycin formulations by combining them with flavonoids through micelles assisted drug combination approach.

Involvement of Phospholipase C in Photosynthesis and Growth of Maize Seedlings.

Phospholipase C is an enzyme that catalyzes the hydrolysis of glycerophospholipids and can be classified as phosphoinositide-specific PLC (PI-PLC) and non-specific PLC (NPC), depending on its hydrolytic substrate. In maize, the function of phospholipase C has not been well characterized. In this study, the phospholipase C inhibitor neomycin sulfate (NS, 100 mM) was applied to maize seedlings to investigate the function of maize PLC. Under the treatment of neomycin sulfate, the growth and development of maize seedlings were impaired, and the leaves were gradually etiolated and wilted. The analysis of physiological and biochemical parameters revealed that inhibition of phospholipase C affected photosynthesis, photosynthetic pigment accumulation, carbon metabolism and the stability of the cell membrane. High-throughput RNA-seq was conducted, and differentially expressed genes (DEGS) were found significantly enriched in photosynthesis and carbon metabolism pathways. When phospholipase C activity was inhibited, the expression of genes related to photosynthetic pigment accumulation was decreased, which led to lowered chlorophyll. Most of the genes related to PSI, PSII and TCA cycles were down-regulated and the net photosynthesis was decreased. Meanwhile, genes related to starch and sucrose metabolism, the pentose phosphate pathway and the glycolysis/gluconeogenesis pathway were up-regulated, which explained the reduction of starch and total soluble sugar content in the leaves of maize seedlings. These findings suggest that phospholipase C plays a key role in photosynthesis and the growth and development of maize seedlings.

Design and Development of Neomycin Sulfate Gel Loaded with Solid Lipid Nanoparticles for Buccal Mucosal Wound Healing.

Drug administration to the wound site is a potential method for wound healing. The drug retention duration should be extended, and drug permeability through the buccal mucosal layer should be regulated. Oral wounds can be caused by inflammation, ulcers, trauma, or pathological lesions; if these wounds are not treated properly, they can lead to pain, infection, and subsequent undesirable scarring. This study aimed to develop Kolliphor-407 P-based gel containing neomycin sulfate (NES) loaded in solid lipid nanoparticles (SLNs) and enhance the antimicrobial activity. By considering lipid concentrations and achieving the lowest particle size (Y1) and maximum entrapment (EE-Y2) effectiveness, the formulation of NES-SLN was optimized using the Box-Behnken design. For the selected responses, 17 runs were formulated (as anticipated by the Design-Expert software) and evaluated accordingly. The optimized formulation could achieve a particle size of 196.25 and EE of 89.27% and was further utilized to prepare the gel formulation. The NES-SLN-G formula was discovered to have a smooth, homogeneous structure and good mechanical and rheological properties. After 24 h of treatment, NES-SLN-G showed a regulated in vitro drug release pattern, excellent ex vivo permeability, and increased in vitro antibacterial activity. These findings indicate the potential application of NES-SLN-loaded gels as a promising formulation for buccal mucosal wound healing.

The polysaccharides from the fruits of Lycium barbarum L. confer anti-diabetic effect by regulating gut microbiota and intestinal barrier.

The antidiabetic effect and potential mechanisms of the polysaccharides from the fruits of Lycium barbarum L. (LBPs) by the mouse model of high-fat diet/streptozotocin-induced diabetes were investigated. Six-week oral administration of LBPs (200 mg/kg/day) resulted in improvement in the levels of fasting blood glucose (13.51% decrease) and glycated hemoglobin and ß-cell function in diabetic mice, and simultaneously induced a 3.3-fold increment in one taxon belonging to genus Allobaculum in gut bacterial community. The experiments of fecal microbiota transplantation and antibiotics treatment confirmed that the LBPs-mediated gut microbiota participated in the glycemic control of the diabetes management. Moreover, LBPs intervention guarded the intestinal barrier function via upregulating the expression of zonula occludens 1 both in vivo (analyzing the gut permeability in diabetic mice) and in vitro (using intestinal-like Caco-2/RAW264.7 cells co-culture inflammation model). Collectively, our study showed that LBPs could confer anti-diabetic effect through modifying gut microbiota and intestinal barrier.

Gut microbiota and its role in stress-induced hyperalgesia: Gender-specific responses linked to different changes in serum metabolites.

Long-term stress causes hyperalgesia; and there are gender differences in the mechanism of pain in male and female individuals. The role of gut microbiota in pain has also been verified. However, whether gut microbiota plays a role in hyperalgesia caused by chronic restraint stress (CRS) with gender differences has not been explored. This study investigated the role of gut microbiota in CRS-induced hyperalgesia gender-specifically through 16 S ribosomal RNA (16 S rRNA) gene sequencing and untargeted metabolomic analysis using liquid chromatography-mass spectrometry (LC-MS). The study found that both male and female mice experienced hyperalgesia after CRS and antibiotic treatment. 16 S rRNA gene sequencing reveals gender differences in the fecal microbiota induced by CRS. The pain threshold decreased after transplanting the fecal microbiota from the male and female CRS group to the corresponding pseudo-germ-free mice. In addition, this study detected gender differences in the host gut microbiota and serum metabolism induced by fecal microbiota transplantation (FMT). Specifically, the different serum metabolites between the pseudo-germ-free mice receiving FMT from the CRS group and those from the control group were mainly involved in bile secretion and steroid hormone biosynthesis for male mice, and in taurine and hypotaurine metabolism and tryptophan metabolism for female mice. In summary, the gut microbiota participates in stress-induced hyperalgesia (SIH) with gender differences by influencing the host's gut microbiota composition and serum metabolism. Therefore, our findings provided insights into developing novel gut microbiota-associated drugs for the management of gender-specific SIH.

Improved Neomycin Sulfate Potency in Streptomyces fradiae Using Atmospheric and Room Temperature Plasma (ARTP) Mutagenesis and Fermentation Medium Optimization.

To improve the screening efficiency of high-yield neomycin sulfate (NM) Streptomyces fradiae strains after mutagenesis, a high-throughput screening method using streptomycin resistance prescreening (8 µg/mL) and a 24-deep well plates/microplate reader (trypan blue spectrophotometry) rescreening strategy was developed. Using this approach, we identified a high-producing NM mutant strain, Sf6-2, via six rounds of atmospheric and room temperature plasma (ARTP) mutagenesis and screening. The mutant displayed a NM potency of 7780 ± 110 U/mL and remarkably stable genetic properties over six generations. Furthermore, the key components (soluble starch, peptone, and (NH4)2SO4) affecting NM potency in fermentation medium were selected using Plackett-Burman and optimized by Box-Behnken designs. Finally, the NM potency of Sf6-2 was increased to 10,849 ± 141 U/mL at the optimal concentration of each factor (73.98 g/L, 9.23 g/L, and 5.99 g/L, respectively), and it exhibited about a 40% and 100% enhancement when compared with before optimization conditions and the wild-type strain, respectively. In this study, we provide a new S. fradiae NM production strategy and generate valuable insights for the breeding and screening of other microorganisms.

Pharmacokinetics of neomycin sulfate after intravenous and oral administrations in swine.

The aminoglycoside antibiotic neomycin, which is used to treat external or internal bacterial infections, is primarily administered in veterinary medicine as a sulfate salt. However, no information is available on the pharmacokinetic characteristics and absolute availability of neomycin sulfate after intravenous (i.v.) and oral (p.o.) administrations in swine. Here, these parameters were studied in swine after i.v. and p.o. doses of single 15 mg/kg body weight doses. The blood samples were assessed using ultra-high-performance liquid chromatography-tandem mass/mass spectrometry (UPLC-MS/MS) and pharmacokinetic parameters were analyzed using a non-compartmental model. In swine, after the p.o. administration, the elimination half-life, mean residue time from t0 to the last collection point, mean maximum concentration, mean time to reach maximum concentration and area under concentration-time curve from t0 to the last collection point values were 12.43 ± 7.63 h, 10.25 ± 4.32 h, 0.11 ± 0.07 µg/ml, 1.92 ± 0.97 h and 1.23 ± 0.78 µg·h/ml, respectively, whereas after the i.v. administration, the values were 5.87 ± 1.12 h, 6.07 ± 0.49 h, 15.80 ± 1.32 µg/ml, 0.30 ± 0.38 h and 76.14 ± 3.52 µg·h/ml, respectively. The absolute bioavailability of neomycin sulfate B was 4.84%±0.03.

Colorimetric detection of neomycin sulfate in tilapia based on plasmonic core-shell Au@PVP nanoparticles.

The rapid colorimetric detection of neomycin sulfate has been achieved using polyvinyl pyrrolidone shell coated gold nanoparticle (Au@PVP NPs) sol. We also observed that, the aggregation of Au@PVP NPs, possibly caused by the hydrogen bonds formed between neomycin sulfate and PVP shell, generates a new surface plasmon resonance absorption in the wavelength of 600 ~ 700 nm. The proposed method showed an excellent performance towards the determination of neomycin sulfate in wide linear range from 0.01 ~ 10 µM with a correlation coefficient of 0.99 and low detection limit of 1 nM. After extracted with trichloroacetic acid and treated with hot chloroform, neomycin sulfate in the tilapia fish samples was detected with satisfied recovery. Additionally, the high selectivity of Au@PVP NPs sol towards neomycin sulfate has been achieved even in presence of common interfering agents. This method has the advantages of high sensitivity, rapidity, specificity, low cost and no complicated pretreatment procedure.

Transition of Determination Method of Potency of Neomycin Sulfate from Microbiological Assay to HPLC-PAD / 中国药学杂志

OBJECTIVE: To establish a high performance liquid chromatography combined with pulsed amperometric detection(HPLC-PAD)method for determination of potency of neomycin sulfate. METHODS: An improved HPLC-PAD method from EP method for determination of the content and related substances of neomycin sulfate was established and validated. The study of impurity profile of neomycin sulfate was completed by LC-IT-TOF method with the help of on-line desalination using a suppressor; and the main components in neomycin sulfate were clarified combining the RESULTS of impurity profile and minimum inhibitory concentrations of the main components and impurities. The semi-preparative liquid chromatography-evaporative light scattering detector(ELSD) was self-assembled, highly purified neomycin B and neomycin C were prepared and their structural confirmation was also conducted. The contents of highly purified neomycin B and neomycin C were determined by means of mass balance method. The potencies of highly purified neomycin B and neomycin C were determined by three-dose antibiotic microbial assay and the conversion factors between contents of neomycin B and neomycin C and their potencies were calculated separately and then a formula for the calculation of potency of neomycin sulfate from the content of main components of neomycin B and neomycin C was obtained.At last, a verification experiment for the accuracy of the conversion factor and the formula were designed and a serial of tests were carried out to investigate the interaction and the verification for the actual sample. RESULTS: The improved HPLC-PAD method was superior to the European Pharmacopoeia method in the separation ability and stability, and was suitable for accurate quantification of various components of neomycin sulfate and related substance inspection. The successful removal of trifluoroacetic acid in the mobile phase by the technology of desalination on-line using a suppressor broke a new way for the study of impurity profile of aminoglycoside such as neomycin sulfate. Combining the impurity profile with the RESULTS of MIC it was clarified that the main activity components of neomycin sulfate were neomycin B and neomycin C. Highly purified neomycin B and neomycin C were successfully prepared. A conversion factor for the transition from potency to purity of neomycin sulfate was obtained through experiments and calculations and was verified successfully. CONCLUSION: It is feasible to replace the microbial assay by HPLC-PAD method for determining the potency of neomycin sulfate.

Quantification of neomycin in rubella vaccine by off/on metal ion mediated photoluminescence from functionalized graphene quantum dots.

The determination of neomycin sulfate was made using photoluminescent amino-functionalized graphene quantum dots (obtained from hydro-exfoliation of a mixture of citric acid and glutathione). From the several ions tested, Fe3+ was the best mediator to enable an off/on photoluminescence effect used for quantification. The mediation of Fe3+ was found to be crucial as it is responsible for the photoluminescence quenching effect, due to the interaction with quantum dots surface, also having large affinity towards neomycin that removes Fe3+ from the surface of GQDs, consequently, promoting restoration of the original nanomaterial photoluminescence. Such signal restoration was proportional to the neomycin sulfate concentration added. The linearized analytical response covered three orders of magnitude (10-7 to 10-5 mol L-1). The proposed method is an alternative to those requiring labor-intensive procedures for chemical the derivatization of neomycin (due to the lack of chromophore groups in aminoglycosides). The method was successfully tested in the analysis of rubella vaccine containing trace residues of neomycin and in pharmaceutical compositions containing neomycin sulfate after solid phase extraction using an aminoglycoside imprinted polymer to improve selectivity in determinations.

Formulation and Quantitative Analysis of Betamethasone Valerate and Neomycin Sulfate Cream by High Performance Liquid Chromatography and Spectrophotometry.

BACKGROUND: Combination of betamethasone valerate and neomycin sulfate in cream is used to treat the itching, redness, dryness, scaling, inflammation and discomfort of various skin conditions caused by infection. The combination of active ingredients has side effects which can cause dry skin, thinning of the skin, hypertrichosis, and stretch marks. AIM: The purpose of this study was to make a formula containing vitamin E and quantitative analysis of betamethasone valerate and neomycin sulfate in creams using High Performance Liquid Chromatography and Spectrophotometry Area Under Curve methods. METHODS: Cream preparation includes smelting and emulsification processes, with oil phases namely stearic acid and vitamin E as well as water phases are glycerin, sodium bi-borate, tri-ethanolamine. Physical tests for the cream were organoleptic, homogeneity, pH, evaluation of dispersion, and viscosity. HPLC analysis for cream was carried out using C18 column, and the mobile phase of methanol: water with comparison optimization beforehand. Spectrophotometry analysis for cream was carried out using application of Area Under Curves methods. RESULTS: The formula used was betamethasone valerate 5 mg, neomycin sulfate 25 mg, stearic acid, glycerin, sodium bi-borate, tri-ethanolamine, vitamin E and distilled water. The obtained cream was in the form of semi-solid, odorless, white (colorless), homogeneous, pH 7, the dispersion power of 500 mg cream is 4.0-4.3 cm in diameter and viscosity is 7500 Cps. Analysis of the determination of the levels of the two components was carried out by the HPLC method C-18 column with the mobile phase of methanol: water (90: 10). Betamethasone valerate and neomycin sulfate levels in formulas made HPLC methods were 94.15%, and 136.56%, respectively and using AUC spectrophotometry methods were 107.98% and 94.81%. CONCLUSION: Cream that made by new formula with vitamin E shows good result in physical evaluation. HPLC methods with a mobile phase of methanol: water (90:10) was not recommended, while the AUC spectrophotometry method shows the valid result of quantitative analysis of betamethasone valerate and neomycin sulfate in cream.

Determination of the content and related substances of neomycin sulfate by HPLC combined with pulsed amperometric detection / 中国药科大学学报

@#A novel method was developed for the content assay and related substances determination of neomycin sulfate by high performance liquid chromatography combined with pulsed amperometric detection(HPLC-PAD). The HPLC was performed on Thermo AcclaimTMAmG C18(4. 6 mm×150 mm, 3 μm). The mobile phase consisted of aqueous solution with 2% trifluoroacetic acid containing 0. 01% pentafluoropropionic acid and 0. 6%NaOH. The pulsed amperometric detector was operated with aquadruple-potential waveform for the detection. Neomycin B, Neomycin C and thirteen related substances were adequately separated by the established HPLC conditions. The limits of detection(LOD)and quantification(LOQ)of neomycin B and neomycin C were both 1. 75 ng and 3. 5 ng, respectively. Good linearities of neomycin B and neomycin C were found in their respective ranges which their correlation coefficients were greater than 0. 998 5. The established method is characterized by high specificity, sensitivity and wide range of linearity which has a good application prospect and provides the basis for improving the standard and quality control of neomycin sulfate.

Desenvolvimento de método colorimétrico para determinação de sulfato de neomicina empregando os conceitos de qualidade por design analítico (AQbD) / Development of a colorimetric method for determination of neomycin sulphate using the concepts of quality by analytical design (AQbD)

Para efetivamente tratar uma infecção, é necessário que o antibiótico possua atividade antimicrobiana adequada e seja capaz de inibir o crescimento do microrganismo patogênico. O doseamento microbiológico é uma metodologia indicada para a análise do antimicrobiano de forma simples, quando comparado com outras metodologias. A Food and Drug Administration (FDA) tem encorajado uma abordagem proativa para introduzir inovações e benefícios associados ao processo de produção farmacêutica. A Qualidade por Design Analítico (AQbD) ajuda no desenvolvimento de métodos analíticos robustos e de baixo custo, que são aplicáveis durante todo ciclo de vida do produto. Os métodos microbiológicos tradicionais, de forma geral, apresentam baixa reprodutibilidade e alta incerteza. Desta forma, justifica-se o desenvolvimento de métodos microbiológicos alternativos para a análise de antimicrobianos empregando-se os conceitos de Qualidade por Design Analítico, com a finalidade de melhorar a reprodutibilidade e reduzir a incerteza final. O objetivo deste trabalho foi aplicar o conceito de Qualidade por Design Analítico (AQbD) no desenvolvimento de método colorimétrico para análise de sulfato de neomicina. O sulfato de neomicina é um antimicrobiano aminoglicosídeo amplamente empregado no tratamento de infecções cutâneas ou mucosas, tais como queimaduras, úlceras, e dermatites infecciosas. Métodos cromatográficos como a cromatografia líquida de alta eficiência em fase reversa, de pareamento iônico ou cromatografia iônica com derivatização (pré ou pós-coluna) são utilizados para a análise de aminoglicosídeos, inclusive sulfato de neomicina. Contudo, de acordo com as farmacopeias, o método microbiológico é o método analítico de escolha para a análise de sulfato de neomicina e outros aminoglicosídeos. A análise colorimétrica é um método amplamente utilizado para a detecção e quantificação de diferentes substâncias, incluindo o crescimento microbiano em estudos de eficácia terapêutica. Neste trabalho, propomos o uso de resazurina como marcador colorimétrico. O indicador sofre uma reação de oxido-redução na qual altera a coloração em resposta à redução química resultante do crescimento celular. O uso de microplacas para a análise colorimétrica é uma alternativa ao método realizado em tubos de ensaio. Uma alternativa ao uso de espectrofotômetros para a análise colorimétrica é o uso de aparelhos smartphones, pois são equipados com CPUs rápidas, câmeras de alta resolução e sensores de imagem. O processamento da imagem captada pela câmera do dispositivo é utilizado como um analisador colorimétrico. Portanto, a aplicação dos conceitos de Qualidade por Design Analítico (AQbD) possibilitou o desenvolvimento racional de método microbiológico colorimétrico para análise de sulfato de neomicina

o effectively treat an infection, the antibiotic must have adequate antimicrobial activity and be capable of inhibiting the growth of the pathogenic microorganism. The microbiological assay is an indicated methodology for the analysis of the antimicrobial in a simple way, when compared with other methodologies. The Food and Drug Administration (FDA) has encouraged a proactive approach to introducing innovations and benefits associated with the pharmaceutical production process. Analytical Design Quality (AQbD) assists in the development of robust, low cost analytical methods that are applicable throughout the product life cycle. Traditional microbiological methods, in general, have low reproducibility and high uncertainty. Thus, it is justified the development of alternative microbiological methods for the analysis of antimicrobials using the concepts of Quality by Analytical Design, in order to improve reproducibility and reduce final uncertainty. The objective of this work was to apply the concept of Quality by Analytical Design (AQbD) in the development of a colorimetric method for the analysis of neomycin sulfate. Neomycin Sulfate is an aminoglycoside antimicrobial widely used in the treatment of cutaneous or mucosal infections, such as burns, ulcers, and infectious dermatitis. Chromatographic methods such as reverse phase high performance liquid chromatography, ion-pairing or ion chromatography with derivatization (pre or post-column) are used for the analysis of aminoglycosides, including neomycin sulfate. However, according to pharmacopoeias, the microbiological method is the analytical method of choice for the analysis of neomycin sulphate and other aminoglycosides. Colorimetric analysis is a widely used method for the detection and quantification of different substances, including microbial growth in studies of therapeutic efficacy. In this work, we propose the use of resazurin as a colorimetric marker. The indicator undergoes an oxidation-reduction reaction in which it alters the coloration in response to the chemical reduction resulting from cell growth. The use of microplates for colorimetric analysis is an alternative to the method carried out in test tubes. An alternative to the use of spectrophotometers for colorimetric analysis is the use of smartphones because they are equipped with fast CPUs, high resolution cameras and image sensors. The image processing captured by the device's camera is used as a colorimetric analyzer. Therefore, the application of the concepts of Quality by Analytical Design (AQbD) allowed the rational development of a microbiological colorimetric method for analysis of neomycin sulfate

GC-MS-based metabolomics analysis reveals L-aspartate enhances the antibiotic sensitivity of neomycin sulfate-resistant Aeromonas hydrophila.

Neomycin sulfate, a kind of drug known as aminoglycoside antibiotic, can be used to treat external or internal bacterial infections. However, there are increasing signs that antibiotics use in aquaculture may have a long-term and permanent potential to select for antibiotic-resistant bacteria in the aquatic environment. In the present study, we aimed to identify key metabolic biomarker whose abundance is correlated with neomycin sulfate resistance in A. hydrophila by gas chromatography-mass spectrometry (GC-MS). Through bioinformatics analysis, L-aspartate was identified as the most crucial biomarker in neomycin sulfate-resistant A. hydrophila and a potential modulator of neomycin sulfate resistance. It was validated as a synergist that incubation of neomycin sulfate-susceptible or -resistant A. hydrophila with exogenous L-aspartate sensitized the bacteria to neomycin sulfate in vitro assay. Moreover, L-aspartate also significantly improved the bactericidal efficacy of neomycin sulfate in Carassius auratus, and increased the survival rate of fish after A. hydrophila challenge. This study presents a novel approach in fighting against antibiotic-resistant pathogens through exploration of antibiotic-resistant biomarkers.

Monitoring of neomycin sulfate antibiotic in microbial fuel cells.

Indirect detection and quantification of the neomycin sulfate antibiotic was accomplished in microbial fuel cells. Performance of the microbial fuel cells was examined on the basis of the following parameters; voltage generation, power density, current density and coulombic efficiencies. Removal of neomycin sulfate was monitored using LC-MS/MS in parallel with chemical oxygen demand and total carbohydrate removal. While neomycin sulfate was partially degraded, microbial fuel cell performance appeared to be affected and eventually inhibited by neomycin sulfate on a concentration-based fashion. In order to further examine the neomycin sulfate bio-sensing activity of the microbial fuel cell, a computational chemistry approach was used to obtain the information about the highest occupied molecular orbital-lowest unoccupied molecular orbital energy values of outer electron orbitals, their distribution, and ionization potentials (IPs). The results showed that electroactive bio-film-based MFCs can be used for sensitive detection of neomycin sulfate found in wastewaters.