Degradation of ciprofloxacin hydrochloride in a multiphase mixed system by subaquatic gas-liquid discharge plasma

In recent years, antibiotic pollution has become a serious threat to human health. In this study, a gas-liquid discharge plasma is developed to degrade ciprofloxacin hydrochloride in a multiphase mixed system containing inorganic and organic impurities. The discharge characteristics are analyzed by diagnosing the applied voltage and discharge current waveforms, as well as the optical emission spectra. The work investigates how degradation efficiency is affected by applied voltage, gas flow rate, treatment time, initial concentration as well as the addition of γ-Al_(2)O_(3) pellets and peanut straw. After 70 min, the degradation efficiency of ciprofloxacin hydrochloride in the multiphase mixed system reached 99.6%. Its removal efficiency increases as the initial concentration decreases and the applied voltage increases. Besides, there is still a good degradation efficiency of ciprofloxacin hydrochloride with the addition of peanut straw.The degradation mechanism of ciprofloxacin hydrochloride is investigated through the analysis of degraded intermediates and reactive species.

Oxidation of ciprofloxacin by the synergistic effect of DBD plasma and persulfate:reactive species and influencing factors analysis

A synergistic system of water falling film dielectric barrier discharge(DBD)plasma and persulfate(PS)was set up and used for oxidizing ciprofloxacin(CIP)in water.Results of reactive species formation in the DBD-only system as well as the DBD–PS system verified the PS activation in the DBD system.Influencing factors on CIP degradation and the degradation process were also been studied.The obtained results showed that the presence of PS could greatly improve the degradation and mineralization of CIP and that the degradation efficiency could reach 97.73%after only 40 min treatment with 4 m M PS addition.The increase of PS concentration,the lower CIP concentration,the acidic solution p H and the addition of metal ions(Fe^(2+)and Cu^(2+))enhanced the CIP degradation,while the existence of Cl^(-)and HCO_(3)^(-)had a negative effect.The experiments related to scavenger addition confirmed the contribution of the main reactive species to the CIP oxidation.Three probable degradation pathways were proposed by analyzing the inorganic ions and organic byproducts formed during the CIP degradation.The toxicity evaluation results of the CIP and its intermediates confirmed the effectiveness of the DBD–PS synergistic system.

Preparation of sodium alginate gel microspheres catalysts and its high catalytic performance for treatment of ciprofloxacin wastewater

The discharge of the antibiotic wastewater has increased dramatically in our country with the development of medical science and wide application of antibiotic,resulting in serious harm to human body and ecological environment.In this work,ciprofloxacin(CIP)was selected as one of typical antibiotics and heterogeneous Fenton-like catalysts were prepared for the treatment of ciprofloxacin wastewater.The sodium alginate(SA)gel microspheres catalysts were prepared by polymerization method using double metal ions of Fe^(3+)and Mn^(2+)as cross-linking agents.Preparation conditions such as metal ions concentration,mass fraction of SA,polymerization temperature and dual-metal ions as crosslinking agent were optimized.Moreover,the effects of operating conditions such as initial concentration of CIP,pH value and catalyst dosage on CIP removal were studied.The kinetic equation showed that the effect of the initial concentration of CIP on the degradation rate was in line with second-order kinetics,and the effects of catalyst dosage and pH value on the degradation rate of CIP were in line with first-order kinetics.The SA gel microspheres catalysts prepared by dual-metal ions exhibited a high CIP removal and showed a good reusability after six recycles.The SA gel microspheres catalysts with an easy recovery performance provided an economical and efficient method for the removal of antibiotics in the future.

Recurrent ciprofloxacin induced hypoglycemia in a non-diabetic patient:A case report

BACKGROUND Fluoroquinolones are a class of broad-spectrum antimicrobials used for various bacterial infections.Frequent use of fluoroquinolones has been questioned due to severe associated adverse effects,including dysglycemia(hypoglycemia or hyperglycemia)due to an alternation in glucose metabolism.Recent clinical trials showed the association of poor clinical outcomes with hypoglycemia in critically ill patients without diabetes.Many predisposing factors worsen fluoroquinolone-induced hypoglycemia,including diabetes,concomitant medication use like sulfonylureas or insulin,renal disease,and the elderly.CASE SUMMARY We report a case of recurrent hypoglycemia after ciprofloxacin initiation for a 71-year-old,non-diabetic,critically ill patient despite the presence of total parenteral nutrition and nasogastric tube feeding.The adverse drug reaction probability(Naranjo)scale was completed with a probable adverse drug reaction.The hypoglycemia resolved entirely after ciprofloxacin discontinuation.CONCLUSION Although ciprofloxacin-induced hypoglycemia is rare,special consideration is needed for the elderly due to their higher susceptibility to adverse side effects.

CdS/Nb_(2)O_(5)异质结材料的制备、表征及光催化降解环丙沙星研究

采用水热法制备了CdS/Nb_(2)O_(5)纳米复合材料,利用X-射线衍射光谱(XRD)、透射电镜(TEM)、红外光谱(FT-IR)、X-射线光电子能谱(XPS)和紫外-可见漫反射(UV-Vis DRS)对制备的材料进行表征。通过可见光下降解环丙沙星评价材料的光催化活性。结果表明,制备的CdS/Nb_(2)O_(5)纳米复合材料由CdS纳米颗粒分散于Nb_(2)O_(5)纳米笼表面,二者形成紧密的Ⅱ型异质结;CdS的引入增强了Nb_(2)O_(5)的可见光吸收性能,同时提高了光生载流子的分离效率;当CdS的含量为15%时,CdS/Nb_(2)O_(5)可在60 min实现环丙沙星的高效降解,其反应速率常数是CdS的7.5倍,Nb_(2)O_(5)的20倍,空穴是该降解反应的主要活性物种,研究结果为抗生素废水的高效治理提供了一条新思路。

聚酪氨酸/纳米金电化学传感器检测水环境中环丙沙星

利用聚酪氨酸有机薄膜负载金纳米粒子作为检测环丙沙星的基底材料,制备了p-Tyr/AuNP s/Au电化学传感器,对环丙沙星(CFX)表现出良好的电催化性能。用扫描电镜对材料的形貌进行了表征,CFX在该材料表面的反应为二电子转移的受吸附控制的过程。用单因素实验对L-酪氨酸(L-Tyr)单体的浓度、聚合的扫描圈数、金纳米沉积时间、溶液pH值进行了优化。在最优条件下,在6.60×10^(-7)~1.57×10^(-5)mol·L^(-1),ΔI与环丙沙星的浓度呈良好的线性关系,检出限为3.50×10^(-7)mol·L^(-1)(S/N=3)。该电化学传感器具有良好的重复性、稳定性和抗干扰性,可用于实际水体中环丙沙星的测定,加标回收率为95.7%~103.5%。

改性钨酸铋纳米材料用于六价铬与环丙沙星光催化共降解研究

抗生素与重金属离子常在废水中共存,提高了废水处理难度,因此亟需高效的处理方法实现二者的共降解.在此,通过一种简单的溶剂热法合成了具有氧空位和3D中空结构钨酸铋光催化材料,实现了六价铬和环丙沙星的高效光催化共降解,光催化反应40 min后可将二者降解99%.实验及表征结果表明,氧空位的引入促进了光生载流子的分离与迁移,使得更多的电子和空穴参与氧化还原反应,进而显著提高了光催化共降解效率.同时,结合降解转化产物检测结果,分析了降解机理与路径.本工作为抗生素/重金属共存废水的处理提出了一种可行的高效方法.

KOH活化制备铁基生物质炭及其对四环素和环丙沙星的吸附研究

低代谢程度的抗生素如四环素和环丙沙星会造成较为严重的水体污染,而活性炭对此种污染有一定的吸附作用。活化是改善生物炭吸附特性的主要方法之一。以甘蔗渣为主要研究对象,用KOH为活化剂,以FeCl_(3)·6H 2O为浸渍溶剂,制备了改性生物炭(KFBC),同时制备甘蔗渣生物炭(BC)作为对照。综合多种表征手段分析KOH活化和FeCl_(3)的掺杂对KFBC的结构和理化性质的影响,采用吸附法探究KFBC对溶液中的四环素(TC)或环丙沙星(CIP)的吸附性能和机理。结果表明:KOH活化后会形成更多的碳结构缺陷,影响BC的官能团的种类和数量以及BC的表面电性;FeCl_(3)的掺杂会增强BC的磁性,有利于KFBC的循环利用;吸附反应受pH影响较小,KFBC能够在一个较宽泛的pH范围内进行吸附。KFBC吸附TC或CIP是以化学吸附为主,且是自发、吸热、自由度增加和熵增的过程;KFBC对TC或CIP的理论最大吸附量可达到743和794 mg/g;KFBC的主导机制并非静电吸附,而是以孔隙扩散和π—π作用等为主,氢键和络合作用也发挥了重要作用。

盐酸环丙沙星不同给药途径对牛胃肠炎的治疗效果分析

为探讨对盐酸环丙沙星不同给药途径对牛胃肠炎的治疗效果。按照盐酸环丙沙星不同给药途径将2022年6月—2023年6月期间收治的128例患有胃肠炎的病牛分为口服组、肌肉注射组、静脉注射组以及瓣胃注射组,每组各32例。观察4组病牛治疗效果、纤毛虫总数以及纤毛虫活力。瓣胃注射组的治疗总有效率最高,且与其他3组相比差异有统计学意义(P<0.05)。用药后瓣胃注射组的纤毛虫总数大于其他3组,且纤毛虫活力高于其他3组,差异有统计学意义(P<0.05)。瓣胃注射组不良反应发生率与其他3组对比,差异有统计学意义(P<0.05)。在牛胃肠炎的治疗中,对盐酸环丙沙星采用瓣胃注射法的治疗效果较好,对纤毛虫影响较小且安全性较高,适合在临床上推广。

水中环丙沙星(CPFX)氯化消毒副产物生成潜能分析

该文首次考察了水中环丙沙星在不同氯化条件下多种含碳及含氮消毒副产物(DBPs)的生成情况。试验发现氯化氟喹诺酮抗生素环丙沙星能够生成包括三氯甲烷、三氯乙烷、二氯乙腈、三氯硝基甲烷、三氯丙酮等多种氯代消毒副产物,且氯化时间、加氯量与氯化p H对DBPs的生成具有显著影响。投加不同浓度的Br-能够使氯化过程中以三氯甲烷为主的氯代消毒副产物生成量减少,而溴代消毒副产物生成量增多。试验为抗生素水源水污染的消毒副产物生成提供了理论依据。

复合催化剂S-CuCo_(2)O_(4)的制备及其活化PMS降解CIP性能研究

采用水热法,以硫脲为硫源对CuCo_(2)O_(4)进行硫化处理合成S-CuCo_(2)O_(4),对复合催化剂S-CuCo_(2)O_(4)进行XRD、FT-IR、SEM、XPS、ICP-OES、EPR表征,并考察其活化过一硫酸盐(PMS)降解环丙沙星(ciprofloxacin,CIP)的效果。实验结果表明:成功制备出S-CuCo_(2)O_(4)催化剂,在其表面富含Co(Ⅱ)和Cu(Ⅰ);当催化剂投加量为0.06 g/L、PMS投加量为0.2 g/L、pH=6.4时,复合催化剂S-CuCo_(2)O_(4)在25 min后对CIP的降解效率可达96.8%,降解效果明显优于CuCo_(2)O_(4)、CuCo_(2)S_(4)。自由基淬灭实验和EPR测试表明,SO_(4)^(-)·和^(1)O_(2)是反应体系的主要活性氧物种,其可能的催化机理是:Cu(Ⅰ)和Co(Ⅱ)能直接与PMS反应生成自由基,同时Cu(Ⅰ)能还原Co(Ⅲ)生成Co(Ⅱ),促进Co(Ⅱ)/Co(Ⅲ)循环,催化剂表面存在的氧空位也可与PMS反应生成^(1)O_(2),在活性氧物种的共同作用下CIP被高效降解。复合催化剂S-CuCo_(2)O_(4)在4次循环使用后对CIP的降解效率仍可达93.5%,证明其循环稳定性较好;对其他污染物也有较好的降解效率,具有较好的通用性,在废水处理中具有良好的应用前景。

浒苔生物炭负载纳米零价铁激活过硫酸盐去除水中环丙沙星的研究

以浒苔(Enteromorpha prolifera)生物炭(biochar,BC)为载体,通过液相还原法制备了一种具有较高去除性能的生物炭负载纳米零价铁(nanoscale zero-valent iron,nZVI)nZVI@BC作为过硫酸盐的激活材料,用于去除水中的抗生素环丙沙星(ciprofloxacin,CIP).采用扫描电镜、透射电镜、X射线衍射仪和X射线光电子能谱对材料的表观形貌、粒径、晶型结构和化学形态进行分析.结果表明,BC的负载有效提高了nZVI的分散性,增加了反应活性位点.在BC与Fe的质量比为2:1,nZVI@BC质量浓度为0.6 g·L^(-1),过硫酸盐浓度为2 mmol·L^(-1),CIP质量浓度为10 mg·L^(-1)条件下,60 min内CIP的去除率达91.45%.自由基猝灭和电子顺磁共振结果证明,CIP的去除主要依靠SO_(4)^(-)·,HO·,·O_(2)^(-)和^(1)O_(2)等自由基的强氧化作用,其中·O_(2)^(-)起主要作用.

国产环丙氟哌酸(Ciprofloxacin)体内抗菌作用研究

本文观察了北京、天津研制的两个国产环丙氟哌酸对大肠杆菌、痢疾杆菌、克雷伯氏肺炎杆菌、绿脓杆菌各2株及金黄色葡萄球菌2株感染小鼠的体内抗菌作用。国产环丙氟哌酸对2株金葡菌感染小鼠具有体内抗菌活性,ED_(50)分别为1.54,1.37;1.56,1.60 mg/kg,低于氟哌酸(norfloxacin)的ED_(50)2.78,4.28 mg/kg的结果,是苯唑青霉素(oxacillin)的1/3—1/8。国产环丙氟哌酸对大肠杆菌、痢疾杆菌感染小鼠的体内抗菌作用很强,ED_(50)值在0.026—0.032mg/kg之间,氟哌酸的ED_(50)值是前者的5—10倍,头孢唑啉(cefazolin)及氨苄青霉素(ampicillin)的ED_(50)值是环丙氟哌酸ED_(50)值的近百倍。环丙氟哌酸对克雷伯氏肺炎杆菌感染小鼠的ED_(50)值为0.115与0.158mg/kg,明显低于头孢唑啉相应的ED_(50)值2.16与2.81mg/kg。环丙氟哌酸对绿脓杆菌的ED_(50)低于1mg/kg,明显低于庆大霉素的ED_(50),后者的ED_(50)为3.37—4.42mg/kg。国产环丙氟哌酸具有广谱体内抗菌活性,对5种临床致病菌ED_(50)资料统计分析表明,环丙氟哌酸的体内抗菌作用明显优于氨苄青霉素、头孢唑啉、庆大霉素及苯唑青霉素(p<0.01)。两个国产环丙氟哌酸的体内抗菌作用相似,两个药的ED_(50)值差异不显著。

壳聚糖/磁性生物炭复合物的制备及其对环丙沙星的吸附性能

本文以芦苇生物质和FeCl_(3)·6H_(2)O为原料,采用浸渍-热解法,控制浸渍比率、热解温度和热解时间制备磁性生物炭(Biochar, MB),再与壳聚糖(Chitosan, CTS)复合,制备了壳聚糖/磁性生物炭复合物(Magnetic biochar, CMB)。利用田口分析方法,以环丙沙星(Ciprofloxacin, CIP)为目标物,以吸附容量为评价指标,优化了CMB的制备条件。使用傅里叶变换红外光谱(FTIR)、X射线衍射分析(XRD)、X射线光电子能谱(XPS)、扫描电镜(SEM)、振动样品磁强计(VSM)和全自动比表面及孔隙度分析仪(BET)对其结构进行了表征。研究了CMB对CIP的吸附动力学和吸附热力学。结果表明,CMB的最佳制备条件为浸渍比率1∶3、热解温度800℃、热解时间4 h,以柠檬酸为交联剂、MB与CTS的质量比5∶1。CMB对CIP的吸附更符合Avrami模型和拟二级动力学模型,吸附过程可能是膜扩散和颗粒内扩散共同作用的结果。Freundlich吸附等温方程能较好地描述CMB对CIP的吸附行为。热力学参数表明,CMB对CIP的吸附是一个自发的吸热反应。

造纸污泥生物炭的制备及其对环丙沙星的吸附

采用化学共沉淀法将高铁酸镍(NiFe_(2)O_(4))负载到造纸污泥生物炭上,制备出一种磁性镍铁氧体/造纸污泥生物炭(NiFe_(2)O_(4)/AC)吸附剂,研究其吸附废水中抗生素环丙沙星(CIP)的有效性,用BET、XRD、SEM、VSM、XPS等表征了材料的结构、形貌、磁性能等性质,研究了生物炭吸附环丙沙星(CIP)的影响因素、吸附等温线和吸附动力学。结果表明,在温度为25℃、pH为6、CIP初始浓度为300mg·L^(-1)、生物炭投加量为0.4g·L^(-1)、吸附时间600min时,吸附量高达600.19mg·g^(-1)。实验数据符合准一级动力学和Langmuir模型,表明其吸附过程是一个单层的物理吸附过程。同时,外加磁场吸附剂可从溶液中分离,在抗生素废水处理中具有潜在的应用前景。

环丙沙星(ciprofloxacin)在鸡蛋中残留的研究

应用高效液相色谱法(HPLC)检测了鸡蛋中环丙沙星的残留.鸡蛋经乙腈溶液提取,提取液真空干燥后用流动相溶解.以0.015 mol/L四丁基溴化铵/乙腈(94/6,V/V)作流动相,用SymmetryC18柱(5 μm,3.9 mm×150 mm),在激发波长280 nm、发射波长455 nm处,用荧光检测器检测.将环丙沙星以0.05、0.50、1.00 mg/kg分别添加到空白鸡蛋样品中,测得鸡蛋样品中环丙沙星的回收率分别为(82.2±6.8)%、(84.5±5.9)%、(87.9±4.7)%,相对标准差均低于8.3%.用该方法测定鸡蛋中环丙沙星的最低检测限为0.01 mg/kg.各试验组产蛋鸡给药剂量分别按10.0、20.0mg/kg(体质量)内服环丙沙星水溶液,每天给药1次,连续5 d.停药后鸡蛋中环丙沙星残留消除缓慢;休药8～9 d时,鸡蛋中环丙沙星残留量低于0.03mg/kg;休药9～10 d时,鸡蛋中环丙沙星残留量均低于最低检测限(0.01 mg/kg);且随着环丙沙星给药剂量的增大,环丙沙星在鸡蛋中的残留量也相应增大.

Preparation, Characterization and in Vitro Release of Ciprofloxacin Polylactic Acid Microspheres

Aim Ciprofloxacin polylactic acid microspheres (CFX-PLA-MS) were preparedusing solvent evaporation method from a solid-in-oil-in-water emulsion system. Methods Orthogonalexperiment was used to optimize the method of CFX-PLA-MS preparation. Microspheres werecharacterized in terms of morphology, size, encapsulation efficiency, drug loading and in vitro drugrelease. Results The physical state of CFX-PLA-MS was determined by scanning electron microscopy(SEM) and differential scanning calorimetry (DSC) . Microspheres formed were spherical with smoothsurfaces. Drug was enveloped in microspheres without mixing physically with PLA. The averageparticle size was 280.80 ± 0.15 μm, with over 90% of microspheres falling in the range of 250 -390 μm. The encapsulation efficiency was 65.8% ± 0.58% and the drug loading was 34.1% ± 0.51% .In vitro release study revealed a profile of sustained release of Ciprofloxacin from CFX-PLA-MS. Theaccumulated release percentage and half-life (T_(1/2) of Ciprofloxacin microspheres were 84.0% in53.2 h, and 31.9 h, respectively. Higuchi equation was Q= -0.0043 + 0.003 9 t^(1/2), r = 0.9941.Conclusion Ciprofloxacin microspheres have been successfully prepared and sustained release of CFXfrom microspheres is achieved.

锰掺杂生物炭强化环丙沙星吸附性能及机制研究

虽然锰掺杂生物炭对水中污染物具有优良的吸附性能,但是锰掺杂生物炭吸附剂物理化学特性与其对污染物的吸附性能之间的相关性仍不清楚。基于此,本研究以MnCl_(2)、玉米秸秆为原料,通过化学浸渍的方法,在300、500和800℃下制备锰掺杂生物炭(分别记为BC_(Mn)-300、BC_(Mn)-500、BC_(Mn)-800),探究不同吸附材料结构和性质差异及其对环丙沙星(CIP)的吸附作用机制。通过电镜扫描、比表面积分析仪、傅里叶变换红外光谱分析仪、拉曼光谱仪和X射线光电子能谱仪等对锰掺杂生物炭进行结构表征分析,发现当煅烧温度从300℃升至800℃时,O/C值从0.66降至0.17,(O+N)/C值从0.7降至0.19,而拉曼光谱中D峰和G峰比值从0.527升至1.010。吸附实验结果发现,锰掺杂生物炭对CIP的吸附性能均高于未掺杂锰生物炭,且随着煅烧温度的升高,CIP的吸附性能逐渐增强。锰掺杂生物炭对CIP的吸附机制主要包括氢键作用、孔填充、疏水作用以及π-π相互作用。构效分析发现,比表面积、总孔体积、ID/IG、C-C、C=O和MnO_(2)的含量均与吸附性能呈正相关,-OH与吸附性能无明显相关性,平均孔径、O/C、(O+N)/C、C-O和MnO的含量均与吸附性能呈负相关。研究显示,锰掺杂生物炭煅烧温度的提高,使其比表面积和孔体积增大,疏水性增强,极性减弱,具有更多的缺陷结构,锰掺杂生物炭的吸附性能取决于不同理化性质的协同作用。该研究结果可为强化CIP去除的定向结构调控、定制化生物炭材料制备提供理论基础。

Bi-MOF衍生的中空BiOBr纳米棒用于高效光催化降解环丙沙星

随着抗生素使用量的不断增加,抗生素引起的水污染日益严重,需要一种可行的解决方案来修复含有抗生素的废水.以Bi-MOF(CAU-17)为模板,制备中空BiOBr纳米棒(hBOB)用于高效光催化降解环丙沙星(CIP).与BiOBr纳米片(sBOB)相比,hBOB具有更大的比表面积和更高的电荷分离效率.在模拟太阳光下30 min的降解效率达到92.5%,降解速率常数是sBOB的2.5倍.通过固体漫反射(DRS)、荧光(PL)、光电流(I-t)、阻抗(EIS)等表征分析光降解能力增强的原因.结果表明多孔结构和纳米片组装的存在缩短了载流子的扩散距离,有利于光生载流子的分离和转移,因此hBOB具有良好的去除CIP的能力.此外,还利用莫特肖特基测试(M-S)和电子自旋共振(ESR)表征研究了光催化降解CIP的机理.

CuBi_(2)O_(4)/Bi_(2)WO_(6)Z型异质结用于光电类芬顿体系下高效降解环丙沙星

针对目前水环境中抗生素污染严重的问题,使用简单的溶剂热法制备了CuBi_(2)O_(4)/Bi_(2)WO_(6)(CBWO)Z型异质结催化剂.扫描电子显微镜分析结果表明,其结构为棒状和纳米片状.能量色散元素图谱显示,Cu,W,Bi和O元素均匀分散在CBWO-60中;使用X射线衍射和傅里叶变换红外光谱探究了催化剂的晶体结构和化学键、官能团组成;BET表征结果证明,CBWO-60具有较高的比表面积.X射线光电子能谱(XPS)证明Cu^(+)和Cu^(2+)共存,促进了芬顿(Fenton)反应的循环进行,XPS结合能的位移证明了异质结中CuBi_(2)O_(4)和Bi_(2)WO_(6)之间具有强的电子相互作用,而不是物理混合;使用紫外⁃可见漫反射光谱和价带-X射线光电子能谱分析了异质结的能带结构;利用光致发射光谱、电化学阻抗谱和瞬态光电流响应谱探究了催化剂的电荷转移情况.在该系列催化剂中,CBWO-60在光电类芬顿(PEF-like)体系中对环丙沙星(CIP)的降解效率最高,90 min时,降解效率为98.0%.同时,溶液初始pH在2~6范围时,体系始终能够维持有效的CIP去除效率,与传统芬顿体系相比,该体系的pH应用范围得到了有效拓宽.在PEF-like体系中,CBWO-60对喹诺酮类、磺胺类和四环素类抗生素均表现出较强的降解能力,充分证明了CBWO-60的普适性.CBWO-60在连续5次循环实验后,对CIP仍保持87.8%的降解率,并且反应后催化剂的晶体结构没有发生改变.根据高效液相色谱⁃质谱的结果,提出了CIP降解的5种可能途径.