ライフサイエンスコーパス: infection control

1 key settings, such as the built environment (infection control).

2 ing cyst production an attractive target for infection control.

3 ergillosis, indicating their contribution to infection control.

4 ciated risk factors in addition to inpatient infection control.

5 mpact of unit-level interventions to improve infection control.

6 t of T-cell immunity and resultant long-term infection control.

7 plemented as regular screening for effective infection control.

8 across cell membranes might be critical for infection control.

9 d virulence genes, are crucial for effective infection control.

10 ng in an antiviral state that is critical to infection control.

11 sion of K. pneumoniae in support of hospital infection control.

12 opment, treatment outcome and mortality, and infection control.

13 ng pathogens is critical in patient care and infection control.

14 ve been proposed for more extensive usage in infection control.

15 aceae have become a substantial challenge to infection control.

16 revolutionize diagnostics, epidemiology, and infection control.

17 s public health crisis exposed major gaps in infection control.

18 romote appropriate antimicrobial therapy and infection control.

19 ave an impact on both clinical treatment and infection control.

20 tending beyond the detection of conventional infection control.

21 personal protective equipment in healthcare infection control.

22 and, in the setting of outbreaks, suboptimal infection control.

23 iciency of this transmission is required for infection control.

24 hancing this defense offers a way to improve infection control.

25 spread of resistant bacteria is critical to infection control.

26 rovide evidence for WGS as an instrument for infection control.

27 and subpopulations, and the effectiveness of infection control.

28 l [CI], 55.9%-77.9%) had at least 1 lapse in infection control; 12 of 68 ASCs (17.6%; 95% CI, 9.9%-28

29 able treatment regimens and take appropriate infection control actions rather than prescribing empiri

30 ction of TB is essential to inform immediate infection control actions to minimize transmission risk.

31 multiplex PCR may help hospitals to improve infection control activities.

32 tment of TB, isoniazid preventive treatment, infection control, administration of ART, TB recording a

33 ng, adverse events, adherence promotion, and infection control, all within a multidisciplinary enviro

34 The future direction of infection control and anti-infective therapy will likely

35 This should be taken into consideration in infection control and antibiotic management decisions.

36 VSEfs), which has important implications for infection control and antibiotic stewardship.

37 accounted for, which suggests that improved infection control and antimicrobial stewardship may help

38 onnel to adhere to fundamental principles of infection control and aseptic technique (for example, re

39 ontaining organisms can significantly impact infection control and clinical practices, as well as the

40 Infection control and decontamination protocols for this

41 f group A Streptococcus (GAS) is crucial for infection control and epidemiology.

42 differentiate closely related pathogens for infection control and forensic purposes.

43 immune pathways and play important roles in infection control and immunomodulatory homeostasis.

44 discern the specific role of neutrophils in infection control and pathology in vivo revealed that al

45 le within healthcare facilities could inform infection control and patient management.

46 Current approaches to infection control and prevention have not been adequate

47 from Southern India highlight challenges of infection control and rapid diagnosis of resistant tuber

48 s and to accurately define new CDI cases for infection control and reimbursement purposes.

49 nd process engineering, survey a spectrum of infection control and safety challenges encountered by c

50 Although infection control and supportive therapies will remain t

51 Infection control and surveillance practices were also a

52 he international community to help implement infection control and surveillance.

53 We also summarize infection control and vaccination strategies for patient

54 ed the value of WGS as a tool for day-to-day infection control and, for some pathogens, as a primary

55 In the acute infection, control and SCI rats developed acute cystitis

56 ould be possible through improved nutrition, infection control, and accident prevention.

57 tion is important for epidemiologic studies, infection control, and decolonization measures.

58 iruses is paramount for effective treatment, infection control, and epidemiological surveillance.

59 s are critical for ID patient care, hospital infection control, and public health responses.

60 lay central roles in antibiotic stewardship, infection control, and quality improvement, particularly

61 general implications for population biology, infection control, and stabilization of quorum-sensing c

62 as antimicrobial stewardship, global health, infection control, and the microbiome, were addressed at

63 host cells, with important consequences for infection, control, and pathogenesis.

64 s include intensified case finding (ICF), TB infection control, antiretroviral therapy (ART), and iso

65 Clinical and infection control applications of the C(T) have yet to b

66 A proactive infection control approach is essential in burn units.

67 Our model suggests that without increased infection control approaches, CRE would become endemic i

68 health measures and scrupulous attention to infection control are required to prevent additional MER

69 rate diagnosis of influenza is important for infection control, as well as for patient management.

70 rn Illinois, including a case-control study, infection control assessment, and collection of environm

71 , patient interviews, clinic site visits and infection control assessments, and molecular sequencing

72 n key components identified: organisation of infection control at the hospital level; bed occupancy,

73 edicare & Medicaid Services (CMS) piloted an infection control audit tool in a sample of ASC inspecti

74 tive infection risk factors and adherence to infection control best practice metrics had no impact on

75 Infection control best practices were monitored perioper

76 he triad of tissue engineering would require infection control, biomaterials, and stem cells.

77 Identified infection control breaches during AMBG included shared u

78 (HCV) infection that were unattributable to infection control breaches were identified at a health c

79 had lapses identified in 3 or more of the 5 infection control categories.

80 ed key roles for these lysosomal pathways in infection control, cell death, inflammation, cancer, neu

81 he delivery of critical care presents unique infection control challenges and unique opportunities to

82 implementation the International Nosocomial Infection Control Consortium multidimensional approach f

83 The International Nosocomial Infection Control Consortium ventilator-associated pneum

84 e the effect of the International Nosocomial Infection Control Consortium's multidimensional approach

85 the methodology of International Nosocomial Infection Control Consortium.

86 n of this phenotype for proper treatment and infection control decisions requires that these coagulas

87 ug-resistant tuberculosis in the 1990s, poor infection control, delayed diagnosis, and a high HIV pre

88 ness by reducing demand through vaccination, infection control, diagnostics, public education, incent

89 Implementing effective infection control during and after admission may limit f

90 of nosocomial HCV transmission, emphasizing infection control, early diagnosis, and therapy.

91 Infection control, early surgical debridement, and antib

92 no specific control measures, facility-level infection control efforts (uncoordinated control measure

93 Enhanced infection control efforts are unlikely to account for su

94 Strengthening infection control efforts in hospitals is crucial for co

95 Improving infection control efforts is thought to be a contributin

96 integration of certain hospital factors into infection control efforts may help reduce MDRO infection

97 biology laboratory is being asked to support infection control efforts through the early identificati

98 ce in MRSA isolates is important to hospital infection control efforts, relevant to patient outcomes

99 g in delays that complicate patient care and infection control efforts.

100 ng carbapenemase genes could greatly benefit infection control efforts.

101 ovide strain-related information relevant to infection control epidemiology and disease prognosis.

102 Surprisingly, despite the absence of infection control, expansion of Vgamma2Vdelta2 T cells a

103 Infection control for hospital pathogens such as methici

104 This case questions whether current infection control guidelines are sufficient for Q fever-

105 t patients is low when currently recommended infection control guidelines for the viral hemorrhagic f

106 ble isolation chamber, which conforms to CDC infection control guidelines, was found to be feasible w

107 ers can be minimized by adherence to current infection control guidelines.

108 sion of Ad14 highlight the need to reinforce infection control guidelines.

109 Assessments focused on 5 areas of infection control: hand hygiene, injection safety and me

110 es a second paradigm shift, from the classic infection control hierarchy to a novel, decentralized ap

111 ion of effective strategies for tuberculosis infection control, improved understanding of where trans

112 Multiple infection control improvements led to the reduced incide

113 e in neutrophil migration and, consequently, infection control in diabetic mice with mild sepsis (MS)

114 organisms in patients with cystic fibrosis, infection control in hospital and outpatient settings is

115 The poor quality of infection control in many rural facilities is a serious

116 to become an increasingly valuable tool for infection control in the near future.

117 ts, highlighting a specific need for careful infection control in these patients.

118 S aureus infection control in vivo and IL-1beta release from cell

119 cy unit in London, United Kingdom, during an infection control incident in November and December 2007

120 Appropriate infection control, including performing laser or electro

121 In response, Israel established a national infection control infrastructure.

122 While infection control initiatives have stemmed the rising pr

123 results show the importance of prioritising infection control interventions (eg, prospective molecul

124 A), with the results being used to institute infection control interventions aimed at preventing tran

125 Our findings should inform future infection control interventions and encourage the applic

126 and to determine whether changes to hospital infection control interventions would have an impact on

127 ncluded the following measures: 1) bundle of infection-control interventions; 2) education; 3) outcom

128 Aggressive multifaceted horizontal infection control is an effective strategy for reducing

129 Therefore, infection control is critical for wound care.

130 Infection control is especially critical, given that mos

131 reatment options and associated clinical and infection control issues.

132 treatment success rates, a lack of airborne infection control, limited drug-resistance testing, and

133 lipopolysaccharide (LPS) or M. tuberculosis infection, control macrophages increased NO synthesis, b

134 apid carbapenemase detection is critical for infection control management.

135 that the clones responded differently to an infection control measure based on the use of topical an

136 This readily implementable infection control measure may result in decreased infect

137 y that would allow for the implementation of infection control measures and also improve antimicrobia

138 Infection control measures and an appreciation of the co

139 We reviewed patient records and infection control measures and interviewed health care p

140 nically in outbreak investigations to inform infection control measures and to determine appropriate

141 f the diagnosis, complications, therapy, and infection control measures associated with influenza.

142 Infection control measures can reduce the risk of Mycoba

143 This article describes infection control measures developed to strengthen the h

144 Infection control measures for air travel need to be und

145 BL-Ec (P < .0001), despite implementation of infection control measures in 75% of ESBL-Kp index patie

146 port, complemented by universal tuberculosis infection control measures in healthcare facilities.

147 , population mobility patterns, adherence to infection control measures in hospital settings, and hos

148 Special infection control measures may be warranted.

149 The effect of hospital infection control measures may differ between different

150 MERS-CoV, how to make a diagnosis, and what infection control measures need to be instituted when a

151 empirical evidence for the effectiveness of infection control measures on aircraft and at borders.

152 by universal implementation of tuberculosis infection control measures should be prioritized.

153 Infection control measures should focus not only on prev

154 ht the potential value of tailoring hospital infection control measures to specific pathogen subtypes

155 int effectiveness of several known influenza infection control measures used in general hospitals, we

156 reatment initiation, culture conversion, and infection control measures were compared to a time perio

157 a high-dependency unit (HDU) where standard infection control measures were in place.

158 ccessful, including reinforcement of general infection control measures, alongside chemical disinfect

159 INTERPRETATION: In the presence of standard infection control measures, health-care workers were inf

160 In the presence of standard infection control measures, health-care workers were inf

161 revention of transmission requires stringent infection control measures, making C. auris a potential

162 Alongside infection control measures, removal of key antibiotic se

163 In an endemic setting with well-implemented infection control measures, ward-based contact with symp

164 ated settings or with high baseline level of infection control measures.

165 well as for the effective implementation of infection control measures.

166 nes could help guide therapy and appropriate infection control measures.

167 biota, and the results obtained should guide infection control measures.

168 tals in a region coordinate surveillance and infection control measures.

169 of treatment beds introduced alongside other infection control measures.

170 Surveillance and infection-control measures are critical to a global publ

171 a quality-improvement directive to intensify infection-control measures, extremely drug-resistant (XD

172 nd the paucity of new drugs in the pipeline, infection control must be our primary defence for now.

173 scrub nurses, and telephone interviews with Infection Control Nurses.

174 well-established roles of T-regs in chronic infection, control of immune homeostasis, and autoimmune

175 rculating toxin and elimination of C. tetani infection, control of spasms and convulsions, maintenanc

176 l response can affect its ability to mediate infection control or to induce autoimmunity, but the mec

177 e of antifungal prophylaxis, improvements in infection control, or changes in catheter insertion prac

178 ing programs, and yet several authorities in infection control organizations have questioned the appr

179 ded community hospitals enrolled in the Duke Infection Control Outreach Network.

180 and 1 ambulatory surgery center in the Duke Infection Control Outreach Network.

181 h hospitals over 1 year (2013-14) to compare infection control performance.

182 Major improvements in laboratory capacity, infection control, performance of tuberculosis control p

183 ystematic covert monitoring was performed by infection control personnel to assure accuracy and lack

184 lities must hold this concept central to any infection control plan and act in a preventive manner.

185 hip programmes, public health interventions, infection control policies, and antimicrobial developmen

186 hese findings provide important insights for infection control practice and signpost areas for interv

187 es and unique opportunities to augment usual infection control practice with specific source-control

188 aning, and antibiotic stewardship); advanced infection control practices (ie, active surveillance, ch

189 HAI surveillance definitions.The Healthcare Infection Control Practices Advisory Committee, a federa

190 g TBIC measures, and the impact of stigma on infection control practices and implementation.

191 Classical infection control practices are only partially effective

192 atients combined with effective multifaceted infection control practices can reduce the transmission

193 gic malignancy unit, which followed the same infection control practices except for the mask policy.

194 filtration, and strict compliance with basic infection control practices for blood culture procuremen

195 Infection control practices for methicillin-resistant St

196 hospitals regularly used several fundamental infection control practices for MRSA and MDR-AB (ie, con

197 Strict infection control practices have been implemented for he

198 Little is known about infection control practices in ASCs.

199 l attention to antimicrobial stewardship and infection control practices is essential to curb this no

200 stic and surveillance testing and subsequent infection control practices may be impacted by the frequ

201 he injection, medication handling, and other infection control practices of all staff under their sup

202 f MRSA colonization or infection facilitates infection control practices that are effective at limiti

203 he extent to which hospital characteristics, infection control practices, and compliance with prevent

204 ine surveillance for most IFIs, adherence to infection control practices, and health-care provider aw

205 Implementation of standard infection control practices, including active screening

206 r Disease Control and Prevention recommended infection control practices, including use of personal p

207 One Health" strategy, fully resourcing basic infection control practices, not performing universal sc

208 We evaluated infection control practices, performed a GAS carriage st

209 In concert with routine infection control practices, the average MB found for th

210 on at 2 transfer hospitals having acceptable infection control practices.

211 treatment, culture conversion, and improved infection control practices.

212 al SSI risk factors and adherence to current infection control practices.

213 cility licensing inspections that scrutinize infection control practices.

214 biotic regimens, intensive care measures and infection control practices.

215 ce or may be spread between patients by poor infection control practices.

216 udit tool, assessed compliance with specific infection control practices.

217 nd promoting strict adherence to established infection control practices.

218 urveillance), promoted better adherence with infection control practices.

219 epidemiological investigations and influence infection control practices.

220 ded valuable information that will influence infection control practices.

221 es has important implications for optimizing infection control practices; establishing antimicrobial

222 be preventable through adherence to current infection control practices; however, the etiology of wo

223 as improved and more rigorous management and infection-control practices have been adopted for treati

224 umonia rates; and 6) performance feedback of infection-control practices.

225 lance is necessary for identifying lapses in infection-control practices.

226 Ultimately, infection control practitioners and clinical microbiolog

227 Strict infection control precautions and a well-prepared hospit

228 ocycline and rifampin with and without other infection control precautions on our rates of central li

229 ared P. aeruginosa strains, strict universal infection control precautions, and hospital design and v

230 uncohorted patients; monitoring adherence to infection control precautions, including unwavering atte

231 th minocycline and rifampin and implementing infection control precautions.

232 whether success occurs independent of other infection control precautions.

233 hat was independent and complementary to the infection control precautions.

234 d for accelerated institution of appropriate infection control precautions.

235 ination still occurred due to a breakdown in infection control procedures indicated by contamination

236 ine the routes of spread so that appropriate infection-control procedures can be implemented.

237 In our hospital with an established infection control program designed to contain transmissi

238 Key components of an effective infection control program include the following: 1) pre-

239 ed skin integrity in residents, a suboptimal infection control program, and lack of awareness of infe

240 rticularly if successful hospital-based MRSA infection control programmes are maintained.

241 These results suggest that community infection control programmes targeting transmission of C

242 should be a central component of C difficile infection control programmes.

243 ectal colonization with CPO, which can guide infection control programs to limit the spread of these

244 the importance of antibiotic stewardship and infection control programs to prevent this disease in ch

245 ignificant pathogens is generally useful for infection control programs, specific data supporting use

246 underlining the urgent need for tuberculosis infection-control programs.

247 rall by initiating appropriate treatment and infection control protocols sooner and by possibly reduc

248 a-lactamases (ESBLs) for epidemiological and infection control purposes and also for the potential of

249 aecium and E. faecalis, a feature useful for infection control purposes that is not a function of BEA

250 To forestall disastrous consequences, infection control, rapid case detection, effective treat

251 1) reeducation of ICU personnel on issues of infection control related to external cerebral ventricul

252 of clusters, enabling effective targeting of infection control resources.

253 The interdisciplinary infection control risk assessment team can address key e

254 renovated intensive care unit as part of the infection control risk assessment team.

255 Performing infection control risk assessments and implementing the

256 than between infection (SE-treated) and non-infection (control) samples within line.

257 ard transmission is affected by standards of infection control, sanitation, access to clean water, ac

258 ld-type SIV infection and uncontrolled HIV-1 infection, controlled SIV/HIV-1 infection did not result

259 mary information on outbreaks is provided by infection control staff at hospitals and includes questi

260 alyzed at the Department of Microbiology and Infection Control, Statens Serum Institut, Copenhagen, D

261 nt difference in trends preimplementation of infection control strategies (annual decrease of 8.0%; 9

262 CUs over a 10-year period, during which time infection control strategies (care bundles) were impleme

263 rengthening TB treatment programs, effective infection control strategies are urgently needed to redu

264 ds before as well as after implementation of infection control strategies can be facilitated using da

265 We evaluated whether horizontal infection control strategies could decrease the prevalen

266 Implementation of infection control strategies in PICU captured through a

267 ons, enhanced community and outpatient-based infection control strategies may be needed to prevent CA

268 utility of laboratory screening and various infection control strategies, and the available laborato

269 ing the need for more efficient surveillance/infection control strategies.

270 epidemic transmission models used to design infection control strategies.

271 ther ExPEC strains and design more efficient infection control strategies.

272 tion, and inform appropriate therapeutic and infection control strategies.

273 associated with timing of implementation of infection control strategies.

274 Unfortunately, infection control studies have not routinely accounted f

275 Infection control studies often rely on infection endpoi

276 To ensure validity, infection control studies should incorporate study desig

277 tibiotic resistant organisms are intensified infection control, surveillance, and antimicrobial stewa

278 Continuous vigilance and strengthening of infection control systems will shape the capacity to pre

279 ing, delayed diagnosis, and the breakdown of infection control systems.

280 oportion of new cases, both groups should be infection control targets.

281 uberculosis infection; however, tuberculosis infection control (TBIC) measures are often poorly imple

282 During phase 1, the infection control team at each intensive care unit condu

283 The hospital infection-control team identified 12 infants colonised w

284 cing to validate and expand findings from an infection-control team who assessed the outbreak through

285 se preliminary findings may be of benefit to infection control teams.

286 ay not be completely preventable by standard infection-control techniques.

287 ines were driven by improvements in hospital infection control, then transmitted (secondary) cases sh

288 use of rapid detection of BI/NAP1/027 as an infection control tool are still awaited.

289 , specific, and timely enough to serve as an infection control tool.

290 gly provided in outpatient settings in which infection control training and oversight may be inadequa

291 ldren participating in the Early Pseudomonas Infection Control trial who received standardized therap

292 f transmission were not self-sustaining when infection control was implemented, but that R in the abs

293 portance of fluoroquinolone restriction over infection control was shown by significant declines in i

294 We also demonstrated that the impaired infection control we observed in the absence of MyD88 co

295 g a sample of US ASCs in 3 states, lapses in infection control were common.

296 tissue engineering approaches for addressing infection control while simultaneously initiating bone r

297 Improving respiratory virus infection control will likely require closing knowledge

298 rnalization kinetics play a critical role in infection control within a granuloma, controlling whethe

299 and IL-10 concentrations is essential to Mtb infection control, within a single granuloma, with minim

300 change in the institutional culture whereby infection control would become the responsibility of eve