ライフサイエンスコーパス: basic biology

1 al therapies and limits understanding of its basic biology.

2 nd nuclear medicine in unique ways by way of basic biology.

3 based therapeutic intervention as well as in basic biology.

4 e that small molecules have had in advancing basic biology.

5 ing the urgent need to better understand its basic biology.

6 oes not require specialized knowledge beyond basic biology.

7 le in several ways that have implications in basic biology.

8 ology, thus influencing our understanding of basic biology.

9 ating a more thorough understanding of their basic biology.

10 g to physicians and is considered as defying basic biology.

11 e discussed in the context of the underlying basic biology.

12 iome has revolutionized many concepts in our basic biology.

13 tus of individuals, vaccine development, and basic biology.

14 ive and sustained participation of lipids in basic biology.

15 models with particular emphases on (1) cGVHD basic biology; (2) the utility of integrating preclinica

16 ears, yet the genetic basis of the bed bug's basic biology and adaptation to dense human environments

17 ision techniques have proven useful both for basic biology and applied biotechnology.

18 contributes to a better understanding of SWD basic biology and behavior, offering insights to the dev

19 Advances in our understanding of the basic biology and biochemistry of chromatin structure an

20 or a broad range of research applications in basic biology and biomedically oriented research.

21 usage is despite limited knowledge in their basic biology and cellular tropism.

22 ol can be conducted by any researcher having basic biology and chemistry skills in ~3 d.

23 overcome the traditional boundaries between basic biology and classical epidemiology.

24 es" article, we have engaged experts in both basic biology and clinical immunology to capture the wor

25 sive despite major efforts to understand its basic biology and clinical pathophysiology.

26 findings transform our understanding of the basic biology and clinical relevance of inflammasomes.

27 nized longevity has profound implication for basic biology and conservation of whales.

28 valuable information for both investigating basic biology and developing therapeutics.

29 the current state of knowledge on neutrophil basic biology and discusses how the breakdown of neutrop

30 en proteomics data and complex phenotypes in basic biology and disease research.

31 nsive to DDX3 inhibition, with relevance for basic biology and disease states where DDX3 is altered.

32 As septins are an essential player in basic biology and disease, understanding the interplay b

33 l types has transformed our understanding of basic biology and disease.

34 locking new insights in the contexts of both basic biology and disease.

35 in vivo, with potential broad application in basic biology and drug target validation.

36 serve as valuable tools for applications in basic biology and fluorescence image-guided surgery (FIG

37 much has changed in the understanding of the basic biology and genetics of kidney cancer.

38 because much remains to be known about their basic biology and genetics.

39 Analysis of Eimeria genes involved in basic biology and host-parasite interaction highlights a

40 nsduction and the effects of this pathway on basic biology and human diseases.

41 Efforts continue to understand the basic biology and improve the efficiency of gene transfe

42 Some of the basic biology and laboratory evidence demonstrating how

43 ment occurs is of fundamental importance for basic biology and medical sciences, but our knowledge is

44 atured a review of recent discoveries in the basic biology and pathogenesis of eosinophilic gastroint

45 To obtain mutants for the study of the basic biology and pathogenic mechanisms of mycoplasmas,

46 flight in the smallest species important for basic biology and physics, and, potentially, for applied

47 netics and has found several applications in basic biology and protein imaging.

48 ring, presenting tremendous implications for basic biology and public health and policy.

49 the study of rare human genetic diseases to basic biology and public health.

50 cent advances, embodied in new insights into basic biology and technology that can be applied to meta

51 Q80 will become a valuable tool to study the basic biology and therapeutic potential of selective CAR

52 elegans, with a view to investigating their basic biology and therapeutic potential.

53 of great importance to our understanding of basic biology and to making advances in biomedical resea

54 Omics methods are widely used in basic biology and translational medicine research.

55 -friendly policies to promote healthy aging, basic biology and translational research has been encour

56 SigQC has been adopted in basic biology and translational studies, including, but

57 pression systems will advance studies on the basic biology and virulence of Leptospira, as well as fa

58 lines of evidence from human neuropathology, basic biology, and genetics have implicated loss of the

59 organisms are widely used for understanding basic biology, and have significantly contributed to the

60 atherosclerosis will bridge epidemiology and basic biology, and promise increased understanding of ca

61 gical aspects; and (3) a reduced emphasis on basic biology apart from an increased focus on mouse mod

62 pathway has yielded fundamental insights for basic biology, as well as provided rational targets for

63 ites of binding, is crucial to understanding basic biology at the molecular level.

64 this review is to summarize the most recent basic biology, biochemistry, and pharmacology that serve

65 our understanding of cGVHD pathogenesis and basic biology, born out of a combination of mouse models

66 t the cell surface is important not only for basic biology but also for the development of novel anti

67 lth and disease will be crucial not only for basic biology but can also be exploited when designing n

68 thwarted progress toward understanding their basic biology, but via the use of new genetic tools and

69 dvanced rapidly and reached a scale at which basic biology, clinical translation and population healt

70 habitat is essential for understanding their basic biology, demography, and ethology.

71 Thus, their basic biology does not predispose them to favor the reco

72 ipotent stem (iPS) cells has applications in basic biology, drug development, and transplantation.

73 This basic biology finding has important implications not onl

74 al regulators of T cell tolerance, but their basic biology has remained under-characterized because t

75 nger ribonucleic acid profiling, advances in basic biology have led to a more complete and sophistica

76 een turned to the use of IEDDA approaches in basic biology, imaging and therapeutics.

77 t and to provide additional insight into the basic biology, immunology, and evolution of the virus.

78 Species trees provide insight into basic biology, including the mechanisms of evolution and

79 However, their basic biology, including their activity throughout a 24-

80 trol agents, a better understanding of their basic biology, including transmission modes and molecula

81 and highlight new opportunities to translate basic biology into clinical advances.

82 The conversion of basic biology into new therapeutics requires scientific

83 industry and emerging cases in humans, their basic biology is hampered by lack of suitable biological

84 re in various mammals, including humans, its basic biology is not well understood.

85 A review of the basic biology literature shows that proposed mechanisms

86 s needed to advance our understanding of the basic biology, mechanisms, and epidemiology of betel qui

87 s unravelled various molecular mechanisms in basic biology, medical genetics, cancer research, immuno

88 AV vectors has implications not only for the basic biology of AAV but also for the optimal use of the

89 We review the basic biology of AAV, the history of progress in AAV vec

90 d significant interest in all aspects of the basic biology of AAV.

91 Our results provide new insights into the basic biology of adjuvant-elicited cellular immunity and

92 A fundamental question in the basic biology of aging is whether there is a universal a

93 s will be broadly useful in the study of the basic biology of ALKBH3 and in clinical cancer applicati

94 portant challenge with relevance both to the basic biology of animal communication and to biomedicine

95 that are relevant for understanding both the basic biology of bacterial adaptation and its technologi

96 lication of our results to understanding the basic biology of bacterial plasmids.

97 l efforts will lead to new insights into the basic biology of biofilm formation, as well as new strat

98 sts and researchers to understand better the basic biology of brain function and the way in which var

99 s and social epidemiology come to affect the basic biology of cancer and ultimately clinical outcomes

100 Both the goal of understanding the basic biology of cancer development as well as the pract

101 Improved understanding of the basic biology of cardiac arrhythmias holds the promise o

102 dosage abnormalities, and the effect on the basic biology of cells when a mouse carries a freely seg

103 e is still much more to understand about the basic biology of cGAMP before its full therapeutic poten

104 iated with autism spectrum disorder, but the basic biology of CHD8 remains poorly understood.

105 hese enzymes could be important for studying basic biology of cholinergic systems and disorders that

106 been invaluable for learning about both the basic biology of CLN3 and the underlying pathological ch

107 neous revascularization does not address the basic biology of coronary atherosclerosis and therefore

108 hese findings have implications both for the basic biology of CSC function, and for the use of in viv

109 of DCIS and explore open questions about the basic biology of DCIS, including those regarding how gen

110 test by general nephrologists, including the basic biology of ddcfDNA, methodological nuances of test

111 In this Review, we discuss the basic biology of flaviviruses, their infectious cycles,

112 This article reviews the basic biology of GVHD, clinical manifestations of acute

113 though extremely useful in understanding the basic biology of H. influenzae, has yet to provide signi

114 though extremely useful in understanding the basic biology of H. influenzae, these data have not prov

115 Here, we review the basic biology of HDACs and their inhibitors, the role of

116 This review updates the basic biology of hematopoietic stem cells (HSC) and prog

117 k for understanding critical features of the basic biology of HIV-1, including the selective tropism

118 In this review, we outline the basic biology of HMO and polyphenols and deeply characte

119 ng force behind the desire to understand the basic biology of HSC niches is the clear implications fo

120 gress in the field, our understanding of the basic biology of HSCs is still rather incomplete.

121 ave built on increasing understanding of the basic biology of HSV to minimise vector toxicity and exp

122 s may contribute to our understanding of the basic biology of human germ cell development and may pro

123 ortance, fundamental questions regarding the basic biology of IL-33 remain.

124 This work provides insights into the basic biology of LOY mutation and potential biomarkers f

125 provide a powerful means to characterize the basic biology of LSCs as well as to identify improved me

126 representing a useful tool for studying the basic biology of M(4) as well for the support of M(4) re

127 is in laboratory broth cultures, much of the basic biology of M. tuberculosis in its natural setting

128 duced a wealth of new observations about the basic biology of malaria parasites, and it is likely tha

129 Clearly, much about the basic biology of mitochondria remains to be understood.

130 The basic biology of monkeypox virus (MPXV) can be inferred

131 thogen we need a better understanding of the basic biology of mycobacterial pathogenesis.

132 ed by important gaps in our knowledge of the basic biology of Mycobacterium tuberculosis, the causati

133 rol their function, our understanding of the basic biology of NK cells has improved dramatically in t

134 Studies of the basic biology of Notch function have provided insights i

135 d factors have numerous implications for the basic biology of obesity and provide prospective targets

136 Skin is an excellent model to study the basic biology of organ regeneration and translational ap

137 Specifically, the authors review the basic biology of oxidative stress, relevant aspects of m

138 icroorganisms allows us to better define the basic biology of pathogenesis while providing better ins

139 g studied intensively both to understand the basic biology of pluripotency and cellular differentiati

140 ors provides an exciting new window into the basic biology of pluripotency and differentiation.

141 The answer depends upon the basic biology of PPARgamma, and the possibility of selec

142 However, the basic biology of psychodid larvae is not well-suited for

143 Aspects of the basic biology of RNAi, its application as a functional g

144 enefit from an improved understanding of the basic biology of SARS-CoV-2.

145 itro establishes the foundation to study the basic biology of SSCs and makes possible germ-line modif

146 tem cells is essential for understanding the basic biology of stem cells and for facilitating clinica

147 The basic biology of stem cells and the relationships betwee

148 robust resource for those interested in the basic biology of stem cells and their applications.

149 Research into the basic biology of telomeres continues to reveal details r

150 arinii pneumonia are well characterized, the basic biology of the causative organism is poorly unders

151 , including a refocusing on the study of the basic biology of the disease, and an embracing of the co

152 Seminar, we focus on the role, function, and basic biology of the ECM in both heart development and i

153 isting immunoepidemiological data and of the basic biology of the host and the parasites.

154 llular functions of individual genes and the basic biology of the host cell.

155 iruses and may help to better understand the basic biology of the human pathogen N. fowleri.

156 Basic biology of the IDO-overexpressing lung cells was e

157 ion to the fact that our knowledge about the basic biology of the MDR and XDR strains of Mycobacteriu

158 llowing injury and provide insights into the basic biology of the organ with implications for develop

159 e caused by A. fumigatus is substantial, the basic biology of the organism is mostly obscure.

160 owerful tools to answer questions related to basic biology of the p53 pathway, as well as cancer ther

161 dings indicate that there are aspects of the basic biology of the ribosome in S. aureus and other rel

162 guide future progress based on insights from basic biology of the SAN.

163 ss not only extends our understanding of the basic biology of the schistosome life cycle but can also

164 search and improves our understanding of the basic biology of the species.

165 of HAdV26 have been extensively studied, the basic biology of the virus with regard to receptor use,

166 However, data regarding the basic biology of the virus, like receptor usage or intra

167 cell immunotherapy, our understanding of the basic biology of these cells, including how their number

168 Here, we review the basic biology of these cytokines, highlighting mechanism

169 overy and vaccine development as well as the basic biology of these fascinating parasites.

170 A better understanding of the basic biology of these IFN-induced GTPases could thus be

171 New research into the basic biology of these neoplasms may add new treatment o

172 may in turn inform our understanding of the basic biology of these pathways and lead to the validati

173 r neural functions, these studies add to the basic biology of these processes and could provide targe

174 nervation during development, as well as the basic biology of these sensory neurons, remains rudiment

175 Further understanding of the basic biology of these targets is imperative to the deve

176 tations has had on fueling insights into the basic biology of thick filament proteins and reinforce t

177 udies have provided greater insight into the basic biology of this chemokine and have implicated CXCL

178 This review covers the basic biology of this class of peptides and discusses th

179 d the important gaps in understanding of the basic biology of this cytokine family.

180 o high pathogen loads, and for exploring the basic biology of this important pest.

181 mechanism - yielding insights into both the basic biology of this neurodegenerative disorder and str

182 lipid metabolism, provides insights into the basic biology of this nonmodel organism.

183 Much of the most basic biology of this organelle is poorly understood, ev

184 hat we develop a better understanding of the basic biology of this parasite and how it interacts with

185 m D. citri can provide insight into both the basic biology of this pest and D. citri-associated patho

186 has been much progress in understanding the basic biology of this platform.

187 The basic biology of this system, including the range of kno

188 ed that a more complete understanding of the basic biology of tumor vessels will be necessary to full

189 onsequences is crucial for understanding the basic biology of tumorigenesis.

190 Additional advances in the basic biology of umbilical cord blood also appear very p

191 here are expected to inform studies of both basic biology of uterine function and its disorders.

192 This review summarizes the basic biology of VEGF-A and illustrates the clinical pro

193 bra finches are widely used for studying the basic biology of vocal learning.

194 irds provides good material for studying the basic biology of vocal learning.

195 ress of studies using baboons as a model for basic biology or human disease.

196 to achieve selectivity, and applications in basic biology or in the clinic.

197 In the face of this health challenge, the basic biology, pathogenesis, and determinants of SVD are

198 In this review, we discuss the basic biology, pathology, and approaches for treatment o

199 ecules identified in screens designed with a basic biology perspective.

200 review examines the current understanding of basic biology, pharmacology, and structural biology in a

201 ion is of primary interest for understanding basic biology, protein biochemistry, and human disease.

202 Yet much about their basic biology remains unknown, including the nature of a

203 haracterize resistance mutations to catalyze basic biology research and drug discovery.

204 livery of macromolecules into cells enhances basic biology research and therapeutic applications in c

205 ked scientists from across diverse fields of basic biology research for their views on the most excit

206 than any other environment studied, and the basic biology research theme accounted for half of the t

207 r a dozen applications in drug discovery and basic biology research, but both types of profiles are r

208 A common yet still manual task in basic biology research, high-throughput drug screening a

209 tory science for those currently involved in basic biology research.

210 Journey through basic biology reveals a way to treat chromosomally unsta

211 These include areas of basic biology, societal aspects, and clinical aspects.

212 rong connections between plant pathology and basic biology, something that could perhaps be made more

213 broad utility of engineered tissue models in basic biology studies.

214 Investigations from basic biology suggest that activation of the Rho/Rho kin

215 is providing a deeper understanding of their basic biology, taxonomy and evolution, as well as their

216 nition in Glomeromycotina and parts of their basic biology that define species.

217 y large, fierce mammals, many aspects of the basic biology that dictate what polar bears (Ursus marit

218 A mechanistic understanding of the basic biology that underlies the 40-hertz treatment will

219 Here, we review recent advances in basic biology, the connections to disease, and preview p

220 subject of intense scientific scrutiny, from basic biology to applications in regenerative medicine.

221 contributing to diverse research areas, from basic biology to biomanufacturing and disease therapy.

222 is widely used to study gene function, from basic biology to biomedical research.

223 Cas9 is driving innovative applications from basic biology to biotechnology and medicine.

224 sks, ranging from investigating questions in basic biology to potentially developing novel therapeuti

225 wering a diversity of questions ranging from basic biology to pre-clinical species selection and tran

226 nic arrhythmia syndromes shows that to bring basic biology to the clinic is a powerful approach.

227 test insights in Wnt signaling, ranging from basic biology to therapeutic implications in cancer, are

228 ultimodal datasets to address questions from basic biology to translation.

229 nable to intervention for various studies in basic biology together with drug evaluation and mechanis

230 ibe the most notable applications of Cas9 in basic biology, translational medicine, synthetic biology

231 homeostasis contributes knowledge about the basic biology underlying taste disruptions in patients t

232 Here, we review the basic biology underlying the differentiation of pluripot

233 available for exploration of this pathogen's basic biology, we chose this heme-detoxification pathway

234 Elucidation of basic biology will aid in translating data gleaned from

235 knowledge presents opportunities to further basic biology with translation to human diseases.