ライフサイエンスコーパス: reactogenicity

1 llum assembly or motility, is sufficient for reactogenicity.

2 novel ways to increase dosage and to reduce reactogenicity.

3 man volunteers, suggesting a role for Hap in reactogenicity.

4 nt of V. cholerae culture may play a role in reactogenicity.

5 improve vaccine efficacy but often increase reactogenicity.

6 the safety assessment of local and systemic reactogenicity.

7 ese adjuvants induce some local and systemic reactogenicity.

8 tive RNA vaccine without triggering unwanted reactogenicity.

9 ated, with mild solicited local and systemic reactogenicity.

10 endosomal escape while reducing inflammatory reactogenicity.

11 les can lead to toxicity, and their possible reactogenicity.

12 f seroconversion and is associated with less reactogenicity.

13 associate signatures with immunogenicity and reactogenicity.

14 ants reported predominantly mild-to-moderate reactogenicity.

15 y as well as the influence on any local skin reactogenicity.

16 S-specific T-cell and B-cell responses, and reactogenicity.

17 ain reaction-confirmed influenza and vaccine reactogenicity.

18 304, 6.2-12.6 and 27 [9%] of 293, 6.4-13.1) reactogenicity.

19 -19 vaccine that is immunogenic with minimal reactogenicity.

20 antibodies, S-specific T-cell responses, and reactogenicity.

21 The primary end points were safety and reactogenicity.

22 dent viraemia occurred in concert with early reactogenicity.

23 vants display unacceptable local or systemic reactogenicity.

24 e expected to be devoid of local or systemic reactogenicity.

25 in combination with PF03512676 had enhanced reactogenicity.

26 V2.S vaccine, we assessed immunogenicity and reactogenicity 28 days after a homologous or heterologou

27 bstudy, of whom 80 (89%) were assessable for reactogenicity, 75 (83%) were assessable for evaluation

28 Reactogenicity, adverse events, and baseline GMCs were s

29 Local and systemic reactogenicity, adverse events, binding and neutralising

30 e second dose or a third dose was lower than reactogenicity after a first dose.

31 Reactogenicity after a late second dose or a third dose

32 Reactogenicity after each dose and safety up to 1 year a

33 Primary outcomes: (1) reactogenicity after first dose; (2) antibody responses

34 eumatic/inflammatory disorders, but enhanced reactogenicity after live vaccination may occur in those

35 Vaccine virus replication and reactogenicity after monovalent Dengue virus vaccination

36 Moderate, transient reactogenicity after vaccination occurred more frequentl

37 possible role for hemagglutinin/protease in reactogenicity, although other factors may also contribu

38 le on COVID-19 vaccine booster or third dose reactogenicity among pregnant and lactating individuals.

39 whom 30 were included in immunogenicity and reactogenicity analyses.

40 The main outcomes for the reactogenicity analysis were symptoms following vaccine

41 as not administered because of the increased reactogenicity and a lack of meaningfully increased immu

42 nd tolerability were evaluated by collecting reactogenicity and adverse event data.

43 re assessed by evaluating local and systemic reactogenicity and adverse events in all participants.

44 Reactogenicity and adverse events were monitored through

45 Reactogenicity and adverse events were monitored.

46 Safety (reactogenicity and adverse events) and efficacy against

47 rimary endpoints included local and systemic reactogenicity and adverse events.

48 the vaccine, assessed as local and systemic reactogenicity and adverse events.

49 vaccines, as assessed by local and systemic reactogenicity and adverse events.

50 painless skin vaccination with reduced local reactogenicity and at least sustained immunogenicity.

51 Safety evaluations included solicited reactogenicity and coagulation parameters.

52 nks between PEG-specific antibodies, vaccine reactogenicity and enhanced clearance of other PEG-conta

53 the 5 x 10(5) dose showed similar safety and reactogenicity and greater immunogenicity when compared

54 Reactogenicity and immune responses to cAd3-EBO vaccine

55 ata on COVID-19 messenger RNA (mRNA) vaccine reactogenicity and immunogenicity in pregnancy and for t

56 n-label trial in the United States evaluated reactogenicity and immunogenicity of 2 vaccination regim

57 Here we report the reactogenicity and immunogenicity of a delayed second do

58 Coprimary outcomes were safety and reactogenicity and immunogenicity of anti-spike IgG meas

59 In a prospective double-blind trial, the reactogenicity and immunogenicity of recombinant baculov

60 On the basis of reactogenicity and immunogenicity, a dose level of 10 mu

61 On the basis of reactogenicity and immunogenicity, a dose level of 10 ug

62 However, systemic reactogenicity and missed activities were significantly

63 2) were associated with more frequent severe reactogenicity and more adverse events than were vaccine

64 Both vaccines were well tolerated, with mild reactogenicity and no serious adverse events related to

65 Data on reactogenicity and other adverse events and blood and na

66 atched strains at day 29 and to evaluate the reactogenicity and safety of mRNA-1083.

67 Reactogenicity and safety of QIV was consistent with TIV

68 Reactogenicity and safety were also assessed.

69 d interim analysis, the primary endpoints of reactogenicity and safety were assessed by blinded study

70 ers against serogroups ACWY, and to evaluate reactogenicity and safety.

71 ratory-confirmed COVID-19, and assessment of reactogenicity and safety.

72 Reactogenicity and serious adverse events were monitored

73 Regression models considered the outcomes of reactogenicity and seroconversion, controlling for all s

74 ility of a mouse model for assessing vaccine reactogenicity and strongly indicate that the fever foll

75 nflammatory pulmonary diseases is limited by reactogenicity and suboptimal delivery.

76 Solicited, self-limiting local, systemic reactogenicity and unsolicited adverse events were simil

77 to the associated antigen without increased reactogenicity, and are currently being tested in Phase

78 e report the preliminary findings on safety, reactogenicity, and cellular and humoral immune response

79 Primary endpoints were safety and reactogenicity, and HA and NA antibody responses against

80 Data are limited on the comparative safety, reactogenicity, and health-related quality of life (HRQO

81 Data are needed on the comparative safety, reactogenicity, and health-related quality of life (HRQO

82 mary and secondary objectives of the safety, reactogenicity, and humoral immunogenicity of a quadriva

83 study objectives were assessment of safety, reactogenicity, and humoral immunogenicity of mRNA-1010,

84 The primary end points were safety, reactogenicity, and humoral immunogenicity on trial days

85 We assessed the safety, reactogenicity, and immunogenicity of a viral vectored c

86 This study assessed the safety, reactogenicity, and immunogenicity of an injectable cell

87 We aimed to assess safety, reactogenicity, and immunogenicity of ExPEC4V in healthy

88 rimary objectives were to assess the safety, reactogenicity, and immunogenicity of mRNA-1273.214 at 2

89 e 1 dose-ranging study evaluated the safety, reactogenicity, and immunogenicity of mRNA-1345 in adult

90 The safety, reactogenicity, and immunogenicity of the CCIV and the e

91 In this trial we compared the safety, reactogenicity, and immunogenicity of the vaccine antige

92 1 of 3 doses and were monitored for safety, reactogenicity, and immunogenicity.

93 inferiority trial evaluating vaccine safety, reactogenicity, and immunogenicity.

94 Present vaccines are immunogenic, of low reactogenicity, and protective, but protection has varie

95 mpare vaccine candidates for immunogenicity, reactogenicity, and response to challenge; investigate t

96 cipants were monitored for vaccine shedding, reactogenicity, and RSV serum antibodies, and followed o

97 Cellular immunogenicity, reactogenicity, and safety appeared to be comparable bet

98 r-blinded study assessed the immunogenicity, reactogenicity, and safety of an inactivated, split-viri

99 ized study, we evaluated the immunogenicity, reactogenicity, and safety of the AS01E-adjuvanted RSV p

100 HZ/su cellular immunogenicity, reactogenicity, and safety were also assessed.

101 Immunogenicity, reactogenicity, and safety were assessed.

102 rised additional immunogenicity assessments, reactogenicity, and safety.

103 developed for local reactogenicity, systemic reactogenicity, and specific individual AEs.

104 anti-spike protein response, 7-day solicited reactogenicity, and unsolicited adverse events.

105 ralizing antibodies; cell-mediated immunity; reactogenicity; and safety.

106 d heat-killed Shigella vaccines with minimal reactogenicity are the mutant toxin molecules.

107 The molecular bases of reactogenicity are unknown, but it has been speculated t

108 duced transgene expression and dose-limiting reactogenicity, as highlighted by recent clinical trials

109 Primary safety endpoints included reactogenicity assessed for the first 7 days and all adv

110 eatment; medical staff performing safety and reactogenicity assessments or blood draws for immunogeni

111 High reactogenicity associated with an increased dose of vCP1

112 antigens by developing biomarkers of vaccine reactogenicity associated with potential adverse events.

113 well tolerated but was associated with more reactogenicity at the highest dose.

114 d cytokine recall responses but reduced skin reactogenicity at the injection site.

115 It displayed no reactogenicity at the site of injection, no tissue disea

116 to provide tools to identify inflammatory or reactogenicity biomarkers.

117 olysin and MARTX toxin contribute to vaccine reactogenicity but that the genes for these toxins can b

118 We examined ways of reducing their reactogenicity by modifying lipid A, the endotoxic part

119 Reactogenicity cannot be used to predict immunity after

120 nt, causing increased serosal hemorrhage and reactogenicity compared to its parent.

121 otein expression without causing significant reactogenicity compared to LNPs containing ALC-0315.

122 3, but not NVX, increased transient systemic reactogenicity compared with homologous schedules.

123 as a heterologous booster, demonstrates less reactogenicity compared with mRNA vaccines, which, if co

124 igher incidence and an increased severity of reactogenicity compared with the Novavax protein-based C

125 We solicited symptoms of reactogenicity daily for 7 days after each vaccination a

126 , children received 1 dose of 2010/2011 TIV, reactogenicity data were collected for 7 days, and anoth

127 -1 was at high dose and all others were low; reactogenicity decreased with the incorporation of other

128 While reducing local reactogenicity, EPD of OVA/LPS/CpG and BCG vaccine gener

129 Primary safety endpoints included reactogenicity events and adverse events (AEs) through 7

130 Secondary outcomes were solicited reactogenicity events and unsolicited adverse events (AE

131 Local and systemic reactogenicity events from the third dose were generally

132 The most common reactogenicity events were headache (n = 4,923) and body

133 Most common reactogenicity events were injection site tenderness and

134 Most reactogenicity events were mild or moderate in severity

135 Most reactogenicity events were mild/moderate; severe events

136 Preliminary local and systemic reactogenicity events were more common in the vaccine gr

137 BNT162b2 reactogenicity events were mostly mild to moderate, with

138 In older adults, reactogenicity events were predominantly mild or moderat

139 Primary safety endpoints included reactogenicity events within 7 days and adverse events (

140 A/H1N1 strains, but was associated with more reactogenicity events.

141 nically observed Trumenba local and systemic reactogenicity fell on the 26th and 93rd percentiles of

142 CFU, self-limited (<48-h duration) objective reactogenicity (fever, diarrhea, or dysentery) developed

143 titres and a gene signatures associated with reactogenicity (Geneva cohort) was identified correlatin

144 Vaccine reactogenicity has complicated the development of safe a

145 Reactogenicity hinders worldwide implementation of the o

146 In a blinded, placebo-controlled study, the reactogenicity, immunogenicity, and clinical efficacy of

147 etry, contributing directly to immunological reactogenicity in bone marrow-derived dendritic cells.

148 though TIV was well tolerated in all groups, reactogenicity in children <5 years old was slightly gre

149 racts of mice and ferrets, and have very low reactogenicity in ferrets.

150 nt of safety, assessed as local and systemic reactogenicity in the 7 days after each vaccination and

151 irus, a vaccine candidate that retained mild reactogenicity in the upper respiratory tracts of 1-mont

152 Local reactogenicity in the vaccine groups was common, but the

153 genes from Vibrio cholerae induce a residual reactogenicity in up to 10% of vaccinees.

154 rimary series and yearly boosters and causes reactogenicity in up to 30% of vaccine recipients.

155 n attenuated vaccine candidate with residual reactogenicity in very young infants, namely, cpts248/40

156 ellular responses (i.e., protein expression, reactogenicity) in multiple cell models.

157 cine providing durable immunity with minimal reactogenicity is needed.

158 unity without incurring any significant skin reactogenicity is urgently needed for cutaneous vaccinat

159 h dose immunization results in minimal local reactogenicity, is well-tolerated, and does not elevate

160 The primary outcomes were reactogenicity; laboratory values (serum chemistry and h

161 s reported fever; only 1 reported any severe reactogenicity (local pain/soreness, chills, arthralgia,

162 CoronaVac vaccine was associated with low reactogenicity, low immunogenicity but reduced incidence

163 s are often associated with toxic effect and reactogenicity, necessitating expanding the repertoire o

164 Reactogenicity occurred in 8 of 23 recipients of CVD 120

165 Reactogenicity occurred less frequently and was of lower

166 The highest reactogenicity occurred when DENV-1 was at high dose and

167 Similar clinical reactogenicity occurred with both vaccines.

168 Using this mouse model, we explored the reactogenicity of 4CMenB components by measuring changes

169 We compared the immunogenicity and reactogenicity of a fractional dose of IPV (one fifth of

170 An open study assessed immunogenicity and reactogenicity of a heterologous booster dose of A/turke

171 The immunogenicity and reactogenicity of a homologous or heterologous booster i

172 s in Geneva to assess the immunogenicity and reactogenicity of a novel recombinant aP (r-aP) vaccine

173 vaccine and assessed the immunogenicity and reactogenicity of a subsequent dose of trivalent influen

174 Despite a higher observed reactogenicity of AS01-containing vaccines, no safety co

175 r biology, clinical spectrum of illness, and reactogenicity of candidate live dengue virus vaccines o

176 We compared the immunogenicity and reactogenicity of Cervarix or Gardasil human papillomavi

177 COVID-19 outcomes and the immunogenicity and reactogenicity of COVID-19 mRNA vaccination among patien

178 the relationship between immunogenicity and reactogenicity of COVID-19 vaccines.

179 The primary end points were the safety and reactogenicity of each dose schedule.

180 protease that modulates the pathogenesis and reactogenicity of epidemic V. cholerae.

181 that a trxA mutation might be used to reduce reactogenicity of live attenuated vaccine strains.

182 enterotoxicity in rabbit ileal loops and the reactogenicity of live cholera vaccine candidates.

183 have mucinase activity and contribute to the reactogenicity of live vaccine candidates, but its role

184 Safety and reactogenicity of MenACWY were also assessed.

185 to-head comparison of the immunogenicity and reactogenicity of PCV10 and PCV13.

186 The immunogenicity and reactogenicity of SARS-CoV-2 vaccines in patients with c

187 r clinical development can be limited by the reactogenicity of some of the most potent preclinical ad

188 The safety and reactogenicity of the 2 vaccines were assessed on the ba

189 the study were the evaluation of safety and reactogenicity of the adjuvanted recombinant zoster vacc

190 result demonstrated that IL-1 contributed to reactogenicity of the rVSV, but was dispensable for indu

191 assessed using logistic regression, and the reactogenicity of the vaccines was compared.

192 activity in vitro did not correlate with the reactogenicity of V. cholerae vaccine candidates.

193 study was to compare the immunogenicity and reactogenicity of vaccines delivered in either consisten

194 tro has been suggested to correlate with the reactogenicity of Vibrio cholerae vaccine candidates.

195 ic drop in incidence, concerns regarding the reactogenicity of wP vaccines led to the development of

196 ection) and tolerability (local and systemic reactogenicity) of the vaccine, and the secondary outcom

197 s, and solicited injection site and systemic reactogenicity on the day of study product administratio

198 on Phase 1/2 trials, evaluating the safety, reactogenicity, optimal doses, routes of administration,

199 participants with mild, moderate, and severe reactogenicity or adverse events, graded as per the Divi

200 No statistically significant differences in reactogenicity or immunogenicity were detected between s

201 The primary composite reactogenicity outcome was the proportion of participant

202 Reactogenicity outcomes were proportions of injection si

203 Primary safety and reactogenicity outcomes were unsolicited adverse events

204 fety data were collected including immediate reactogenicity, post-dosing toxicology ascertained 24 h

205 ework for the further development of vaccine reactogenicity predictive models.

206 file, with mainly transient mild-to-moderate reactogenicity (predominantly injection-site pain [in 79

207 quential administration and had a safety and reactogenicity profile consistent with both vaccines adm

208 ar immune responses were correlated with the reactogenicity profile of subjects and did not differ be

209 The reactogenicity profile of TDV was acceptable, and simila

210 e regimens were well tolerated, with similar reactogenicity profiles among them.

211 H56:IC31 showed acceptable reactogenicity profiles irrespective of dose, number of

212 y relevant difference between the safety and reactogenicity profiles of the 2 vaccines.

213 ntibody titres at day 28, local and systemic reactogenicity profiles, adverse events, and serious adv

214 accines had clinically acceptable safety and reactogenicity profiles.

215 ine formulations and the placebo had similar reactogenicity profiles.

216 of gE while retaining acceptable safety and reactogenicity profiles.

217 beit analysis by age indicated greater local reactogenicity rates for adolescents (46% for TAK-003 an

218 Treatment was well tolerated with reactogenicity rates similar to those seen in non-pregna

219 Reactogenicity rates were similar in LAIV and placebo re

220 At 3 x 10(5) pfu, early-onset reactogenicity remained frequent (45 [88%] of 51 compare

221 nses; however, balancing immunogenicity with reactogenicity remains problematic.

222 stinct physiological (temperature/heart rate/reactogenicity) response-patterns not seen with non-adju

223 1]) and were monitored for vaccine shedding, reactogenicity, RSV-antibody responses and RSV-associate

224 Reactogenicity, safety, and immunogenicity measured by h

225 Reactogenicity/safety of the revaccination dose were sim

226 RSV administered to 6- to 7-month-olds had a reactogenicity/safety profile like other childhood vacci

227 nted FLU-aQIV and RSVPreF3 OA had acceptable reactogenicity/safety profiles when co-administered in >

228 A novel reactogenicity scoring framework accounting for the freq

229 AEs were mostly expected reactogenicity signs and symptoms.

230 as common, but the frequency and severity of reactogenicity signs or symptoms did not differ between

231 Reactogenicity solicited for 7 days, other safety events

232 be further enrolled in an immunogenicity and reactogenicity sub-study to evaluate the safety profile

233 Children enrolled in the immunogenicity and reactogenicity sub-study will have blood drawn before va

234 The most frequently reported systemic reactogenicity symptoms in the active vaccine groups wer

235 Predictive models were developed for local reactogenicity, systemic reactogenicity, and specific in

236 The primary endpoints were safety and reactogenicity (take rate) of CCSV.

237 ent the results of secondary immunogenicity, reactogenicity, tetanus toxoid IgE-mediated immune respo

238 t immunogenic and was associated with higher reactogenicity than the BNT162b2 and Ad26.COV2.S booster

239 -Hist did not exhibit the immunogenicity and reactogenicity that can limit repeated LNP dosing.

240 fy putative biomarkers of early inflammation/reactogenicity that could guide the design of subsequent

241 separated by 2-6 months, local and systemic reactogenicity that is significantly greater than observ

242 Among participants with severe reactogenicity, the mean (SD) EQ-5D-5L Index score decre

243 Reactogenicity, the occurrence of adverse local/systemic

244 participants had injection site and systemic reactogenicity, these symptoms were mostly mild to moder

245 and immunogenic cell death and (3) favouring reactogenicity through the modulation of factors that co

246 p short-term immunity and may have increased reactogenicity to coronavirus disease 2019 (COVID-19) va

247 Here, we used an infant rabbit model of reactogenicity to determine what V. cholerae factors tri

248 valuation included analyses of postinjection reactogenicity, unsolicited adverse events (AEs), seriou

249 An accurate prediction of vaccine reactogenicity using in vitro assays and computational m

250 Systemic reactogenicity varied by vaccine and correlated with imm

251 Reactogenicity was absent or mild in the majority of par

252 Immunization reactogenicity was also reviewed.

253 Reactogenicity was assessed for 7 days after vaccination

254 In this interim analysis, safety and reactogenicity was assessed in all individuals who recei

255 Reactogenicity was assessed up to 7 days after vaccinati

256 Clinical reactogenicity was assessed, and state-of-the-art immuno

257 Reactogenicity was associated with adjuvant but not with

258 Mild to moderate injection site and systemic reactogenicity was common but brief.

259 Reactogenicity was comparable between groups.

260 stration of mRNA COVID-19 and IIV4 vaccines, reactogenicity was comparable in both groups.

261 Mild-to-moderate early-onset reactogenicity was frequent but transient (median, 1 day

262 Reactogenicity was generally mild and transient.

263 Reactogenicity was generally mild or moderate and resolv

264 mild to moderate in severity; injection site reactogenicity was greater in vaccination groups receivi

265 Reactogenicity was higher after the booster injection bu

266 Reactogenicity was higher with Ad26.COV2.S than with pla

267 Reactogenicity was largely mild to moderate and transien

268 Reactogenicity was lower after the second dose.

269 Systemic reactogenicity was mild in all groups.

270 All reported local and systemic reactogenicity was mild to moderate in severity.

271 Reactogenicity was mild, transient, and most commonly re

272 Reactogenicity was minimal with doses of 5 x 10(10) vp o

273 containing 15, 45, or 135 microg of each HA, reactogenicity was minor.

274 Reactogenicity was monitored to day 7 and unsolicited ad

275 Transient local reactogenicity was more frequently seen at the higher do

276 Reactogenicity was mostly mild to moderate and transient

277 Local reactogenicity was observed after administration of N6LS

278 Self-limited reactogenicity was observed after the initial immunizati

279 Self-limited reactogenicity was observed after the initial immunizati

280 Mild to moderate reactogenicity was observed after vaccination, with symp

281 Primarily mild or moderate reactogenicity was observed in both vaccine groups but w

282 Reactogenicity was predominantly mild to moderate in sev

283 More pronounced local reactogenicity was seen with the intradermal and subcuta

284 BCG was well tolerated, and reactogenicity was similar between groups, regardless of

285 Reactogenicity was similar to that of mRNA-1273 vaccines

286 Reactogenicity was similar to that reported for the prim

287 lant recipients undergoing mRNA vaccination, reactogenicity was similar to that reported in the origi

288 Local and systemic reactogenicity was transient and self-limiting.

289 ticipants reported solicited and unsolicited reactogenicity; we measured IgG binding, neutralizing an

290 ticipants reported solicited and unsolicited reactogenicity; we measured immunoglobulin G binding, ne

291 Local and systemic reactogenicities were consistent with intramuscular need

292 Rates of local and systemic reactogenicities were higher with 3A-HBV compared with 1

293 odified intention-to-treat basis; safety and reactogenicity were assessed in the intention-to-treat p

294 Solicited symptoms of reactogenicity were assessed, and all safety assessments

295 RSV serum antibodies, vaccine shedding, and reactogenicity were assessed.

296 ccurrence and severity of local and systemic reactogenicity were similar across active groups.

297 Safety and reactogenicity were similar with the two booster vaccine

298 ustly activate newborn DCs but can result in reactogenicity when delivered in soluble form.

299 nistration of rBCG was associated with local reactogenicity, whereas intravenous and intradermal admi

300 (saRNA-5mC) has demonstrated reduced vaccine reactogenicity while maintaining robust humoral response