ライフサイエンスコーパス: immunobiology

1 lin genes offer insights into the underlying immunobiology.

2 rstanding of the paradoxical nature of liver immunobiology.

3 ion may be key to understanding and altering immunobiology.

4 c acid ligands has important implications in immunobiology.

5 provide advances with broad implications in immunobiology.

6 primate model to the understanding of human immunobiology.

7 ly focused on T-cell-PD-1 expression and its immunobiology.

8 des critical insights into tumor biology and immunobiology.

9 peutic inhibitor development and fundamental immunobiology.

10 hat incorporates a deep understanding of RCC immunobiology.

11 ls of the immune system, and their impact on immunobiology.

12 ous tumour models, to uncover the underlying immunobiology.

13 ular biology of cancer and the physiology of immunobiology.

14 increasing evidence implicates dysregulated immunobiology.

15 over microbiome links to asthma outcomes and immunobiology.

16 en gut and oropharyngeal microbiota and lung immunobiology.

17 articular relevance to transplant-associated immunobiology.

18 ant animal models of HLA-E-restricted T cell immunobiology.

19 t histologic comparison of early engraftment immunobiology.

20 they induce offer direct insight into human immunobiology.

21 ccine design and future research in TFH cell immunobiology.

22 and nonhuman primates for the study of human immunobiology.

23 hput selection represent major challenges in immunobiology.

24 et in corneal transplant pharmacotherapy and immunobiology.

25 though little is known about its role in pDC immunobiology.

26 le of alternatively activated macrophages in immunobiology.

27 be very useful for in vivo studies of human immunobiology.

28 respiratory syncytial virus pathogenesis and immunobiology.

29 our evolving understanding of the disease's immunobiology.

30 saki is a Waldemar Von Zedtwitz Professor of Immunobiology, a Professor of Molecular and Cellular and

31 luable tool for the study of transplantation immunobiology allergy, autoimmunity, and infectious dise

32 ations in the expression of genes related to immunobiology among the African-American patients, consi

33 IL-8 levels in identifying unfavorable tumor immunobiology and as an independent biomarker in patient

34 peptide splicing events has implications for immunobiology and autoimmunity theories and may provide

35 modern understanding of xenotransplantation immunobiology and continued experience with large animal

36 Here we review the immunobiology and design principles of current prototype

37 ts may lead to better understanding of liver immunobiology and development of new strategies for trea

38 group leader at the Max Planck Institute of Immunobiology and Epigenetics in Freiburg, Germany.

39 serve as a useful tool in the study of viral immunobiology and for the design of treatments for murin

40 tic cancer and should be considered in tumor immunobiology and for the development of new therapeutic

41 of patients and to fundamental paradigms in immunobiology and hemostasis.

42 infectious disease studies, yet their B cell immunobiology and immunogenetics remain ill-characterize

43 There is evidence that tumor immunobiology and immunotherapy response may differ betw

44 study of these important APC in normal liver immunobiology and in immune-mediated hepatic disorders.

45 In conclusion, with novel immunobiology and metabolomics insights, harnessing the

46 h play remarkably varied and potent roles in immunobiology and neurobiology.

47 highlighted biological processes relating to immunobiology and olfaction, some of which may relate to

48 ne-editing tools to the study of liver fluke immunobiology and pathogenesis has accelerated the disco

49 provide a more detailed understanding of the immunobiology and pathogenesis of GVHD and GVL responses

50 Studies in the immunobiology and pathology of IBD and colitis-associate

51 in soluble form to facilitate study of their immunobiology and potential role in vaccines.

52 review, we survey current knowledge of ILC2 immunobiology and present an overview of ILC2 phenotypin

53 Rapidly advancing skin immunobiology and recently described parasite developmen

54 Current understanding of T cell immunobiology and the critical role of inflammatory proc

55 model for the study of human Treg ontogeny, immunobiology and therapy.

56 s, understanding of their role in transplant immunobiology and transplant rejection is extremely limi

57 th rapid developments in the field of sepsis immunobiology and ultimately to improve clinical outcome

58 These findings uncover facets of CAR immunobiology and underscore the potential of CRISPR/Cas

59 er and more profound understanding of cancer immunobiology, and the leverage of this knowledge to eff

60 tory effects that could modify host-parasite immunobiology, and the lipid solubility of plant oils mi

61 act of CD11c-DTR and Langerin-DTR mice on DC immunobiology, and we highlight the problems to be aware

62 Advances in MRI, pathology, and immunobiology are needed to increase understanding of th

63 are DNA viruses, and their pathogenesis and immunobiology are similar.

64 Recent advances in immunobiology are very promising for the identification

65 blood and coalesced around perturbations of immunobiology being centrally insulted by ELA.

66 mors indicate prominent differences in tumor immunobiology between African-American and European-Amer

67 This review summarizes the state of CD28/B7 immunobiology both in vitro and in vivo; summarizes the

68 e shed light onto multiple aspects of cancer immunobiology, but they are limited by the lack of physi

69 el has provided numerous insights into liver immunobiology, cellular and molecular regulation of live

70 This review highlights the current relevant immunobiology, clinical developments, and management of

71 ling in gliomas, its implications for glioma immunobiology, compartment-specific roles for STING sign

72 his review of Brucella-host interactions and immunobiology discusses recent discoveries as the basis

73 These data revise the understanding of pDC immunobiology during SIV infection, indicating that pDCs

74 encing did not discernibly affect the cells' immunobiology (e.g., costimulatory molecules, chemokines

75 stic and structural studies of pathogenesis, immunobiology, environmental resistance, and biotransfor

76 the past 20 years, his expertise in mucosal immunobiology has been applied to the immunology of HIV/

77 munodeficiency virus type 1 (HIV-1) envelope immunobiology has been derived almost exclusively from a

78 thma has been explored and the importance of immunobiology has come sharply into focus with the ident

79 ymphoid cells (ILCs), our knowledge of their immunobiology has expanded rapidly.

80 ur enhanced understanding of transplantation immunobiology has refined clinical management and improv

81 To increase our understanding of CMV immunobiology in an animal model, we used a genomic appr

82 inophil cell biology, molecular biology, and immunobiology in health and disease.

83 obilization is fundamental to the underlying immunobiology in KD.

84 mmarize current views on monocyte/macrophage immunobiology in kidney transplantation.

85 summarize the current knowledge of cellular immunobiology in pregnancy and its complications that ha

86 ization of a murine model to enable study of immunobiology in the setting of ABOi transplantation.

87 In this study, we investigated MHC-E immunobiology in two common nonhuman primate species, In

88 e provide a comprehensive overview of recent immunobiology insights in PSC.

89 rstanding of influenza antigen structure and immunobiology is advancing novel vaccine candidates into

90 and we have recently shown that endothelial immunobiology is anchorage dependent.

91 liver failure (iPALF), so understanding its immunobiology is critical to preventing disease progress

92 This immunobiology is especially relevant to cancer patients

93 These studies demonstrate that ICAM-1 immunobiology is highly complex but that individual isof

94 Appreciation of this dichotomy in IL-10 immunobiology may allow for the design of more effective

95 sease processes, better understanding of its immunobiology might lead to the development of IL-18 and

96 We here review the immunobiology of 2 particularly promising TNFRSF target

97 nsplant, and show how dissecting the complex immunobiology of allo-HCT represents a crucial step towa

98 Much of the immunobiology of allogeneic HSCT has been gleaned from p

99 The immunobiology of allogeneic HSCT is unique in transplant

100 posite allografts, as well as studies of the immunobiology of allografts and xenografts.

101 lung transplant as a model for studying the immunobiology of AMR.

102 elanoma cells may contribute to the clinical immunobiology of anti-CTLA4 responses.Significance: Thes

103 might, in part, explain the inheritance and immunobiology of asthma.

104 sponses.Recent advances in understanding the immunobiology of B cells and areas requiring further inv

105 rus, identifies knowledge gaps regarding the immunobiology of both diseases, and aims to prioritise r

106 opment hampered by poor understanding of the immunobiology of C. jejuni infection.

107 The full understanding of the immunobiology of cancer immunosurveillance and immunoedi

108 tryptophan catabolism as a key factor in the immunobiology of cancer.

109 le for the HTLV-I SU binding proteins in the immunobiology of CD4(+) T cells.

110 Although much is known concerning the immunobiology of CD8+ T memory cells, the initial events

111 The immunobiology of CD80 expression by keratinocytes, espec

112 reat deal remains to be understood about the immunobiology of DC populations in relation to human tra

113 f some long-standing enigmas surrounding the immunobiology of dendritic cells, illuminating their opp

114 refine patient selection, and inform on the immunobiology of disease.

115 tive strategies and provide insight into the immunobiology of dMMR tumors.

116 To this end, a better understanding of the immunobiology of DSA production is necessary and also th

117 This review will primarily focus on the immunobiology of experimental acute GVHD with an emphasi

118 ow only limited understanding of the genuine immunobiology of FDCs in their native habitat.

119 gene expression patterns, which underlie the immunobiology of FHL.

120 IL-2 and TGF-beta1 play key roles in the immunobiology of Foxp3-expressing CD25(+)CD4(+) T cells

121 n combination has been used to elucidate the immunobiology of graft-vs-host disease (GVHD) following

122 hes are based on better understanding of the immunobiology of HIV and its impact on hematopoietic tis

123 cine development in the context of the basic immunobiology of HIV and SIV, review the evidence for th

124 Mechanistic studies investigating the immunobiology of HIV-associated HCC are urgently require

125 nd the phenotypic progression and underlying immunobiology of HSE including the cytokine/chemokine en

126 y to inhibit apoptosis may be factors in the immunobiology of HSV infections.

127 th a focus on novel understanding of mucosal immunobiology of HSV-2, and vaccine efforts to date, in

128 We sought to study the immunobiology of human IgE-expressing B cells in healthy

129 In this review, we discuss immunobiology of i35-Breg cell, i35-Breg therapies for a

130 rk reveals new mechanistic insights into the immunobiology of IgE and the action of omalizumab with p

131 Here, we discuss the pathogenesis and immunobiology of IgE-FA in addition to its diagnosis, pr

132 Some of the recent key advances in the immunobiology of IL-18 are discussed in this review.

133 ions of this new appreciation concerning the immunobiology of IL-2 with respect to targeting IL-2 or

134 Here we provide an overview of the immunobiology of IL-27 and review advances in understand

135 ous antagonists of IL-6 and consider how the immunobiology of IL-6 may inform clinical decisions.

136 This review summarizes discoveries in immunobiology of ILCs and their roles in allergic diseas

137 Exploiting the immunobiology of interleukin (IL)-2, IL-12, IL-15, IL-18

138 to 78 days, providing new insights into the immunobiology of LCs.

139 t and reproducible murine model to study the immunobiology of male genital tissue in the context of t

140 Recognition of such relevant proteins in the immunobiology of malignant tumors may lead to the develo

141 owever, many gaps in knowledge regarding the immunobiology of maternal immunisation prevent the optim

142 , but also the complex interplay between the immunobiology of memory CD4(+) T helper cells (which for

143 es recent insights into the pathogenesis and immunobiology of MF/SS and how these have shaped current

144 nodes of regulation relevant for the unique immunobiology of neonatal humans.

145 terface in humans, within an overview of the immunobiology of NKG2D and mechanisms underlying the reg

146 To elucidate the immunobiology of norovirus infection in humans, 15 volun

147 mmunity, but years of investigation into the immunobiology of other flaviviruses has helped to accele

148 role of this important human pathogen in the immunobiology of pelvic inflammatory disease.

149 ions should improve our understanding of the immunobiology of persistent viral infection.

150 ng of genetic defects in pES, the underlying immunobiology of pES is poorly defined, and characterist

151 The immunobiology of recombinant adenovirus was studied in m

152 These data provide insights into the immunobiology of SLE and identify type III IFNs as impor

153 This review summarizes the immunobiology of SP and its effect on immune cells and i

154 Recent advances in our understanding of the immunobiology of stem-cell engraftment, tolerance and tu

155 oral diseases, with special emphasis on the immunobiology of Streptococcus mutans, leading to active

156 highlight recent discoveries related to the immunobiology of T cell exhaustion that offer a more nua

157 view, we synthesize current knowledge on the immunobiology of T cell priming in cancer, define how ca

158 require a more detailed understanding of the immunobiology of T1D, as well as technologies to monitor

159 Understanding the immunobiology of the 15% to 30% of patients with follicu

160 arrow transplantation (BMT), but the complex immunobiology of the allogeneic environment on responses

161 An improved understanding of the immunobiology of the B-cell response to these vaccines m

162 d for models offering an all-inclusive neuro-immunobiology of the disease together with a clinical co

163 This model offers an all-inclusive neuro-immunobiology of the disease, allowing for the testing o

164 des despite an evolving understanding of the immunobiology of the graft-versus-leukemia effect and th

165 hieved through a better understanding of the immunobiology of the HLA system and through more precise

166 This study highlights the unique immunobiology of the lung and the complexity of lung tra

167 Improved understanding of the immunobiology of these cells has increased the possibili

168 a greater understanding of the genetics and immunobiology of these diseases, facilitating the matchi

169 Advances in the immunobiology of these disorders are discussed including

170 rus outbreaks, yet little is known about the immunobiology of these viruses.

171 in understanding oncogenic signaling and the immunobiology of this cancer.

172 t cell is central to an understanding of the immunobiology of this intracellular parasite but is a ma

173 Although our knowledge of the immunobiology of this organ is beginning to accumulate a

174 tion of life-threatening airway defects, the immunobiology of this organ system must be better charac

175 or delay future tissue damage; however, the immunobiology of this stage is unclear.

176 A critical appraisal of the intricate immunobiology of tick-host associations can plant new se

177 The Immunobiology of Transplantation and Alloimmunity study

178 is characterization of the intrinsic spatial immunobiology of treatment-naive TNBC highlights the imp

179 Recent advances in the understanding of the immunobiology of xenograft rejection has spurred experim

180 els have clarified the pathology, if not the immunobiology, of chronic intestinal allograft rejection

181 e outline an evolving understanding of IL-33 immunobiology, paying particular attention to how IL-33

182 This immunobiology presents a rapidly evolving case study in

183 Several unanswered questions in T cell immunobiology relating to intracellular processing or in

184 ns in controlling tissue-specific cDC subset immunobiology remains elusive.

185 such, the role of gammadelta T cells in RCC immunobiology remains questionable.

186 evolving and providing new opportunities for immunobiology research.

187 hed for neurobiology, growth, metabolism and immunobiology, suggesting that these biological processe

188 interaction network extracted from Janeway's Immunobiology textbook.

189 mental differences in immune composition and immunobiology that not only explain the differences in r

190 f lymphatic vessels and lymphangiogenesis in immunobiology, the impact immunosuppressive therapies ha

191 efining our understanding of transplantation immunobiology, these findings identify new therapeutic t

192 grate our understanding of HNSCC biology and immunobiology to identify predictive biomarkers that wil

193 tal SpA, confirmed a fundamentally different immunobiology to rheumatoid arthritis.

194 ng from biomaterials science, drug delivery, immunobiology, to tissue engineering.

195 To elucidate the underlying immunobiology, we performed a deep immune analysis of in

196 By leveraging the basic immunobiology, we rationally direct tolerance-restoring

197 chlamydia natural history, pathogenesis, and immunobiology were reviewed and gaps in our knowledge th

198 e a fundamental link between liver and tumor immunobiology wherein hepatocytes govern productive T ce

199 paradoxical pro-tumor role for CXCR3 in lung immunobiology wherein the CXCR3 axis drives both the ant

200 e the current state of knowledge of FcRn-IgG immunobiology, with an emphasis on the functional and pa

201 ammation has emerged as an active process in immunobiology, with cells of the mononuclear phagocyte s

202 elated to C. trachomatis natural history and immunobiology, with implications for control programs;to