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A Skin Prep System (SPS) has been developed to provide a well-tolerated and controlled method of stratum corneum disruption using mild abrasion as part of transcutaneous immunization (TCI). In this study, four groups ( n = 10) of volunteers were pretreated with the SPS using three different lengths of mild abrasive strips (13 mm, 25 mm and 38 mm), or a handheld applicator. They then received a vaccine patch containing 50 μg of the heat-labile enterotoxin from Escherichia coli (LT) at day 0 and day 21. Subsequent anti-LT IgG antibody responses were dependent on abrasive strip length, with highest immune responses seen after use of the longest strip. The development of a simple, single-use, disposable device that is well-tolerated and allows disruption to be modulated represents an important step forward in physical penetration enhancement for the skin.

Background. Transcutaneous immunization (TCI) is a needle-free technique that delivers antigens and adjuvants to potent epidermal immune cells. To address critical unmet needs in biodefense against anthrax, we have designed a novel vaccine delivery system using a dry adhesive patch that simplifies administration and improves tolerability of a subunit anthrax vaccine. Methods. Mice and rabbits were vaccinated with recombinant protective antigen of Bacillus anthracis and the heat-labile toxin of Escherichia coli. Serologic changes, levels of toxin-neutralizing antibodies (TNAs), and pulmonary and nodal responses were monitored in the mice. A lethal aerosolized B. anthracis challenge model was used in A/J mice, to demonstrate efficacy. Results. The level of systemic immunity and protection induced by TCI was comparable to that induced by intramuscular vaccination, and peak immunity could be achieved with only 2 doses. The addition of adjuvant in the patch induced superior TNA levels, compared with injected vaccination. Conclusions. Anthrax vaccine patches stimulated robust and functional immune responses that protected against lethal challenge. Demonstration of responses in the lung suggests that a mechanism exists for protection against challenge with aerosolized anthrax spores. A formulated, pressure-sensitive, dry adhesive patch, which is stable and can be manufactured in large scale, elicited comparable immunoglobulin G and TNA responses, suggesting that an anthrax vaccine patch is feasible and should advance into clinical evaluation.

In this trial, 50 healthy adults 18 to 40 years of age received an intradermal injection of one fifth the standard dose of an influenza vaccine. The resulting increases in hemagglutination-inhibition titers were at least similar to those elicited by the standard dose of vaccine administered intramuscularly to 50 control subjects. 50 healthy adults received an intradermal injection of one fifth the standard dose of an influenza vaccine. The use of reduced doses of vaccine may be one way of expanding a limited supply of vaccine. Vaccination against influenzavirus is an important public health measure to help protect against the annual morbidity and mortality associated with influenza. A major global supplier of influenza vaccine recently experienced manufacturing problems that led regulatory authorities to declare more than 48 million doses, almost half the U.S. supply of influenza vaccine, unfit for use. 1 This has created a public health crisis, with widespread shortages leaving many in the United States without vaccine coverage. Various emergency measures are being considered in an effort to expand the supply and consist either of reducing the intramuscular dose or importing doses from manufacturers that . . .

The skin is an attractive target for vaccine delivery. Topical application of adjuvants results in potent immune responses and good safety profiles. Adjuvants can be coadministered in a patch with vaccine antigens (transcutaneous immunization) or similar delivery format, or administered separately with an injection or IS™ patch (Iomai), leading to enhanced immune responses. These observations have moved into the clinic, highlighting the likelihood that skin delivery of vaccines will play an important future role in vaccine applications.

Enterotoxigenic Escherichia coli (ETEC) is a major cause of travellers' diarrhoea. We investigated the rate of diarrhoea attacks, safety, and feasibility of a vaccine containing heat-labile enterotoxin (LT) from ETEC delivered to the skin by patch in travellers to Mexico and Guatemala. In this phase II study, healthy adults (aged 18–64 years) who planned to travel to Mexico or Guatemala and had access to a US regional vaccination centre were eligible. A centralised randomisation code was used for allocation, which was masked to participants and site staff. Primary endpoints were to investigate the field rate of ETEC diarrhoea, and to assess the safety of heat-labile toxins from E coli (LT) delivered via patch. Secondary endpoints included vaccine efficacy against travellers' diarrhoea and ETEC. Participants were vaccinated before travel, with two patches given 2–3 weeks apart. Patches contained either 37·5 μg of LT or placebo. Participants tracked stool output on diary cards in country and provided samples for pathogen identification if diarrhoea occurred. Diarrhoea was graded by the number of loose stools in 24 h: mild (three), moderate (four or five), and severe (at least six). Analysis was per protocol. The trial is registered with ClinicalTrials.gov, number NCT00516659. Recruitment closed after 201 participants were assigned patches. 178 individuals received two vaccinations and travelled and 170 were analysed. 24 (22%) of 111 placebo recipients had diarrhoea, of whom 11 (10%) had ETEC diarrhoea. The vaccine was safe and immunogenic. The 59 LT-patch recipients were protected against moderate-to-severe diarrhoea (protective efficacy [PE] 75%, p=0·0070) and severe diarrhoea (PE 84%, p=0·0332). LT-patch recipients who became ill had shorter episodes of diarrhoea (0·5 days vs 2·1 days, p=0·0006) with fewer loose stools (3·7 vs 10·5, p<0·0001) than placebo. Travellers' diarrhoea is a common ailment, with ETEC diarrhoea illness occurring in 10% of cases. The vaccine patch is safe and feasible, with benefits to the rate and severity of travellers' diarrhoea. IOMAI Corporation.

An enterotoxigenic Escherichia coli (ETEC) vaccine could reduce diarrhea among children in developing countries and travelers to these countries. The heat-labile toxin (LT) of ETEC is immunogenic but too toxic for oral or nasal vaccines. In a double-blind, placebo-controlled trial, 59 adults were randomized to receive 50 μg of LT or placebo in a patch applied to alternating arms on days 0, 21, and 42. On day 56, 27 vaccinees and 20 controls were challenged orally with 6 × 10 8 cfu of LT +/ST + ETEC. 100 and 97% of vaccinees had 4-fold increases in anti-LT IgG and IgA, and 100 and 90% developed IgG- and IgA-antibody-secreting cell responses. The study did not meet the primary endpoint: 82% of vaccinees and 75% of controls had moderate to severe ETEC illness. However, vaccinees with ETEC illness had lower numbers (6.8 versus 9.7, p = 0.04) and weights of loose stools (840 g versus 1147 g, p < 0.05), a decreased need for intravenous fluids (14% versus 40%, p = 0.03) and a delayed onset of diarrhea (30 h versus 22 h, p = 0.01). Transcutaneous LT vaccination induced anti-toxin immune responses that did not prevent but mitigated illness following a high-dose challenge with a virulent LT +/ST + ETEC strain.

The elderly have greater morbidity and mortality due to influenza, and respond poorly to influenza vaccination compared to younger adults. This study was designed to determine if the adjuvant heat-labile enterotoxin from Escherichia coli (LT), administered as an immunostimulant (IS) patch on the skin with influenza vaccination, improves influenza immune responses in the elderly. Three weeks following vaccination, hemagglutination inhibition (HAI) responses in LT IS patch recipients showed improvement over those of elderly receiving vaccine alone, as demonstrated by significance or trends in fold rise [A/Panama ( P = 0.004), A/New Caledonia ( P = 0.09)], seroconversion [A/New Caledonia (63% versus 40%, P = 0.01), A/Panama (54% versus 36%, P = 0.08)] and seroprotection [26%, 20% and 16% greater for the patch group for A/New Caledonia, A/Panama and B/Shandong strains, respectively]. The data suggest that an LT IS patch may further enhance influenza vaccine immune responses in the elderly.

The skin is an attractive target for vaccine delivery. Adjuvants and antigens delivered into the skin can result in potent immune responses and an unmatched safety profile. The heat- labile enterotoxin (LT) from Echerichia coli, which acts both as antigen and adjuvant, has been shown to be delivered to human skin efficiently when used in a patch, resulting in strong immune responses. Iomai scientists have capitalized on these observations to develop late-stage products based on LT. This has encouraged commercial-level product development of a delivery system that is efficient, user-friendly and designed to address important medical needs. Over the past 2 years, extensive clinical testing and optimization has allowed the patch to evolve to a late-stage product. As a strategy for approval of a revolutionary vaccine-delivery system, the singular focus on optimization of LT delivery has enabled technical progress to extend patch-vaccine product development beyond LT. The field efficacy of the LT-based travelers' diarrhea vaccine has validated this approach. The discussion of transcutaneous immunization is unique, in that any consideration of the adjuvant must also include delivery, and the significant advances in a commercial patch application system are described. In this review, we integrate these concepts, update the clinical data and look to the future.

The use of adjuvants to enhance the immune response to novel pandemic influenza vaccine candidates may overcome the poor immune responses seen in immunologically naïve populations. The confluence of a highly pathogenic H5N1 influenza virus and the widespread absence of pre-existing immunity has driven the search for effective strategies for immunization in the face of a lethal pandemic. The potent adjuvant, heat labile enterotoxin from E. coli (LT), placed over the immunization site in a patch, is a novel adjuvant strategy for immune enhancement, and was evaluated using an H5N1 injectable vaccine. In this observer-blind, placebo-controlled clinical study, 500 healthy adults 18–49 years of age were randomized to receive two intramuscular doses of A/Vietnam/1194/2004 A/H5N1 vaccine (5 μg, 15 μg or 45 μg) or placebo (saline) 21 days apart. For each of the influenza vaccine doses, a 50 μg LT adjuvant patch was applied over the injection site at either the second or both immunizations and the HI responses (titers) were compared to H5N1 vaccine alone. The study's primary endpoint was safety, and secondary immunogenicity endpoints were evaluated using European (CHMP) licensure criteria. The vaccine was safe and well tolerated, and subjects generally lacked pre-existing H5N1 immunity. The single-dose injection 45 μg HA/LT patch regimen met all CHMP licensure criteria, including a 73% seroprotection rate compared to 49% seroprotection without a patch. Significant adjuvant effects were seen at all HA doses on Day 21. By contrast, only modest adjuvant effects were observed with the boosting regimen in subjects first primed with H5N1 alone and given the adjuvant patch only on the second immunization. The two-injection/two-patch 45 μg HA regimen achieved significantly higher titers and GMFR compared to injection alone (GMFR 33.1 vs. 16.9, HI 226 vs. 94, p < 0.05) and a 94% seroprotection rate. The LT adjuvant patch placed over the injection site was safe, significantly enhanced the immune response to an H5N1 candidate vaccine, and achieved a 73% seroprotection rate after a single dose. The LT adjuvant patch has more modest benefits in recently primed populations similar to other candidate vaccine adjuvants, but a two-dose patch plus injection regimen resulted in robust HI responses.

Background An enterotoxigenicEscherichia coli(ETEC) vaccine could reduce diarrhea among children in developing countries and travelers to these countries. The heat-labile toxin (LT) of ETEC is immunogenic but too toxic for oral or nasal vaccines. Methods In a double-blind, placebo-controlled trial, 59 adults were randomized to receive 50μg of LT or placebo in a patch applied to alternating arms on days 0, 21, and 42. On day 56, 27 vaccinees and 20 controls were challenged orally with 6x108cfu of LT+/ST+ETEC. Results 100 and 97% of vaccinees had 4-fold increases in anti-LT IgG and IgA, and 100 and 90% developed IgG- and IgA-antibody-secreting cell responses. The study did not meet the primary endpoint: 82% of vaccinees and 75% of controls had moderate to severe ETEC illness. However, vaccinees with ETEC illness had lower numbers (6.8 versus 9.7,p=0.04) and weights of loose stools (840g versus 1147g,p<0.05), a decreased need for intravenous fluids (14% versus 40%,p=0.03) and a delayed onset of diarrhea (30h versus 22h,p=0.01). Conclusions Transcutaneous LT vaccination induced anti-toxin immune responses that did not prevent but mitigated illness following a high-dose challenge with a virulent LT+/ST+ETEC strain.