B群链球菌耐药性及红霉素耐药机制的研究

目的探讨荆州地区GBS对常用抗生素的耐药谱和对红霉素的耐药机制。方法采用选择性培养法从阴道和肛门拭子中分离B群链球菌(GroupB Streptococci,GBS),用标准的K-B法对常用的7种抗生素进行药敏试验,然后针对红霉素耐药菌株检测耐药基因ermA、ermB和mefA。结果 176株GBS对头孢噻肟和万古霉素均敏感,对青霉素和氨苄青霉素虽然没有耐药但其中介率达到12.0%。对红霉素的耐药率和中介率分别为35.8%和6.8%;对克林霉素的耐药率和中介率分别为9.5%和12.5%。63株对红霉素耐药的GBS中有22株同时对克林霉素耐药(cMLS型),有41株对红霉素耐药而对克林霉素敏感(M型)。在22株cMLS型耐药的菌株中有18株检测到ermB基因,2株检测到检测到ermA基因。在M型耐药的菌株中有32株检测到mefA基因,6株检测到ermB基因,1株检测到检测到ermA基因。结论青霉素是治疗本地区GBS感染的有效药物,但本地区GBS对红霉素的耐药比较严重。mefA介导的外排机制可能是是本地区分离的GBS对红霉素耐药的主要机制。     

粪肠球菌和屎肠球菌耐药性分析

目的 监测我院肠球菌中粪肠球菌株和屎肠球菌株的耐药性,为临床合理应用抗菌药物提供依据。方法 采用法国生物梅里埃公司的GPI板进行细菌鉴定及药敏试验,应用whonet5软件统计粪肠球菌和屎肠球菌的耐药率。结果 粪肠球菌和屎肠球菌对氯霉素、呋喃妥因、万古霉素有较好体外抗菌活性,耐药率都在50%以下,对万古霉素的耐药率在1%以下。粪肠球菌对青霉素、高水平庆大霉素、环丙沙星、利福平、红霉素等大部分抗菌素的耐药率有逐年下降趋势,而屎肠球菌对环丙沙星、利福平、呋喃妥因等抗菌素的耐药率则有上升趋势,屎肠球菌对大多数抗菌素耐药率都高于粪肠球菌。结论 粪肠球菌和屎肠球菌呈多重耐药,临床用药应结合药敏试验结果合理选择抗菌药物。     

血流感染粪肠球菌和屎肠球菌的临床分布及耐药研究

回顾性分析上海市某三甲医院血培养阳性标本中粪肠球菌和屎肠球菌的临床分布及对抗菌药物的耐药特征,为临床治疗其所致感染奠定基础。收集上海市某三甲医院2012年2月—2016年9月血流感染患者血液标本中的粪肠球菌和屎肠球菌,采用法国生物梅里埃公司的VITEK 2Compact全自动细菌鉴定和药敏分析系统进行细菌鉴定及药敏测定,研究细菌临床分布特点及对常用抗菌药物的耐药特征。共分离获得30株粪肠球菌和17株屎肠球菌。粪肠球菌样本主要来自泌尿科、消化科和血液科,所占比例分别为13.33%、16.67%和10.00%。粪肠球菌对青霉素、氨苄西林、环丙沙星、左氧氟沙星、四环素和红霉素的耐药率分别为13.33%、10.00%、36.67%、33.33%、66.67%和60.00%。屎肠球菌样本主要来自消化科(29.41%),其对以上抗菌药物的耐药率分别为88.24%、82.35%、88.24%、76.47%、23.53%和70.59%。屎肠球菌对青霉素、氨苄西林、环丙沙星和左氧氟沙星的耐药率显著高于粪肠球菌,而对四环素的耐药率显著低于粪肠球菌。两者均对替加环素、利奈唑胺和万古霉素敏感,但万古霉素对屎肠球菌的最低抑菌浓度显著低于粪肠球菌。结果提示,屎肠球菌对青霉素、氨苄西林、环丙沙星、左氧氟沙星的耐药率高于屎肠球菌,对万古霉素敏感,且其万古霉素最低抑菌浓度低于粪肠球菌。本研究为治疗这两种细菌所致感染的经验性用药提供了数据支持。     

临床分离肠球菌的分布特征及耐药性分析

目的:了解我院临床分离肠球菌的分布特征及耐药现状,为临床合理用药提供依据。方法:对我院2010年1月至2012年12月期间所有临床分离的肠球菌分布情况及药敏结果进行回顾性分析。结果:临床共分离肠球菌242株,粪肠球菌分离率(55.0%)高于屎肠球菌(40.9%),屎肠球菌分离率有增高的趋势。标本来源以尿液(62.9%)、分泌物(10.3%)、血液(6.9%)为主。肠球菌对万古霉素、替考拉宁的敏感性最高,均高于90%。发现耐万古霉素的肠球菌(VRE)7株,其中5株同时耐高浓度的氨基糖苷类抗生素(HLAR);对克林霉素、复方磺胺、阿米卡星、庆大霉素、妥布霉素、苯唑西林耐、头孢西丁耐药率最高,均高于95%。屎肠球菌对青霉素类、氨苄西林、红霉素、呋喃妥因、环丙沙星耐药率均高于粪肠球菌;对四环素、奎努普丁/达福普汀耐药率低于粪肠球菌。结论:肠球菌是临床感染重要病原菌,且具有多重耐药性,屎肠球菌和粪肠球菌耐药水平差异较大,临床应根据药敏结果合理选择抗菌药物。     

氨基糖苷类高水平耐药肠球菌耐药基因的检测与研究

目的 研究氨基糖苷类高水平耐药(high-level aminoglycoside-resistant,HLAR)肠球菌临床株表面蛋白基因(esp)、Ⅰ类整合酶基因(IntI1)、耐氯霉素肠球菌乙酰转移酶基因(cat)等三种耐药基因的流行情况及肠球菌对常见抗菌药物的耐药情况.方法 对53株肠球菌进行菌株鉴定和药敏试验,用PCR法扩增肠球菌esp基因、IntI1基因和cat基因,阳性产物送测序并对序列进行分析.结果 53株HLAR肠球菌中,esp基因阳性率为28.3％,Ⅰ类整合酶基因阳性率为49.1％,没有检测到cat基因.菌株对多种抗菌药物的耐药率为:氨苄西林62.3％、环丙沙星75.5％、红霉素94.3％、高水平庆大霉素75.5％、高水平链霉素73.6％、喹努普汀/达福普汀32.1％、四环素66.0％、万占霉素1.9％、利奈唑胺0.结论 肠球菌对常见抗菌药物存在不同程度的耐药,esp基因和IntI1基因与肠球菌耐药性密切相关.     

肠球菌的临床感染与耐药性分析

目的了解温州医学院附属第一医院临床分离主要肠球菌的分布及其对常用抗菌药物的耐药现状,以指导临床合理用药。方法对2008年至2011年临床分离的635株粪肠球菌和屎肠球菌的标本来源和药敏结果进行回顾性分析。结果各种临床标本中两种肠球菌的分布比例存在差异,总体以尿液标本所占比例最多,且屎肠球菌的总体分离率高于粪肠球菌。粪肠球菌对利奈唑胺、氨苄西林、万古霉素、呋喃妥因和替考拉宁的耐药率都在5．0％以下,对莫西沙星和青霉素G的耐药率也仅为7．0％和6．7％;屎肠球菌对莫西沙星、左旋氧氟沙星、环丙沙星、氨苄西林、青霉素G和红霉素的耐药率都在90．0％以上,对利奈唑胺、万古霉素、替考拉宁和奎奴敏感。粪肠球菌的多重耐药株占总数的26．4％,屎肠球菌的多重耐药株占总数的78．2％。结论粪肠球菌和屎肠球菌对15种抗菌药物的耐药情况不同,屎肠球菌具有更高的耐药率和更广的耐药谱。临床应根据药敏试验的结果合理选择抗菌药物,以防止耐药菌株的产生和播散。     

基于全基因组关联分析研究粪肠球菌发酵食品分离株的耐药性

【目的】研究15株分离自自然发酵食品的粪肠球菌(Enterococcus faecalis)和1株粪肠球菌模式株对15种(1种β-内酰胺类和14种非β-内酰胺类)抗生素的耐药性,并通过菌株耐药表型与基因型的关联分析找到粪肠球菌潜在的耐药基因。【方法】利用微量肉汤稀释法检测试验菌株对15种抗生素的耐药性,运用Scoary软件进行表型与基因型的关联分析。【结果】16株粪肠球菌对卡那霉素、万古霉素、利奈唑胺和红霉素100%敏感;对其余11种抗生素均表现出不同程度的耐药,其中对克林霉素为100%耐药。基因组关联分析发现了9个功能基因与5种抗生素(氯霉素、环丙沙星、甲氧苄啶、新霉素和四环素)存在显著相关关系,其中基因FAM000296和FAM005768与氯霉素、甲氧苄啶和环丙沙星的耐药性有关。进一步分析发现基因FAM000296和FAM005768同被注释为Sec G,但基因FAM005768与基因FAM000296相比在3′端丢失了21个碱基。【结论】分离自自然发酵食品的粪肠球菌对多种抗生素具有耐药性,其基因组中携带有潜在的耐药基因。因此,对分离自自然发酵食品的粪肠球菌需要进行全面的安全性评估后方可考虑应用。     

耐甲氧西林凝固酶阴性葡萄球菌中多种抗生素耐药基因的观察

探讨耐甲氧西林凝固酶阴性葡萄球菌(methicillin-resistant coagulase negative staphylococci,MRCNS)中多种抗生素耐药基因的分布情况,采取Kirby Bauer标准纸片扩散法(K-B纸片扩散法)对MRCNS开展药敏实验,并通过PCR检测菌种携带的抗生素耐药基因。药敏实验结果显示,96株MRCNS对庆大霉素、红霉素、莫匹罗星以及四环素的耐药性各有差异,但对氨苄西林的耐药性却达到100%,未发现对万古霉素具有耐药性的菌株;PCR检测结果显示,9种耐药基因merA、ermB、ermC、msrA、tetM、tetK、aac(6’)-aph(2")、aph(3’)-III、mupA的阳性检出率各有差异,没有扩增出vanA、ermA、vanB以及ant(6’)-I基因,但都扩增出mecA基因。结果表明,MRCNS可以同时携带多种抗生素耐药基因,属于一种多重耐药菌。     

267株肠球菌分布及耐药性分析

目的 了解肠球菌的分布特征和耐药特点,指导临床合理用药.方法 采用美国Dade Behring Mi-croscan Walkaway40全自动细菌鉴定及药敏测试仪对267株肠球菌进行鉴定和药敏测试,用全国医院感染监测网软件和P检验进行分析.结果 267株肠球菌以屎肠球菌和粪肠球菌为主,分别占60.7%和31.5%,以尿液和脓液中分离出最多,其次为血液和胆汁,依次是56.6%、14.2%、10.9%、9.7%,占总标本的91.4%.肠球菌不同种间的耐药性差异存在显著性.屎肠球菌的耐药率相对较高,除对万古霉素的耐药率3.7%最低,四环素37.7%外,对其它抗菌药物的耐药率均超过了50%.粪肠球菌的耐药率虽比屎肠球菌低,但对红霉素、四环素、氨基糖苷类的耐药性仍高,在60%以上.屎肠球菌和粪肠球菌对高浓度庆大霉素和链霉素的耐药率均在55%以上.共检出耐万古霉素株11株,对万古霉素的耐药率为4.1%.结论 肠球菌可引起多种部位感染,呈多重和高耐药性,耐万古霉 素的菌株出现,增加了感染控制难度,应引起临床重视.     

肠球菌属细菌的临床分布与耐药性分析

目的了解2012-2017年临床分离肠球菌的分布特征及耐药性,为临床合理用药提供依据。方法采用全自动微生物分析仪进行菌株鉴定及药敏试验,对肠球菌的临床分布与耐药情况进行统计分析。结果共分离出1 432株肠球菌,其中粪肠球菌为603株(42.11%),屎肠球菌为596株(41.62%)。肠球菌属细菌标本来源以尿液、胆汁和全血为主,分别占39.66%、34.50%和11.59%,其中粪肠球菌主要来自普外科、泌尿外科和ICU,而屎肠球菌主要来自ICU、普外科和消化内科。肠球菌总体对红霉素的耐药率最高(67.81%),其次为四环素(47.49%)、环丙沙星(47.00%)和左旋氧氟沙星(46.44%),对利奈唑胺和万古霉素的耐药率较低,分别为4.89%和1.19%。粪肠球菌对奎奴普丁/达福普汀、四环素的耐药率分别为83.91%和64.01%,明显高于屎肠球菌(均P0.05)。屎肠球菌对红霉素、青霉素G、氨苄西林、喹诺酮类的耐药率均超过85.00%,且均高于粪肠球菌(均P0.05)。粪肠球菌和屎肠球菌对利奈唑胺的耐药率分别为6.80%和2.18%,对万古霉素的耐药率分别为0.66%和0.67%。结论肠球菌感染病原菌以粪肠球菌和屎肠球菌为主,肠球菌属细菌对万古霉素和利奈唑胺仍然保持较高的敏感性,不同种的肠球菌其耐药性差异显著。     

The frequency of the occurrence of genes ermA, ermB, ermC and msrA/B among methicillin-resistant Staphylococcus aureus strains resistant to erythromycin

The group of 50 clinical MRSA strains resistant to MLS-B was examined for the presence of ermA, ermB, ermC, msrA/B genes by using PCR. Gene ermA was found in 43 strains (86%). 20 of ermA strains demonstrated inducible whereas 23 constitutive type of expression. The gene ermC was present in 15 of examined MRSA strains (30%). The expression of the gene was inducible in the case of 9 and constitutive in the case of 6 of the strains. The msrA/B gene was present in the case of 5 strains (10%). The ermB gene was not detected among the investigated strains.     

Characterisation and transfer of antibiotic resistance genes from enterococci isolated from food

The genetic determinants responsible for the resistances against the antibiotics tetracycline [tet(M), tet(O), tet(S), tet(K) and tet(L)], erythromycin (ermA,B,C; mefA,E; msrA/B; and ereA,B) and chloramphenicol (cat) of 38 antibiotic-resistant Enterococcus faecium and Enterococcus faecalis strains from food were characterised. In addition, the transferability of resistance genes was also assessed using filter mating assays. The tet(L) determinant was the most commonly detected among tetracycline-resistant enterococci (94% of the strains), followed by the tet(M) gene, which occurred in 63.0% of the strains. Tet(K) occurred in 56.0% of the resistant strains, while genes for tet(O) and tet(S) could not be detected. The integrase gene of the Tn916-1545 family of transposons was present in 81.3% of the tetracycline resistant strains, indicating that resistance genes might be transferable by transposons. All chloramphenicol-resistant strains carried a cat gene. 81.8% of the erythromycin-resistant strains carried the ermB gene. Two (9.5%) of the 21 erythromycin-resistant strains, which did not contain ermA,B,C, ereA,B and mphA genes harboured the msrC gene encoding an erythromycin efflux pump, which was confirmed by sequencing the PCR amplicon. In addition, all E. faecium strains contained the msrC gene, but none of the E. faecalis strains. Transfer of the genetic determinants for antibiotic resistance could only be demonstrated in one filter mating experiment, where both the tet(M) and tet(L) genes were transferred from E. faecalis FAIR-E 315 to the E. faecalis OG1X recipient strain. Our results show the presence of various types of resistance genes as well as transposon integrase genes associated with transferable resistances in enterococci, indicating a potential for gene transfer in the food environment.     

Multiplex PCR detection of the antibiotic resistance genes in <Emphasis Type="Italic">Staphylococcus aureus</Emphasis> strains isolated from auricular infections

Thirty-five Staphylococcus aureus strains from auricular infections were isolated. The identification of strains was confirmed by Api ID 32 Staph strips, the antibiotic susceptibility test was performed using ATB Staph kit. PCR assay was used to detect the oxacillin resistance gene (mecA) and the erythromycin genes (ermA, ermB, ermC, msrA and mef). The susceptibility profile of all strains revealed a low resistance level to oxacillin and erythromycin. The PCR results show that 60 % of the strains are mecA positive. The frequency of erythromycin genes was: ermA (+) 22.8 %, ermB (+) 45.7, ermC (+) 17.1, msrA (+) 28.6. The mef gene was not detected in any strain. No correlations between genotypic and phenotypic methods for the determination of oxacillin and erythromycin resistance was found. However, multiplex PCR technique was shown to be a fast, practical and economic technique for the detection of methicillin-and erythromycin-resistant staphylococci.     

Microarray analysis of erythromycin resistance determinants

AIMS: To develop a DNA microarray for analysis of genes encoding resistance determinants to erythromycin and the related macrolide, lincosamide and streptogramin B (MLS) compounds. METHODS AND RESULTS: We developed an oligonucleotide microarray containing seven oligonucleotide probes (oligoprobes) for each of the six genes (ermA, ermB, ermC, ereA, ereB and msrA/B) that account for more than 98% of MLS resistance in Staphylococcus aureus clinical isolates. The microarray was used to test reference and clinical S. aureus and Streptococcus pyrogenes strains. Target genes from clinical strains were amplified and fluorescently labelled using multiplex PCR target amplification. The microarray assay correctly identified the MLS resistance genes in the reference strains and clinical isolates of S. aureus, and the results were confirmed by direct DNA sequence analysis. Of 18 S. aureus clinical strains tested, 11 isolates carry MLS determinants. One gene (ermC) was found in all 11 clinical isolates tested, and two others, ermA and msrA/B, were found in five or more isolates. Indeed, eight (72%) of 11 clinical isolate strains contained two or three MLS resistance genes, in one of the three combinations (ermA with ermC, ermC with msrA/B, ermA with ermC and msrA/B). CONCLUSIONS: Oligonucleotide microarray can detect and identify the six MLS resistance determinants analysed in this study. SIGNIFICANCE AND IMPACT OF THE STUDY: Our results suggest that microarray-based detection of microbial antibiotic resistance genes might be a useful tool for identifying antibiotic resistance determinants in a wide range of bacterial strains, given the high homology among microbial MLS resistance genes.     

Detection and characterization of erythromycin-resistant methylase genes in Gram-positive bacteria isolated from poultry litter

The epidemiology of four erythromycin-resistant methylase ( erm) genes, ermA, ermB, ermC and msrA, was determined in erythromycin-resistant staphylococci, enterococci and streptococci isolated from poultry litter. All isolates were resistant to multiple antibiotics. Southern hybridization indicated that 4 of the 20 staphylococci contained the ermC gene on plasmids: on a 2.2 kb plasmid in Staphylococcus hominis and S. sciuri, on a 6.0 kb plasmid in S. xylosus, and on a 7.0 kb plasmid in S. lentus. In 16 of the 20 staphylococci, the ermA gene was harbored exclusively on the chromosome, as a double chromosomal insert on 8.0 and 6.2 kb EcoRI fragments. None of the staphylococci harbored the msrA gene. Dot-blot analysis indicated that all enterococci and streptococci hybridized with a biotinylated ermB gene probe. Southern hybridization indicated that only 2 of the 19 erythromycin-resistant enterococci contained the ermB gene on plasmids. The gene was localized on 4.0 kb and 5.9 kb plasmids, respectively, in two Enterococcus faecium isolates. Results from our studies indicate that the patterns of occurrence of erm genes, the sizes of the plasmids and the copy numbers of the inserts were different from the existing information on the presence of erm genes in clinical strains of Staphylococcus spp.     

Characterization of glycopeptides, aminoglycosides and macrolide resistance among Enterococcus faecalis and Enterococcus faecium isolates from hospitals in Tehran

The prevalence of glycopeptides, aminoglycosides and erythromycin resistance among Enterococcus faecalis and Enterococcus faecium was investigated. The susceptibility of 326 enterococcal hospital isolates to amikacin, kanamycin, netilmicin and tobramycin were determined using disk diffusion method. The minimum inhibitory concentration (MIC) of vancomycin, teicoplanin, gentamicin, streptomycin, and erythromycin were determined by microbroth dilution method. The genes encoding aminoglycoside modifying enzymes described as AMEs genes, erythromycin-resistant methylase (erm) and vancomycin-resistant were targeted by multiplex-PCR reaction. High level resistance (HLR) to gentamicin and streptomycin among enterococci isolates were 52% and 72% respectively. The most prevalent of AMEs genes were aac (6')-Ie aph (2") (63%) followed by aph (3')-IIIa (37%). The erythromycin resistance was 45% and 41% of isolates were positive for ermB gene. The ermA gene was found in 5% of isolates whereas the ermC gene was not detected in any isolates. The prevalence of vancomycin resistant enterococci (VRE) was 12% consisting of E. faecalis (6%) and E. faecium (22%) and all of them were VanA Phenotype. The results demonstrated that AMEs, erm and van genes are common in enterococci isolated in Tehran. Furthermore our results show an increase in the rate of vancomycin resistance among enterococci isolates in Iran.     

6类抗生素耐药基因在耐甲氧西林凝固酶阴性葡萄球菌中的分布及分析

目的了解6类抗生素耐药基因在耐甲氧西林凝固酶阴性葡萄球菌（MRCNS）中的分布情况,为抗生素的合理使用及感染控制提供依据。方法应用K-B纸片扩散法对6种抗生素进行药敏试验,聚合酶链反应（PCR）对6类耐药基因进行检测。结果 MRCNS对氨苄西林、红霉素、四环素、庆大霉素和莫匹罗星的耐药率分别为100%、87.50%、30.21%、61.46%和27.08%,未检测出对万古霉素的耐药菌株;mecA、ermB、ermC、msrA、tetM、tetK、aac（6’）/aph（2＂）、aph（3’）-III和mupA耐药基因的阳性检出率分别为100.0%、10.42%、77.08%、46.86%、5.21%、2.08%、75.00%、39.58%和25.00%,未检测出ermA、ant（6’）-I、vanA和vanB耐药基因。结论 MRCNS能同时携带多种抗生素耐药基因,为多重耐药菌。     

The correlation between phenotypes and genotypes of macrolides, lincosamides and streptogramins B resistance in Staphylococcus aureus

For 31 clinical strains of S. aureus the correlation between phenotype and genotype of resistance to macrolides, lincosamides and streptogramins B (MLSB) was established.. Phenotypes were determined on the basis of: susceptibility to erythromycin and clindamycin and the ability to an induction of the resistance (phenotypes S, susceptible; R , constitutive resistant, D, resistant after induction with erythromycin, D+, resistant after induction with erythromycin and with a presence of the small colonies inside inhibition zone between erythromycin and clindamycin discs), and on the basis of the resistance to spectinomycin (spR, resistant, spS, susceptible). Among examined S. aureus strains eight phenotypes of resistance to MLSB were recognized (the corresponding genotypes are given in brackets). Six phenotypes were typical: SspS (lack of MLS-B resistance genes), NEGspS (msrA/B, 1 strain), D+spS (ermCi, 4 strains),. DspR (ermAi, 11 strains and ermAi + msrA/B, 2 strains), RspR (ermAc, 4 strains and ermA + msrA/B,1 strain and ermA + ermC, 1 strain) and RspS (ermCc, 6 strains and ermB, 1 strain). Two rare phenotypes in two single strains were observed: SspR (ermAi, the strain with altered inducibility, inductor other than erythromycin) and DspS (ermAi, presumably mutation or lack of spc in Tn554).     

Clonality and Occurrence of Genes Encoding Antibiotic Resistance and Biofilm in Methicillin-Resistant Staphylococcus epidermidis Strains Isolated from Catheters and Bacteremia in Neutropenic Patients

Thirty methicillin-resistant Staphylococcus epidermidis strains isolated from catheters and blood cultures from neutropenic patients were studied. They were classified into 17 multidrug-resistance patterns. Polymerase cahin reaction analysis revealed that methicillin resistance was encoded by the mecA gene in all strains, and aminoglycosides resistance was due to aac(6')-Ie-aph(2')-Ia (23 strains), ant(4')-Ia (13), and aph(3')-IIIa (1) genes. The aac(6')-Ie-aph(2')-Ia gene was detected concomitantly with aph(3')-IIIa, and ant(4')-Ia genes in one and nine strains, respectively. Erythromycin resistance was encoded by the ermC (11 strains), ermA (6), and msrA (2) genes. The ermC gene was inducibly expressed in five strains, whereas the ermA was exclusively constitutively expressed. The icaA and icaC genes were detected in 19 strains; however, biofilm production was observed in only 16 strains. Most strains harbored multiple plasmids of variable sizes ranging from 2.2 to 70 kb, and two strains were plasmid-free. PFGE identified 15 distinct PFGE types, and five predominant genotypes were found. Our study showed the occurrence of complex genetic phenomenons. In unrelated strains, evidence of horizontal transfer of antibiotic-encoding genes and/or ica operon, and in indistinguishable strains, there is a quite good likelihood of independent steps of loss and/or gain of these genes. This genome dynamicity might have enhanced the invasiveness power of these methicillin-resistant S epidermidis strains.