鲁氏耶尔森氏菌口服微球疫苗特性分析及免疫效果研究

为制备并评价鲁氏耶尔森氏菌口服微球疫苗的免疫效果,实验采用天然高分子聚合物海藻酸钠为疫苗载体,鲁氏耶尔森氏菌灭活疫苗为抗原,制备鲁氏耶尔森氏菌口服疫苗。以拌料口服方式进行免疫,通过血清非特异免疫指标、抗体效价、免疫保护率等综合评价疫苗的免疫效果。结果表明,鲁氏耶尔森氏菌口服微球疫苗成球性好,粒径均匀,粒径(8.761.73) m,跨距0.47,包封效率94.51%,具备良好的抗酸性、肠溶性及高安全性的特点。将疫苗免疫斑点叉尾,能显著提高斑点叉尾血清中溶菌酶活力、总超氧化物歧化酶活力(T-SOD)以及补体替代途径活性(ACH50);血清凝集效价于第5周达到峰值为1:8,至免疫后第8周仍能检测到特异性抗体;口服鲁氏耶尔森氏菌微球疫苗的斑点叉尾获得的抗鲁氏耶尔森氏菌相对免疫保护率为65.52%。综上所述,实验制备的鲁氏耶尔森氏菌口服微球疫苗能够对鲁氏耶尔森氏菌病起到较好的预防作用。       

壳聚糖-海藻酸钠包裹Hp全菌蛋白微球剂的研制及其表征分析

以壳聚糖、海藻酸钠为主要合成材料包裹幽门螺杆菌全菌超声蛋白抗原 ,制备新型Hp疫苗制剂。采用一定工艺 ,将海藻酸钠、壳聚糖以及Hp超声全菌抗原制备成W /O/W微球。通过扫描电镜、粒径分布仪等设备检测微球粒径大小 ;微球溶出度仪、Lowry法检测蛋白含量、高压液相色谱等检测微球的蛋白的包封率以及释放速率 ;12 5I标记后口服观测微球的定向靶向作用等。所制备微球形态规则 ,粒径均在 10 μm以内 ;包封率达到 4 1%左右 ;整个包封过程对蛋白没有任何降解作用 ;微球呈缓 快 缓释药模式 ,药物缓释时间可长达 72h ;微球在肠PP结分布明显高…     

IBDV丝素蛋白/壳聚糖DNA微球疫苗的制备及免疫原性分析

为了制备传染性法氏囊病病毒(Infectious bursal disease virus,IBDV)DNA微球疫苗,并评价其免疫效果。以丝素蛋白(Silk fibroin,SF)/壳聚糖(Chitosan,CS)为壁材,IBDV的VP2/4/3 DNA疫苗为芯材,通过戊二醛和Na2SO4介导的乳化交联技术,制备出SF/CS复合微球疫苗,然后经肌肉注射14日龄非免疫鸡,2周后加强免疫一次,酶联免疫法(ELISA)定期监测鸡血清的IBDV抗体,以研究微球化疫苗的免疫原性。结果显示:戊二醛介导交联方法影响荷载DNA疫苗的活性,而Na2SO4介导的交联方法操作简单且不影响荷载DNA活性;建立了以壳聚糖浓度0.5%(pH 5.0)、丝素蛋白浓度0.6%,质粒DNA 500μg/mL溶解在2%Na2SO4溶液中的工作条件;SF-CS复合微球DNA疫苗荷载率89.14%,大小1.98μm,对DNaseⅠ的消化有保护作用。免疫后的抗IBDV血清ELISA抗体的检测显示,微球免疫组总体高于质粒疫苗免疫组(P0.05),而且SF/CS复合微球组免疫反应要略高于单纯CS包被的抗原组。研究表明,丝素蛋白/壳聚糖作为微球佐剂能提高IBDV DNA疫苗的临床免疫效果,有很好的应用前景。     

大肠杆菌微球包封效率及稳定性的研究

多聚物制备而成的微球是一种具有佐剂效应的疫苗控释系统,在疫苗研制中得到广泛应用.为改进大肠杆菌疫苗的制备质量,本文以天然高分子聚合物海藻酸钠和壳聚糖为材料,应用了三种不同制备微球的方法来制备大肠杆菌微球,观察微球的形态、粒径和稳定性,并测算其对大肠杆菌的包封率.结果表明,采用乳化-内部凝胶化法制备的大肠杆菌海藻酸钙-壳聚糖微球,圆整规则,粒径较小,包封率达到≈93.1％,具有良好的控释性能和稳定性,适于低温保存.     

基于rV270抗原的鼠疫多孔微球疫苗的制备及其免疫保护作用评价

目的：评价生物可降解高分子材料多孔微球作为鼠疫亚单位疫苗佐剂的可行性。方法：制备可生物降解的高分子材料多孔微球,将rV270抗原蛋白吸附到多孔微球中制备微球疫苗,肌肉注射免疫BALB/c小鼠,初次免疫后21d加强免疫1次,于初次免疫后第10周用600LD50鼠疫耶尔森氏菌攻毒,攻毒后观察14d。结果：攻毒后,微球疫苗免疫的小鼠全部存活,且健康状况良好,对照组小鼠几乎全部死亡。结论：生物可降解多孔微球可作为免疫佐剂用于鼠疫亚单位疫苗研制。     

不同温度下恩诺沙星及其代谢物在斑点叉尾鲖各组织中的残留及消除规律比较

分别在18℃和28℃水温下, 以20 mg/(kg·d)鱼体质量对斑点叉尾鲙给药恩诺沙星, 连续灌胃7d。给药后在不同的时间点取样, 用高效液相色谱荧光检测器检测, 研究恩诺沙星及其主要代谢产物环丙沙星在斑点叉尾鲙体内(血液、肌肉、皮肤、肝脏和肾脏)的残留消除规律。结果表明, 恩诺沙星在不同组织、不同水温消除速率不同: 水温为18℃, 皮肤、肝脏、肾脏和肌肉中的消除曲线方程分别为C=1022.1e–0.034t、C=2601.3e–0.046t、C=2903.6e–0.072t和C=1186.5e–0.036t, 消除半衰期分别为31.79d、45.29d、16.15d和35.54d; 水温为28℃, 皮肤、肝脏、肾脏和肌肉中的消除曲线方程分别为C=8805.5e–0.04t、C=3154e–0.08t、C=4145.1e–0.1t和C=1302.1e–0.068t, 消除半衰期分别为18.33d、6.26d、12.44d和10.34d。恩诺沙星在斑点叉尾鲙体内可代谢为环丙沙星, 恩诺沙星在斑点叉尾鲙体内的代谢速度较慢, 代谢物环丙沙星在斑点叉尾鲙体内的消除速度比恩诺沙星快; 在18℃水温下, 斑点叉尾鲙肉中的恩诺沙星和环丙沙星完全消除需要150d以上; 在28℃水温下, 斑点叉尾鲙肉中的恩诺沙星和环丙沙星完全消除需要120d。在实验条件下, 建议水温为18℃和28℃时, 休药期分别为3240℃·日和4200℃·日。     

嗜麦芽寡养单胞菌脂多糖对斑点叉尾免疫保护作用

嗜麦芽寡养单胞菌(Stenotrophomonas maltophilia)是近年来引起斑点叉尾高致死性、传染性疾病的主要病原之一。为了研究嗜麦芽寡养单胞菌脂多糖对斑点叉尾的免疫保护作用,实验选用了400尾健康斑点叉尾,随机分成Ⅰ、Ⅱ、Ⅲ、Ⅳ四个组,每组用鱼100尾,每组下设两个重复,每个重复用鱼50尾,以腹腔注射的方式分别向Ⅰ、Ⅱ、Ⅲ、Ⅳ四个组的斑点叉尾注射嗜麦芽寡养单胞菌脂多糖、无花果多糖加脂多糖、全菌灭活苗和生理盐水,在试验第0、第28天时分别进行首次免疫和加强免疫,试验期间每隔7d,对试验鱼的血液白细胞杀菌活性、补体C3含量、IgM含量和血清凝集效价滴度进行测定;试验第49天时进行活菌攻毒。结果表明,首免后,接种脂多糖、无花果多糖加脂多糖的试验鱼血清凝集效价滴度明显升高,白细胞杀菌活性、补体C3含量、IgM含量也明显增加;加强免疫后,脂多糖、无花果多糖加脂多糖的试验鱼血清凝集效价滴度峰值分别为1∶256和1∶512,白细胞杀菌活性峰值分别为0.565和0.511,补体C3含量峰值分别0.194和0.180mg/mL,IgM含量峰值分别1.415和1.464mg/mL,免疫保护率分别为70.0%和65%。嗜麦芽寡养单胞菌脂多糖和脂多糖+无花果多糖受免鱼的上述指标均显著(P<0.05)或极显著(P<0.01)地高于生理盐水注射组,这两者的免疫保护效果优越于全细胞灭菌苗。     

载荷壳聚糖微球的海藻酸钠水凝胶的制备

目的:在支架材料上引入具有控释行为的微球,旨在通过微球包裹生长因子,通过生长因子的缓慢释放从而促进种子细胞的生长分化。方法:本实验通过在海藻酸钠水凝胶中负载具有控释功能的壳聚糖微球,并通过在微球中包载溶菌酶从而达到控制壳聚糖降解速率的功效。实验研究了不同搅拌速度下壳聚糖微球的形貌及粒径大小,通过扫描电镜对壳聚糖微球及复合支架的形貌进行了观察,通过紫外光吸收法测试了微球的载药量及包封率,并研究了壳聚糖微球在体外的降解行为等。结果:制备的壳聚糖微球表面较光滑,溶菌酶的包封率在25.78%-41.89%之间,载药量在15.20%-24.44%之间。包封溶菌酶的微胶囊在降解9天后壳聚糖分子量下降了70.40%,载荷微球的复合凝胶孔洞增多,孔洞大小均匀。结论:此复合材料有望作为载荷软骨相关生长因子的支架模型,从而解决软骨组织工程中种子细胞匮乏的问题。     

生物可降解微球作为HPV-E7 蛋白免疫佐剂的研究

目的:对聚乳酸聚羟基乙酸(PGLA)作为疫苗运输载体进行免疫学评价。方法:用复乳法制备PLGA微球,通过表面吸附人乳头状瘤病毒(HPV)E7蛋白制备成聚乳酸聚羟基乙酸(PGLA)微球,考察粒径分布情况及体外释放水平,通过皮下免疫注射途径免疫C57BL/6小鼠,用间接ELISA法检测免疫鼠血清中的抗体水平,由此评价PLGA微球疫苗运输载体的佐剂效应。。结果:复乳法制备的PLGA微球表面光滑,大小均匀,包封率20.1%,注射小鼠6周后(第2周加强免疫1次),微球疫苗诱导产生的IgG1抗体水平较同剂量的铝佐剂组和溴化二甲基双十八胺(DDA)组明显升高,(平均滴度分别为3805、1270、2262);微球疫苗诱导产生IgG2b的抗体水平明显高于铝佐剂组,略低于DDA组,(平均滴度分别为1131、475、2653)而IgG2c的抗体量高于铝佐剂组和DDA组(平均滴度分别为150、36、106)。结论:人乳头状瘤病毒E7蛋白聚乳酸羟基乙酸微球作为疫苗输送体系可以明显的提高抗原的免疫原性。     

口蹄疫病毒VP1基因在番茄中的表达及转基因番茄对豚鼠诱导免疫保护

构建克隆有O型口蹄疫病毒China99株VP1基因的植物双元表达载体pBin438/VP1。通过农杆菌介导法转化番茄子叶,经卡那霉素抗性筛选,获得60株抗性植株。对抗性植株分别做PCR、RT-PCR检测目的基因的整合与转录,ELISA筛选约40%的卡那抗性植株阳性,分别提取两株ELISA和Western blot检测阳性的转基因番茄叶片蛋白与弗氏佐剂乳化,于0、15、30d经肌肉途径免疫豚鼠,第三次免疫后28d用100ID50的同源强毒攻击,根据豚鼠抗体水平的消长动态和免疫豚鼠抗强毒攻击的保护率进行转基因植物疫苗免疫原性的评估。结果表明,双元表达载体pBin438/VP1构建正确,PCR、RT-PCR结果证实口蹄疫病毒VP1基因已整合到番茄基因组并在转录水平表达,ELISA和Western blot检测重组蛋白能够与FMDV阳性血清反应。转基因番茄第三次免疫豚鼠后21d血清效价最高可达1∶64,攻毒后两组免疫豚鼠保护率分别达80%和40%,证明转基因番茄表达的VP1蛋白具有良好的免疫原性。     

人轮状病毒ZTR-5株灭活疫苗的制备及小鼠血清免疫学评价

目的: 研究人轮状病毒ZTR-5株灭活疫苗的制备及在实验小鼠中的免疫原性评价。方法: 轮状病毒ZTR-5株在MA104细胞上经蚀斑筛选纯化后,获得单一克隆接种至Vero细胞上适应性培养,免疫荧光定量检测病毒的感染性滴度,对收获的病毒液进行离心、超滤、分子筛纯化,甲醛灭活,抗原定量检测Al(OH)₃吸附制备的实验性疫苗。使用不同剂量(8EU、32EU、128EU、256EU)经肌内注射免疫小鼠,共免疫三次,免疫间隔2周。采用间接ELISA法检测血清特异性抗体效价。 结果: 通过蚀斑纯化,筛选得到一株纯化的病毒株ZTR-5纯-1,在Vero细胞上适应性后感染性滴度达7.35logCCID₅₀/ml;大量培养收获的病毒原液滴度为7.57logCCID₅₀/ml,制备获得轮状病毒样品抗原含量为2 560EU/ml;经肌内注射,初次免疫后,所有剂量组动物均获得抗体阳转,阳转率为100%;第一次加强免疫后,各组血清特异性抗体水平均明显增高,免疫剂量为128EU和256EU的两组小鼠血清抗体效价均达1∶10 240;第二次加强免疫后,各剂量组(8EU、32EU、128EU、256EU)血清抗体效价依次达1∶5 120,1∶7 456,1∶14 481.54,1∶14 481.54。 结论:人轮状病毒ZTR-5株可在Vero细胞上稳定增殖,所制备的疫苗具良好免疫原性,用128EU/2次免疫即可获得良好的免疫效果。     

Characterization of serum and mucosal antibody responses in white sturgeon (Acipenser transmontanus Richardson) following immunization with WSIV and a protein hapten antigen

Serum and cutaneous mucus antibodies were monitored in white sturgeon for 15 weeks following intraperitoneal immunization. Ten fish were immunized (50 microg) with white sturgeon iridovirus (WSIV) or white sturgeon gonad (WSGO) tissue culture cells emulsified with or without FCA. An additional group was immunized with FITC:KLH+FCA. Fish were booster immunized at 6 weeks. Fish immunized with FITC:KLH+FCA produced significant serum antibodies to FITC by 6 weeks and this response peaked at 12 weeks (average titer 31,000). Mucosal antibodies to FITC were first detected at 12 weeks and significantly elevated by 15 weeks (average titer 18). Anti-WSIV antibody titers were detected in the serum by 9 weeks in fish immunized with WSIV and WSIV+FCA, but only a small number responded to immunization. At 15 weeks, four fish immunized with WSIV produced serum antibodies (average titer 838) and one fish immunized with WSIV+FCA had a serum titer of 1600. Mucosal anti-WSIV antibody titers of 8 and 16 were observed in two fish from the WSIV group at 12 weeks while four different fish from this group responded at 15 weeks (average titer 4). Western Blot using a monoclonal antibody confirmed immunoglobulin in mucus, and specificity to WSIV was further demonstrated by immunocytochemistry using serum from fish immunized with WSIV. Specific antibody was not detected in mucus of fish immunized with WSIV+FCA, WSGO, or WSGO+FCA. Collectively, these experiments demonstrate that white sturgeon can generate a specific antibody response following immunization, and is the first report showing mucosal immunoglobulin is present in this species.     

鼠伤寒杆菌外膜蛋白作为保护性疫苗的初步实验研究

本文采用超声波破碎和Triton X-100处理、超速离心的方法,提取了鼠伤寒杆菌的外膜蛋白(OMP)。用提取的OMP免疫家兔和小鼠,经用ELISA方法测定小鼠、家兔及鼠伤寒意染患者血清中抗-OMP抗体含量,并用小鼠作足垫肿胀实验及主动和血清被动保护试验。结果免疫动物及患者血清中都含有较高滴度抗体,免疫小鼠足垫出现明显地DTH反应。50ug OMP免疫小鼠可保护500 LD50毒株的攻击,0.2ml免疫血清亦能够被动保护以上同样的毒株攻击。这些结果表明,提取的OMP有较强的免疫原性和明显的免疫保护作用,应用Western blot分析免疫血清均能识别36KD蛋白带,36KD蛋白带可能是鼠伤寒杆菌的主要免疫原。     

Passive immunization of channel catfish Ictalurus punctatus with anti-Flavobacterium columnare sera

Passive immunization of channel catfish Ictalurus punctatus (Rafinesque) was conducted to determine if anti-Flavobacterium columnare serum was protective when injected intraperitoneally (i.p.) into channel catfish. The anti-F. columnare serum was produced by actively immunizing (i.p. injection) channel catfish with sonicated whole cells or purified lipopolysaccharide (LPS) of F. columnare in Freund's adjuvant. Serum anti-F. columnare activity was verified by Western blotting and ELISA of serum. Normal serum and sterile culture broth were used as controls. Complement was inactivated in all sera by heating. After 48 h, passively immunized fish were challenged with virulent F. columnare by i.p. injection. A group of unchallenged fish served as controls. The immune response of catfish to the antigenic fractions was different when examined by Western blotting. Antibody produced with whole-cell antigen responded to a broad range of molecular weight components, while LPS antigens were restricted to a pair of bands near 20 kDa. Control fish injected with culture medium experienced 100% mortality 14 d post-challenge. Relative percent survival was 77 and 73 for catfish passively immunized with anti-LPS and anti-whole-cell serum, respectively. Results suggest that antibodies in the serum are involved in the protective immune response against columnaris disease in channel catfish.     

Response and function of cutaneous mucosal and serum antibodies in barramundi (Lates calcarifer) acclimated in seawater and freshwater

Mucosal and serum antibody responses were studied in sibling barramundi (Lates calcarifer) acclimated in either seawater or freshwater following vaccination by intraperitoneal injection or direct immersion in an inactivated Streptococcus iniae vaccine. As expected, route of vaccination had a marked effect on immune response, with direct immersion resulting in low serum antibody levels against S. iniae by ELISA detected 21 days post vaccination at 26 degrees C, whilst a significant response was detected in mucus. A strong specific antibody response was detected in both mucus and serum 21 days following intraperitoneal injection. Fish acclimated in seawater prior to vaccination showed a markedly higher specific mucosal antibody response than sibling fish acclimated in freshwater, regardless of the route of vaccination, whilst the serum antibody response was not affected by salinity. Both mucosal and serum antibodies from fish in seawater and freshwater were capable of binding antigen at salinities similar to full strength seawater in a modified ELISA assay. These results indicate that this euryhaline fish species is not only able to mount significant specific antibody response in cutaneous mucus, but that these antibodies will function in the marine environment.     

约氏疟原虫Pys48核酸疫苗传播阻断效应的实验研究

探讨约氏疟原虫（Plasmodium yoelii17XL）Pys48核酸疫苗免疫BALB/c小鼠的特异性抗体产生特点及其效应。将Pys48核酸疫苗肌肉内注射免疫BALB/c小鼠,并以空质粒注射组作为对照,3次免疫后通过P.y17XL攻击小鼠;采用ELISA检测免疫后小鼠血清中特异性抗体水平;通过P.y17XL感染小鼠,取其感染后第3天含有配子体的血液进行体外培养,观察合子、动合子的形成数量。ELISA结果显示疫苗免疫组小鼠血清特异性抗体滴度明显高于对照组;而合子、动合子数量明显低于对照组。提示Pys48核酸疫苗具有良好的免疫原性,免疫小鼠后可以建立起有效的传播阻断效应。     

南方鲇免疫球蛋白单克隆抗体的制备及特性

采用PEG沉淀结合Sepharose-4B柱层析法分离纯化了健康非免疫状态下南方鲇血清免疫球蛋白,在SDS-PAGE电泳条件下血清免疫球蛋白重链和轻链的分子量分别约为77 kD和27 kD。应用杂交瘤单克隆抗体技术制备了4个南方鲇免疫球蛋白特异性的单克隆抗体细胞株,并对这些单克隆抗体的特性进行了分析。经抗体亚级份测定,其中IgG1有2株,IgG2a有1株,IgG2b有1株;抗体滴度为104—106,有三株单抗具有Western-blot反应特性,识别南方鲇免疫球蛋白的重链。4株单抗都能特异地识别南方鲇、鲇的免疫球蛋白,而与鲫、草鱼、罗非鱼、斑点叉尾、光泽黄颡鱼血清以及水产动物常见病原菌如气单胞菌、爱德华氏菌、弧菌、柱状屈桡杆菌、沙门氏菌及大肠杆菌等无任何交叉反应。单克隆抗体F4-A12对纯化的南方鲇免疫球蛋白的检测灵敏度为31 ng。实验结果证明这些单抗具有高度特异、高度灵敏等特点,可用于南方鲇免疫球蛋白的结构分析、免疫应答水平监测和病原诊断,具有广阔的应用前景。     

Effect of immunization of channel catfish with inactivated trophonts on serum and cutaneous antibody titers and survival against Ichthyophthirius multifiliis

Two trials were conducted to determine the effect of immunization of channel catfish with inactivated trophonts on serum and cutaneous antibody titers and survival against Ichthyophthirius multifiliis Fouquet (Ich). In trial I, catfish were immunized intraperitoneally (IP) with: 1) 1% formalin-inactivated trophonts, 2) 3% formalin-inactivated trophonts and 3) freeze-thawed trophonts. Positive and negative control catfish were immunized with live theronts and 5% bovine serum albumin (BSA), respectively. At day 14, 28 and 50 post-immunizations, no statistical difference was noted in serum or cutaneous anti-Ich antibody titers to formalin-inactivated trophonts or freeze-thawed trophonts. The survival of catfish challenged with live theronts ranged from 33.3% to 43.3% for the formalin-inactivated or freeze-thawed trophonts at 50 d post-immunization. The survival of catfish immunized with live theront and BSA was 93.3 and 0%, respectively. In trial II, catfish were IP immunized with sonicated trophonts at doses of 1) 5 trophonts or 10.2 microg protein g(-1) fish, 2) 10 trophonts or 20.4 microg protein g(-1) fish, 3) 20 trophonts or 40.8 microg protein g(-1) fish, and 4) 5% BSA as the control. Fish immunized with 10 or 20 trophonts g(-1) fish showed highest serum (1/210 to 1/480) and cutaneous antibody titers (1/48 to 1/52), respectively, at 22 d post-immunization and survival (63.3-60.0%). The fish immunized with 5 trophonts g(-1) fish had titers of 1/52 and 1/12 for serum and cutaneous antibody and survival of 23.3%. BSA immunized catfish had background titers and a survival of 6.7%. There was a significant correlation between doses of sonicated trophonts used to immunize and catfish survival (correlation coefficient = 0.859, p < 0.01). These results indicate that doses of sonicated trophonts, but not formalin-inactivated or freeze-thawed trophonts provided both serum and cutaneous antibody responses and survival to live trophont challenge.     

Enhanced liposomal vaccine formulation and performance: simple physicochemical and immunological approaches

The Dtxd (Diphtheria toxoid) was the first antigen encapsulated within liposomes, their adjuvant properties were discovered (their capacity to enhance the vaccine immunogenicity). The point here is not to propose a new method to prepare this lipossomal vaccine. The central idea is to give new dresses for old vaccines by using classical and well-established liposome preparation method changing only the encapsulation pH and the immunization protocol.The most appropriate method of Dtxd encapsulation within liposome was based on lipid film hydration in 100 mM citrate buffer, pH 4.0. This was accompanied by changes on protein hydrophobicity, observed by CD and fluorescence spectroscopies. Whenever the Dtxd exposed its hydrophobic residues at pH 4.0, it interacted better with the lipossomal (observed by electrophoretic mobility) film than when its hydrophobic residues were buried (pH 9.0). The Dtxd partition coefficient in Triton-X114 and the acrylamide fluorescence quenching were also pH dependent. Both were bigger at pH 4.0 than at pH 9.0. The relationship protein structure and lipid interaction was pH dependent and now it can be easily maximized to enhance encapsulation of antigens in vaccine development.Mice were primed with formulations containing 5 mug of Dtxd within liposomes prepared in pH 4.0 or 7.0 or 9.0. The boosters were done 38 or 138 days after the first immunization. The IgM produced by immediate response of all lipossomal formulations were higher than the control (free protein). The response patterns and the immune maturity were measured by IgG1 and IgG2a titrations. The IgG1 titers produced by both formulations at pH 4.0 and 7.0 were at least 22 higher than those produced by mice injected lipossomal formulation at pH 9.0. When the boosters were done, 138 days after priming the mice produced a IgG2a titer of 29 and the group that received the booster 30 days after priming produced a titer of 25. The strongest antibody production was the neutralizing antibody (245 higher than the control) produced by those mice injected with lipossomal formulation at pH 4.0 with the booster done 138 days after priming. The simple change on lipossomal pH formulation and timing of the booster enhanced both antibody production and selectivity.