ライフサイエンスコーパス: medicine

1 ersonalized to a given individual (precision medicine).

2 work best for which patients (ie, precision medicine).

3 been extensively used in traditional Chinese medicine.

4 ts in matter to the study of human health in medicine.

5 e mechanisms for advancement of personalized medicine.

6 represents a major barrier in cardiovascular medicine.

7 SCs) holds enormous promise for regenerative medicine.

8 ng-known and has many applications including medicine.

9 put allergy research on the map of precision medicine.

10 ication in cancer treatment and regenerative medicine.

11 ave a significant impact on cancer precision medicine.

12 es, including organogenesis and regenerative medicine.

13 for noninvasive clinical analysis and sports medicine.

14 ates the relevance of photocontrol in future medicine.

15 related to MPYS-mediated human diseases and medicine.

16 pplications in genome research and precision medicine.

17 ciplinary areas of science, engineering, and medicine.

18 ramming holds great promise for regenerative medicine.

19 ic cells for drug discovery and personalized medicine.

20 ery), opening new dimensions in personalized medicine.

21 great interest in the field of regenerative medicine.

22 mics studies and in the setting of precision medicine.

23 herapeutic ramifications for transplantation medicine.

24 them invaluable in the field of regenerative medicine.

25 of funding for cancer research and precision medicine.

26 stages of life - from preconception to adult medicine.

27 formatics analyses, and ultimately precision medicine.

28 these technologies will alter the future of medicine.

29 edicine, and molecular knowledge-based redox medicine.

30 stroke and realise the promise of precision medicine.

31 of disease and the realization of precision medicine.

32 biology, clinical research and personalized medicine.

33 e therefore highly desirable in regenerative medicine.

34 h new tissue is a major goal of regenerative medicine.

35 P. notoginseng are the parts used to produce medicine.

36 infection-targeted imaging in cardiovascular medicine.

37 iac biology, drug discovery and regenerative medicine.

38 umor evolution, is a key challenge in cancer medicine.

39 vel drug targets or markers for personalised medicine.

40 stent with standard procedures in laboratory medicine.

41 al models, and develop new cannabinoid-based medicine.

42 cells remains a major challenge in precision medicine.

43 y, as a reflection of the power of precision medicine.

44 udy advances the goals of liver regenerative medicine.

45 teome baseline is essential for personalized medicine.

46 understanding of viruses in transplantation medicine.

47 sing appropriate stem cells for regenerative medicine.

48 r translational applications in regenerative medicine.

49 ad use in basic research, biotechnology, and medicine.

50 nitors with great potential for regenerative medicine.

51 s hold great promise for achieving precision medicine.

52 thesis testing, and the promise of precision medicine.

53 ials for tissue engineering and regenerative medicine.

54 seminal fluid, and its role in evolution and medicine.

55 ytokines have potential uses in research and medicine.

56 y an important role in individualized cancer medicine.

57 tial steps toward advancing cancer precision medicine.

58 to be used in the practice of cardiovascular medicine.

59 HR) systems have transformed the practice of medicine.

60 n is still not confirmed despite advances in medicine.

61 about specific treatments in cardiovascular medicine.

62 opment and form the foundation for precision medicine.

63 ominence across diverse areas of biology and medicine.

64 s for both disease modeling and regenerative medicine.

65 pies an attractive strategy for personalized medicine.

66 ineages in disease modeling and regenerative medicine.

67 the full potential of plasma in biology and medicine.

68 foundation for developing PCC/PGL precision medicine.

69 n smartphones and tablets profoundly affects medicine.

70 s one of the greatest achievements in all of medicine.

71 with immediate implications for personalized medicine.

72 tance for realizing the promise of precision medicine.

73 oxicity is a long-standing concern of modern medicine.

74 to use in drug development and regenerative medicine.

75 in liquids in modern chemistry, biology, and medicine.

76 assembly lines to produce new materials and medicines.

77 omponents of catalysts, natural products and medicines.

78 employees of a company that produced herbal medicines.

79 gredients (e.g. in soup or bread) and herbal medicines.

80 xacerbated by tumour resistance to available medicines.

81 potential of predatory bacteria as cellular medicines.

82 ignificant challenge in the discovery of new medicines.

83 nes are also used as flavors, fragrances and medicines.

84 wledge) has aided the discovery of important medicines.

85 ines, biological probes, and even commercial medicines.

86 orders, Valvular Heart Disease, and Vascular Medicine (1-84).

87 to use at least one blood pressure-lowering medicine (adjusted odds ratio [OR] 2.23, 95% CI 1.59-3.1

88 d Drug Administration (FDA) and the European Medicines Agency (EMA) between 2003 and 2013.

89 ood and Drug Administration and the European Medicines Agency-should be preferentially used as second

90 the design of synthetic molecules for use in medicine, agriculture, and materials.

91 metabolites (SMs) are extremely important in medicine and agriculture, but regulation of their biosyn

92 e advantage of this historic opportunity for medicine and also basic human biology.

93 d incorporated into Society of Critical Care Medicine and American Heart Association/Pediatric Advanc

94 herapy, tissue engineering, and regenerative medicine and are frequently used in preclinical mouse mo

95 iscovery of mRNA capping, how my training in medicine and biochemistry merged as I evolved into a vir

96 because of their (potential) application in medicine and biotechnology and as a potential source for

97 standard platform not only for regenerative medicine and developmental biology but also for biophysi

98 r applying stem cell biology to regenerative medicine and disease modeling.

99 vivo gene-editing applications in precision medicine and drug discovery and aid in the development o

100 he application of principles of personalized medicine and in decision making for targeted therapy of

101 d they thus have revolutionary potential for medicine and industry.

102 Nazi medicine and its atrocities have been explored in depth

103 Overtreatment is pervasive in medicine and leads to potential patient harms and excess

104 d the potential for applications in biology, medicine and materials chemistry.

105 The Society of Nuclear Medicine and Molecular Imaging and the American College

106 he RADAR committee of the Society of Nuclear Medicine and Molecular Imaging, based on 2007 recommenda

107 r disease subtyping is crucial for precision medicine and personalized treatment of complex diseases.

108 core disciplines that enable high-definition medicine and project how these technologies will alter t

109 and for clinical decision support systems in medicine and self-diagnostic symptom checkers has substa

110 about how they will die and the emphasis by medicine and society on intervention and cure has someti

111 sms over time and more broadly addresses how medicine and surgery apply the knowledge and technology

112 nts with type 2 diabetes admitted to general medicine and surgery services in hospital in the non-int

113 .6 units per kg or less, admitted to general medicine and surgery services.

114 The Institute of Medicine and the International Committee of Medical Jour

115 d from chemicals in the diet and traditional medicines and from lipid peroxidation products, in human

116 ith important implications for conservation, medicine, and agriculture.

117 s including tissue engineering, regenerative medicine, and cell and therapeutic delivery.

118 ogy into nutritional sciences, environmental medicine, and molecular knowledge-based redox medicine.

119 ncentration for clinical diagnostics, sports medicine, and the food industry.

120 apy has not yet entered the era of precision medicine, and there have been no approaches to adjust do

121 description are critical to the practice of medicine, and to ophthalmology in particular.

122 ibution of low-cost, high-quality antifungal medicines; and concomitant integration of fungal disease

123 nted potential for a variety of regenerative medicine applications including novel drug delivery plat

124 rs for early disease detection and precision medicine applications.

125 its potential role in personalized exercise medicine applications.

126 riety of tissue engineering and regenerative medicine applications.

127 techniques that could facilitate a precision medicine approach for ARDS.

128 ia will be heavily influenced by a precision medicine approach, with rapid diagnostic techniques of b

129 ntial to facilitate development of precision medicine approaches for CHD and other diseases associate

130 owledge can be obtained with systems biology/medicine approaches that account for the complexity of h

131 e sharing of these data to promote precision medicine approaches to the diagnosis and treatment of ca

132 L biology and the basis for future precision medicine approaches to this disease.

133 the basis for implementing precision cancer medicine approaches.

134 parative therapeutic value of all new cancer medicines approved by the US Food and Drug Administratio

135 to Brazil that is widely used in traditional medicine as a physical and mental stimulant.

136 of young talented women choosing science and medicine as their professional career over the past deca

137 computational deep phenotyping and precision medicine as well as integration of clinical data into tr

138 The demonstrated precise printing of medicines as films, without the use of solvents, can acc

139 ell as the American Society for Reproductive Medicine, Asia Pacific Society of Human Genetics, Britis

140 ary structures offers an effective, precise, medicine-based approach to directly impede transcription

141 e widely employed in chemistry, biology, and medicine because of their exquisite specificity and sust

142 ulatory and effector pathways will precision medicine become a reality with selective and effective a

143 with implications for fields as divergent as medicine, biodiversity conservation, agriculture and spa

144 ntation at Tufts University School of Dental Medicine, Boston, Massachusetts, from June 1, 2006 to Ma

145 stitute a promising fast assay for precision medicine, bridging the gap between genotype and phenotyp

146 ling not just basic research in personalized medicine but also accurate diagnostics and monitoring dr

147 oming popular in the context of personalized medicine, but a new study shows that these models could

148 role in tissue engineering and regenerative medicine by functioning as biomimetic substrates to mani

149 indicate that a commonly prescribed diabetic medicine can restrain mitochondrial metabolism and tumor

150 istilled into the world's traditional herbal medicines can be reinterpreted and exploited through the

151 63 travel and tropical medicine clinics in 30 countries.

152 nual health habits screen in the PCP general medicine clinics were studied.

153 psychiatry, nursing, hospice and palliative medicine, communication skills, health disparities, and

154 nd limitations exist when applying precision-medicine concepts in leukemia and myelodysplastic syndro

155 d leukemias and the limitations of precision-medicine concepts in MDS.

156 onuclide therapy (TRT) is a branch of cancer medicine concerned with the use of radioisotopes, radiol

157 Thus, when exiting the nuclear medicine department, the NET patients injected with (68)

158 ghlight the potential of traditional Chinese medicine-derived drug leads.

159 ished recently in the New England Journal of Medicine describe the utility of abiraterone acetate, an

160 The Digital Imaging and Communications in Medicine (DICOM) standard is widely adopted for image an

161 concepts and their resulting applications to medicine discovery.

162 es and sources in order to support precision medicine, disease modeling, and mechanistic exploration.

163 Each village has two community medicine distributors (CMDs), who are the seed nodes and

164 For critical medicines, drug rechallenge may be appropriate when 1) n

165 rd certified in cardiology and critical care medicine ("dual-boarded cardiologists").

166 ram from the European Association of Nuclear Medicine (EANM) (PSFEARL).

167 Experimental medicine (EM) offers an approach that can help investiga

168 critical applications in different fields in medicine, engineering and technology but their enhanced

169 tions in tissue engineering and regenerative medicine, followed by a summary and perspective on futur

170 has been widely applied in food industry and medicine for a long time.

171 Precision medicine for alcohol use disorder (AUD) allows optimal t

172 biomarkers in drug development and precision medicine for CNS disorders.

173 ways carry a C1-INH-HAE information card and medicine for emergency use.

174 ent of the 1983 Nobel Prize in Physiology or Medicine for her discovery of transposable elements in m

175 In our efforts to generate a new medicine for liver fibrosis, we sought to identify impro

176 as been used in clinical routines in nuclear medicine for more than 60 y-as (131)I for diagnostic and

177 among the most promising concepts in nuclear medicine for optimizing and individualizing treatments f

178 ized therapeutic interventions and precision medicine for optimizing clinical care of these individua

179 to the development of improved regenerative medicine for patients with white matter disorders.

180 ing of the 2016 Nobel Prize in Physiology or Medicine for research in autophagy.

181 Cannabis has been known as a medicine for several thousand years across many cultures

182 and opened up new prospects for personalized medicine for the fetus.

183 e, E209, which meets key requirements of the Medicines for Malaria Venture drug candidate profiles.

184 Discovery of first-in-class medicines for treating cancer is limited by concerns wit

185 Investigation of botanical folk medicines for wounds and infections led us to study Schi

186 t precise or versatile enough for customized medicine formulation and manufacture.

187 Advances in cardiovascular medicine fueled by innovative clinical trials have drama

188 The vision of a precision medicine-guided approach to novel cancer drug developmen

189 International Collaboration for Transfusion Medicine Guidelines (the use of leukoreduction and plate

190 International Collaboration for Transfusion Medicine Guidelines.

191 g vaccination to MSM who visit genitourinary medicine (GUM) clinics.

192 In cancer, precision medicine has been nearly synonymous with genomics.

193 onal Academies of Sciences, Engineering, and Medicine has made 14 recommendations that require ongoin

194 widely available treatment modality in sleep medicine, has not been systematically studied in the PD

195 alation study conducted at Baylor College of Medicine, Houston Methodist Hospital, and Texas Children

196 Human Genetics, British Society for Genetic Medicine, Human Genetics Society of Australasia, Profess

197 current analysis was to test this precision medicine hypothesis of the PREDICT study via analyses of

198 Success on the internal medicine (IM) examination is a central requirement of th

199 educe radiation exposure from CT and nuclear medicine imaging in accord with the as-low-as-reasonably

200 He was elected to the Institute of Medicine in 2005.

201 cal complexity and to move towards precision medicine in COPD, we need to integrate (bioinformatics)

202 ent knowledge on the potential for precision medicine in food allergy, drug allergy, and anaphylaxis

203 ntion of liver diseases as well as precision medicine in hepatology.

204 d can aid in the development of personalized medicine in humans.

205 Antibiotics have revolutionised medicine in many aspects, and their discovery is conside

206 promising resource of cells for regenerative medicine in neurological disorders.

207 ethod at the Washington University School of Medicine in St Louis, Missouri.

208 translate mouse model findings to precision medicine in the clinic on the organoid platform.

209 to the implementation of truly personalized medicine in the clinic.

210 Moving toward precision medicine in the field of transplantation will require tr

211 large quaternary referral center for genomic medicine in the Northwest of England.

212 We also outline the potential of precision medicine in transplantation.

213 ower Silesia Regional Centre of Occupational Medicine in Wroclaw, Poland.

214 is one of the most prescribed cardiovascular medicines in China, its therapeutic indications and mech

215 Their future outlook in regenerative medicine including the current clinical significance of

216 cause of their potential use in personalized medicine, including cancer-targeting treatments for pati

217 mographic, medical condition, and prescribed medicine information of adults 40 years and older betwee

218 Deceased donation medicine involves unique ethical challenges.

219 RATIONALE: The Institute of Medicine (IOM) standards for guideline development have

220 Precision medicine is an emerging integrative approach for disease

221 Underpinning the vision of precision medicine is the concept that causative mutations in a pa

222 A major challenge in regenerative medicine is to improve therapeutic cells' delivery and t

223 The essential job of precision medicine is to match the right drugs to the right patien

224 es for the controlled loading and release of medicines is presented.

225 Shamans, including medicine-men, mediums, and the prophets of religious mov

226 , as well as approaches that apply precision medicine methods to populations with the increased risk,

227 suicide, we investigated whether a precision medicine model using administrative data after outpatien

228 areas of nanobio-technology such as nanobio-medicine, nanobio-sensing, as well as nanoelectronics wi

229 (eg, physicians in intensive care, emergency medicine, neurology, neurosurgery, pulmonology) who may

230 ough the multidisciplinary nature of nuclear medicine (NM) and clinical molecular imaging is a key st

231 ists of education and reassurance, analgesic medicines, non-pharmacological therapies, and timely rev

232 etically engineered T cells are powerful new medicines, offering hope for curative responses in patie

233 tial therapeutic application in regenerative medicine or angiogenesis-related diseases is drawing inc

234 The 2017 Nobel Prize in Medicine or Physiology has been awarded to Jeffrey Hall,

235 ology and ecology, promising applications in medicine or plant pathology.

236 As interest has grown in precision medicine over the past decade, the principle of companio

237 In this perspective, we apply the precision medicine paradigm to the emerging use of extracorporeal

238 Severe burnout is common in critical care medicine physician assistants.

239 risk factors for burnout among critical care medicine physician assistants.

240 eterogeneous lesions as defined by 2 nuclear medicine physicians (P < 0.05).

241 itative interviews of surgeons and emergency medicine physicians were conducted at 10 hospitals, incl

242 rs, physical therapists, primary care sports medicine physicians, and orthopedic surgeons have provid

243 Microbiology (ASM) Evidence-Based Laboratory Medicine Practice Guidelines Committee of the Profession

244 The American College of Critical Care Medicine provided 2002 and 2007 guidelines for hemodynam

245 IVCCM images were analyzed at Weill Cornell Medicine-Qatar in Ar-Rayyan, Qatar.

246 is largely a result of the 2005 Institute of Medicine Report From Cancer Patient to Cancer Survivor:

247 Since the release of the Institute of Medicine report: From cancer patient to cancer survivor:

248 n, an element of the concept of precision in medicine, requires new infrastructure that spans geograp

249 ng the data from the Marshfield Personalized Medicine Research Project, a site in the electronic Medi

250 Internal medicine residency at a university hospital in Switzerla

251 ttle current evidence documents how internal medicine residents spend their time at work, particularl

252 At this Swiss teaching hospital, internal medicine residents spent more time at work than schedule

253 In the field of veterinary medicine, resistance to ivermectin is now widespread, bu

254 equirement of the American Board of Internal Medicine's (ABIM's) Maintenance of Certification program

255 Three members of PLOS Medicine's editorial board who are leading researchers i

256 ciples at stake in this debate also underlie medicine's responsibilities regarding other issues and t

257 In an Editorial accompanying PLOS Medicine's Special Issue on Advances in Prevention, Trea

258 Precision cancer medicine seeks to target the underlying genetic alterati

259 Imaging and the American College of Nuclear Medicine should choose the membership of a radiopharmace

260 nology provides (systems biology and network medicine) so diagnosis, stratification, and treatment of

261 ngitudinal information on health, prescribed medicine, social and socioeconomic information, and anal

262 Part Two includes the sections: CV Medicine & Society, Hypertension, Imaging, Metabolic & L

263 otolaryngologists, dermatologists, and oral medicine specialists.

264 d guidance, such as Cochrane or Institute of Medicine standards for conducting systematic reviews, wo

265 unprecedented opportunity to apply precision medicine strategies in transplantation research.

266 nome Research Institute-funded DCM Precision Medicine Study, which aims to enroll 1300 individuals (6

267 PEG antibody during treatment with PEGylated medicines, suggesting that genetics might play a role in

268 rvation could be improved by using precision medicine techniques to determine novel treatments and ma

269 croscopy, achieving a new milestone for tele-medicine technologies.

270 unded a review in the New England Journal of Medicine that discounted evidence linking sucrose consum

271 itutes a potential strategy for personalized medicine that enhances inference from static genotypic r

272 a compound derived from traditional Chinese medicine that has potent anti-inflammatory, tumor-inhibi

273 role in advocating for treatments, including medicines that are available, affordable, and accessible

274 evention published in New England Journal of Medicine, The Lancet, and the Journal of the American Me

275 y, drug screening, and emerging regenerative medicine therapies are fundamentally reliant on high-qua

276 ans than do currently available regenerative medicine therapies.

277 rtance of such experiments for translational medicine, there have been relatively few efforts to comp

278 implications of tumor dynamics for precision medicine, there is a need to systematically characterize

279 een among the best-investigated therapies in medicine; these devices have been the topic of numerous

280 In nuclear medicine, this expression describes the use of tracers f

281 (PCC) has been advocated by the Institute of Medicine to improve health care in the United States.

282 ant Saururus cernuus are used in traditional medicine to manage a wide range of ailments such as edem

283 made for the European Association of Nuclear Medicine to restore its surveys of reported adverse reac

284 ortance for topics ranging from personalized medicine to theories of the evolution of host-microorgan

285 round the world have used traditional herbal medicine to treat a myriad of maladies.

286 begin the effort to discover new and better medicines to treat these illnesses.

287 ifferences and taking advantage of precision medicine tools-such as genomics, radiomics, and mathemat

288 Adolescent Medicine Trials Network for HIV/AIDS Interventions 113 (

289 Adolescent Medicine Trials Network for HIV/AIDS Interventions 113 e

290 ectin, a well-established drug in veterinary medicine under consideration for regulatory submission f

291 n applications of protein crystallography to medicine was evident, as the first high-resolution struc

292 erial species are required, for instance, in medicine, water quality monitoring, and the food industr

293 Although 22 (42%) of 53 new medicines were associated with an increase in QoL, 24 (4

294 in communities where blood pressure-lowering medicines were not available.

295 ical framework put forth by the Institute of Medicine whereby quality was defined as testing being sa

296 A challenge for modern medicine will be to discover new antibiotics or strategi

297 changes, and patient demand for personalized medicine will require physicians to embrace technology i

298 g release has grown to include most areas of medicine with examples in the literature of targeted dru

299 and affordability of blood pressure-lowering medicines with data recorded from 626 communities in 20

300 ith lung cancer and the promise of precision medicine, with special emphasis on new targeted therapie