• IMMUNE NETWORK
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• 제13권3호
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• pp.81-85
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• 2013

The mucosal surfaces are constantly exposed to incoming pathogens which can cause infections that result in severe morbidity and/or mortality. Studies have reported that mucosal immunity is important for providing protection against these pathogens and that mucosal vaccination is effective in preventing local infections. For many years, the sublingual mucosa has been targeted to deliver immunotherapy to treat allergic hypersensitivities. However, the potential of vaccine delivery via sublingual mucosal has received little attention until recently. Recent studies exploring such potential have documented the safety and effectiveness of sublingual immunization, demonstrating the ability of sublingual immunization to induce both systemic and mucosal immune responses against a variety of antigens, including soluble proteins, inter particulate antigens, and live-attenuated viruses. This review will summarize the recent findings that address the promising potential of sublingual immunization in proving protection against various mucosal pathogens.

• Journal of Microbiology and Biotechnology
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• 제18권3호
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• pp.591-599
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• 2008

A murine model immunized by systemic and mucosal delivery of plasmid DNA vaccine expressing glycoprotein B (pCIgB) of pseudorabies virus (PrV) was used to evaluate both the nature of the induced immunity and protection against a virulent virus. With regard to systemic delivery, the intramuscular (i.m.) immunization with pCIgB induced strong PrV-specific IgG responses in serum but was inefficient in generating a mucosal IgA response. Mucosal delivery through intranasal (i.n.) immunization of pCIgB induced both systemic and mucosal immunity at the distal mucosal site. However, the levels of systemic immunity induced by i.n. immunization were less than those induced by i.m. immunization. Moreover, i.n. genetic transfer of pCIgB appeared to induce Th2-biased immunity compared with systemic delivery, as judged by the ratio of PrV-specific IgG isotypes and Th1- and Th2-type cytokines produced by stimulated T cells. Moreover, the immunity induced by i.n. immunization did not provide effective protection against i.n. challenge of a virulent PrV strain, whereas i.m. immunization produced resistance to viral infection. Therefore, although i.n. immunization was a useful route for inducing mucosal immunity at the virus entry site, i.n. immunization did not provide effective protection against the lethal infection of PrV.

• 대한약학회:학술대회논문집
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• 대한약학회 2003년도 Proceedings of the Convention of the Pharmaceutical Society of Korea Vol.1
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• pp.121-121
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• 2003

The purpose of this study is to investigate the effect of mucosal vaccine delivery vehicles and adjuvants on the local and systemic antibody responses following mucosal immunization of mice with hepatitis B surface antigen (HBsAg). Mice were immunized on days 0 and 21 by administration of hepatitis B surface antigen B (HBsAg) into the vagina. HBsAg was delivered in saline or poloxamer(Pol)-based vehicle containing mucoadhesive polycarbophil (PC). (omitted)

• 약학회지
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• 제38권1호
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• pp.67-77
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• 1994

In order to investigate the feasibility of transmucosal delivery of the model peptide, LHRH, metabolism of LHRH and inhibition effect of medium chain fatty acid salts were studied in rabbit mucosal homogenate. LHRH incubated in homogenates of rectal(RE), nasal(NA) and vaginal(VA) mucosa were assayed by HPLC. Five to six degradation products of LHRH were deterted and the degradation of LHRH$(500\;{\mu}g/ml)$ followed the first order kinetics. The main degradation products were found as $LHRH^{1-5}(M-I)$, $LHRH^{1-3}(M-II)$ and $LHRH^{1-6}(M-III)$ by the method of amino acid analysis. The half-lives of LHRH in the mucosal homogenates were found to be less than 20 min at protein concentration of 2.5 mg/ml with the order of VA>NA>RE mucosal homogenate. Medium chain fatty acid salts such as sodium caprylate $(C_8)$, sodium caprate $(C_{10})$ and sodium laurate $(C_{12})$ at the concentration of $0.5%{\sim}1.0%$ inhibit the proteolysis of LHRH significantly. The addition of sodium laurate(0.5%) into the NA and VA mucosal homogenates protected LHRH completely from the degradation.

• Journal of Pharmaceutical Investigation
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• 제22권3호
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• pp.173-183
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• 1992

To study the feasibility of transmucosal delivery of $[D-ala^2]-methionine$ enkephalinamide (YAGFM), its enzymatic degradation and stabilization in various rabbit mucosal extracts were investigated by HPLC method. The degradation of YAGFM was observed to follow the first-order kinetics and the half-lives of YAGFM in the nasal, rectal and vaginal mucosal extracts were found to be 25.7, 3.0 and 7.8 hr, respectively. However, there was no significant difference in degradation rates of YAGFM between the mucosal and serosal extracts obtained from the same mucosal membrane. This finding suggests that even a synthetic enkephalin analog, which is designed to be resistent to aminopeptidases, needs to be fully protected from the enzymatic degradation in mucosal sites for the delivery of the analog through mucosal routes. To inhibit the degradation of YAGFM in various mucosal extracts, effects of enzyme inhibitors such as bestatin (BS), amastatin (AM), thiorphan (TP), thimerosal (TM) and EDTA, alone or in combination, and modified cyclodextrins were observed by assaying YAGFM staying intact during 24 hr-incubation at $37^{\circ}C$. It was found from the results that mixed inhibitors such as TM (0.5 mM)/EDTA (5 mM) or AM $(50{\mu}M)/TM$ (0.5 mM)/EDTA (5 mM) provided very useful means for the stabilization in various mucosal extracts. The latter was found to protect YAGFM from the degradation in the nasal, rectal, and vaginal mucosal extracts by 90.9, 90.4 and 91.3%, respectively, after 24 hr-incubation, suggesting almost complete inhibition of YAGFM-degrading enzymes present in the incubation mixture. However, BS $(50{\mu}M)$, AM 50 $(50{\mu}M)$ or TP$(50{\mu}M)$ alone did not reveal sufficient inhibition except TM (0.5 mM) or EDTA (5 mM). The adddition of $2-hydroxylpropyl-{\beta}-cyclodextrin$(10%) to the nasal mucosal extract, and $dimethyl-{\beta}-cyclodextrin$(10%) to the rectal and vaginal mucosal extracts reduced the first-order rate constants for the degradation of YAGFM by 5.8, 17.3 and 8.9 times, respectively, compared to those with no additive.

• IMMUNE NETWORK
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• 제13권4호
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• pp.157-162
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• 2013

Application of vaccine materials through oral mucosal route confers great economical advantage in animal farming industry due to much less vaccination cost compared with that of injection-based vaccination. In particular, oral administration of recombinant protein antigen against foot-and- mouth disease virus (FMDV) is an ideal strategy because it is safe from FMDV transmission during vaccine production and can induce antigen-specific immune response in mucosal compartments, where FMDV infection has been initiated, which is hardly achievable through parenteral immunization. Given that effective delivery of vaccine materials into immune inductive sites is prerequisite for effective oral mucosal vaccination, M cell-targeting strategy is crucial in successful vaccination since M cells are main gateway for luminal antigen influx into mucosal lymphoid tissue. Here, we applied previously identified M cell-targeting ligand Co1 to VP1 of FMDV in order to test the possible oral mucosal vaccination against FMDV infection. M cell-targeting ligand Co1-conjugated VP1 interacted efficiently with M cells of Peyer's patch. In addition, oral administration of ligand-conjugated VP1 enhanced the induction of VP1-specific IgG and IgA responses in systemic and mucosal compartments, respectively, in comparison with those from oral administration of VP1 alone. In addition, the enhanced VP1-specific immune response was found to be due to antigen-specific Th2-type cytokine production. Collectively, it is suggested that the M cell-targeting strategy could be applied to develop efficient oral mucosal vaccine against FMDV infection.

• Molecules and Cells
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• 제22권2호
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• pp.175-181
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• 2006

Delivery of DNA vaccines to airway mucosa would be an ideal method for mucosal immunization. However, there have been few reports of a suitable gene delivery system. In this study we used a cationic emulsion to immunize mice via the intranasal route with pCMV-S coding for Hepatitis B virus surface antigen (HBsAg). Complexing pCMV-S with a cationic emulsion dramatically enhanced HBsAg expression in both nasal tissue and lung, and was associated with increases in the levels of HBs-specific Abs in serum and mucosal fluids, of cytotoxic T lymphocytes (CTL) in the spleen and cervical and iliac lymph nodes, and of delayed-type hypersensitivity (DTH) against HBsAg. In contrast, very weak humoral and cellular immunities were observed following immunization with naked DNA. In support of these observations, a higher proliferative response of spleenocytes was detected in the group immunized with the emulsion/pCMV-S complex than in the group immunized with naked pCMV-S. These findings may facilitate development of an emulsion-mediated gene vaccination technique for use against intracellular pathogens that invade mucosal surfaces.

• Journal of Plant Biotechnology
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• 제37권3호
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• pp.283-291
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• 2010

Vaccine is one of the best known and most successful applications of immunological theory to human health and it protects human life through inducing the immune response in systemic compartment. However, when we consider the fact that mucosal epithelium is exposed to diverse foreign materials including viruses, bacteria, and food antigens and protects body from entry of unwanted materials using layer of tightly joined epithelial cells, establishing the immunological barrier on the lining of mucosal surfaces is believed to be an effective strategy to protect body from unwanted antigens. Unfortunately, however, oral mucosal site, which is considered as the best target to induce mucosal immune response due to application convenience, is prone to induce immune tolerance rather than immune stimulation. Since intestinal epithelium is tightly organized, a prerequisite for successful mucosal vaccination is delivery of antigen to mucosal immune induction site including a complex system of highly specialized cells such as M cells. Consequently, development of efficient mucosal adjuvant capable of introducing antigens to mucosal immune induction site and overcome oral tolerance is an important subject in oral vaccine development. In this review, various approaches on the development of oral mucosal adjuvants being suggested for effective oral mucosal immune induction.

• IMMUNE NETWORK
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• 제12권5호
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• pp.165-175
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• 2012

Vaccination is one of the most effective methods available to prevent infectious diseases. Mucosa, which are exposed to heavy loads of commensal and pathogenic microorganisms, are one of the first areas where infections are established, and therefore have frontline status in immunity, making mucosa ideal sites for vaccine application. Moreover, vaccination through the mucosal immune system could induce effective systemic immune responses together with mucosal immunity in contrast to parenteral vaccination, which is a poor inducer of effective immunity at mucosal surfaces. Among mucosal vaccines, oral mucosal vaccines have the advantages of ease and low cost of vaccine administration. The oral mucosal immune system, however, is generally recognized as poorly immunogenic due to the frequent induction of tolerance against orally-introduced antigens. Consequently, a prerequisite for successful mucosal vaccination is that the orally introduced antigen should be transported across the mucosal surface into the mucosa-associated lymphoid tissue (MALT). In particular, M cells are responsible for antigen up-take into MALT, and the rapid and effective transcytotic activity of M cells makes them an attractive target for mucosal vaccine delivery, although simple transport of the antigen into M cells does not guarantee the induction of specific immune responses. Consequently, development of mucosal vaccine adjuvants based on an understanding of the biology of M cells has attracted much research interest. Here, we review the characteristics of the oral mucosal immune system and delineate strategies to design effective oral mucosal vaccines with an emphasis on mucosal vaccine adjuvants.

• 한국미생물생명공학회:학술대회논문집
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• 한국미생물생명공학회 2003년도 2003 Annual Meeting, BioExhibition and International Symposium
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• pp.55-62
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• 2003

The mucosal immune system provides a first line of defense against invasion of infectious agents via inhalation, ingestion and sexual contact. For the induction of protective immunity at these invasion sites, one must consider the use of the CMIS, which interconnects inductive tissues, including PP and NALT, and effector tissues of the intestinal, respiratory and genitourinary tracts. In order for the CMIS to induce maximal protective mucosal immunity, co-administration of mucosal adjuvant or use of mucosal antigen delivery vehicle has been shown to be essential. When vaccine antigen is administered via oral or nasal route, antigen-specific Th 1 and Th2 cells, cytotoxic T lymphocytes(CTLs) and IgA B cell responses are effectively induced by the CMIS. In the early stages of induction of mucosal immune response, the uptake of orally or nasally administered antigens is achieved through a unique set of antigen-sampling cells, M cells located in follicle-associated epithelium(FAE) of inductive sites. After successful uptake, the antigens are immediately processed and presented by the underlying DCs for the generation of antigen-specific T cells and IgA committed B cells. These antigen-specific lymphocytes are then home to the distant mucosal effector tissues for the induction of antigen-specific humoral(e.g., IgA) and cell-mediated (e.g., CTL and Th1) immune responses in order to form the first line of defense. Elucidation of the molecular/cellular characteristics of the immunological sequence of mucosal immune response beginning from the antigen sampling and processing/presentation by M cells and mucosal DCs followed by the effector phase with antigen-specific lymphocytes will greatly facilitate the design of a new generation of effective mucosal antigen-specific lymphocytes will greatly facilitate the design of a new generation of a new generation of effective mucosal adjuvants and of a vaccine deliver vehicle that maximizes the use of the CMIS.