コーパス検索結果 (1語後でソート)
通し番号をクリックするとPubMedの該当ページを表示します
1 hat PAM compounds showed great inhibition of osteoclast formation.
2 their enhanced support of MM-cell growth and osteoclast formation.
3 optosis in myeloma cell lines, and increases osteoclast formation.
4 tivator for NF-kappaB ligand (RANKL)-induced osteoclast formation.
5 lear which of them are essential sources for osteoclast formation.
6 ligand, and osteoprotegerin; and up-regulate osteoclast formation.
7 sfunction, also showed higher propensity for osteoclast formation.
8 , caused osteoclast apoptosis, and inhibited osteoclast formation.
9 ment and thereby decrease MM cell growth and osteoclast formation.
10 by RNA interference abrogates tumor-induced osteoclast formation.
11 RANKL expression, accounting for a delay in osteoclast formation.
12 survival, while its overexpression decreases osteoclast formation.
13 ulating cell-fusion events involved in human osteoclast formation.
14 ment and may directly or indirectly modulate osteoclast formation.
15 a transcription factor required in OCPs for osteoclast formation.
16 Here we show an unexpected role of Btk in osteoclast formation.
17 ed medium stimulated in vitro multinucleated osteoclast formation.
18 alveolar bone loss through directly blocking osteoclast formation.
19 ner and consequently stimulate TRAP-positive osteoclast formation.
20 ow-derived PSV10 stromal cell line to induce osteoclast formation.
21 lunts the effects of TNFalpha in stimulating osteoclast formation.
22 tion in response to RANKL, thereby enhancing osteoclast formation.
23 increased osteoclast survival, not increased osteoclast formation.
24 r-kappaB (RANK) ligand (RANKL) and inhibited osteoclast formation.
25 ceptor mediates the effects of annexin II on osteoclast formation.
26 a direct target of NFATc1 in RANKL-dependent osteoclast formation.
27 at is produced by osteoclasts and stimulates osteoclast formation.
28 th healthy controls and that IL-3 stimulates osteoclast formation.
29 ucing ligand-induced apoptosis and decreased osteoclast formation.
30 timulating the production of an inhibitor of osteoclast formation.
31 EGFR signaling regulated osteoclast formation.
32 erin (OPG) and anti-TNF antibodies inhibited osteoclast formation.
33 appaB ligand (RANKL), a cytokine that drives osteoclast formation.
34 s, such as MIP-1alpha and/or IL-6, to induce osteoclast formation.
35 of cancellous bone volume and inhibition of osteoclast formation.
36 on of osteoprotegerin (OPG), an inhibitor of osteoclast formation.
37 the osteoblast lineage is a prerequisite for osteoclast formation.
38 that stellate reticulum-derived PTHrP drives osteoclast formation.
39 r activator of NF-kappaB) required to induce osteoclast formation.
40 activation of pathways that are involved in osteoclast formation.
41 teoblastic cell line (UAMS-32) that supports osteoclast formation.
42 toward alveolar bone and is associated with osteoclast formation.
43 RANK is essential in osteoclast formation.
44 in (OPG) is a secreted protein that inhibits osteoclast formation.
45 surface CSF-1 alone is sufficient to support osteoclast formation.
46 mechanistically linked to the inhibition of osteoclast formation.
47 ect bone resorption but moderately inhibited osteoclast formation.
48 ndrocytes also express RANKL/OPG and support osteoclast formation.
49 t differentiation and the ability to support osteoclast formation.
50 ), takes a role in modulating osteoblast and osteoclast formation.
51 sis of tibiae through negative regulation of osteoclast formation.
52 s, but it was linked to reduced RANKL-driven osteoclast formation.
53 to inflammatory bone loss, owing to enhanced osteoclast formation.
54 oumermycin A1 and novobiocin) did not affect osteoclast formation.
55 ression of Hsf1 enhanced 17-AAG effects upon osteoclast formation.
56 eated with RANKL or with TNFalpha to promote osteoclast formation.
57 which attenuated the effect of IL-1alpha on osteoclast formation.
58 using a unique gene footprint and to inhibit osteoclast formation.
59 nation of TRAF6, thus limiting RANKL-induced osteoclast formation.
60 ling is critical for stromal cell support of osteoclast formation.
61 to be necessary and sufficient for enhanced osteoclast formation.
62 , cytokines that exhibit opposing effects on osteoclast formation.
63 marrow macrophages attenuates RANKL-induced osteoclast formation.
64 it does not participate in RANKL-stimulated osteoclast formation.
66 oclasts, a biochemical function critical for osteoclast formation, actin organization and motility.
68 of normal mice evoked a striking increase in osteoclast formation, an effect dependent on RANK/RANKL
69 at TNF-alpha dysregulation leads to enhanced osteoclast formation and accelerated loss of cartilage.
74 ave anti-osteoclastogenic effects and reduce osteoclast formation and activity by inducing their apop
75 ondingly, MIP-1 delta significantly enhanced osteoclast formation and activity in response to RANKL i
76 Tumor necrosis factor-alpha (TNF) enhances osteoclast formation and activity leading to bone loss i
77 olysis with 2-deoxy-D-glucose (2-DG) reduced osteoclast formation and activity under both basal and h
78 factor receptor family member that inhibits osteoclast formation and activity was examined for its a
80 have been implicated as factors that enhance osteoclast formation and bone destruction in patients wi
81 of marrow cells from iNOS-/- mice) increased osteoclast formation and bone pit resorption, indicating
82 osteoclastogenesis, but the role of CCR3 in osteoclast formation and bone remodeling in adult mice i
83 lts demonstrated that CFZ blocks PTH-induced osteoclast formation and bone resorption by its addition
84 that LPS P. gingivalis stimulates periosteal osteoclast formation and bone resorption by stimulating
85 RBP-J deficiency enables TNF-alpha to induce osteoclast formation and bone resorption in DAP12-defici
86 , we have prepared compounds able to inhibit osteoclast formation and bone resorption in vitro at con
87 parent compound, flurbiprofen, at inhibiting osteoclast formation and bone resorption in vitro, and t
89 toid joint destruction result from increased osteoclast formation and bone resorption induced by rece
92 cessive RANKL signaling leads to superfluous osteoclast formation and bone resorption, is widespread
97 ective function might cause a more excessive osteoclast formation and contribute to greater osteolysi
99 tivirus-mediated short hairpin RNAs inhibits osteoclast formation and decreases cellular ferrous iron
102 We therefore establish that Lyn regulates osteoclast formation and does it in a manner antithetica
103 ppaB ligand (RANKL), cytokines essential for osteoclast formation and expressed by a variety of cell
104 d RAW264.7 cells were evaluated by analyzing osteoclast formation and expression of genes important i
105 These data suggest that Cdc42 regulates osteoclast formation and function and may represent a pr
107 ctural determinants of the RANK that mediate osteoclast formation and function have not been definiti
108 hus, the impact of inflammatory cytokines on osteoclast formation and function was among the most imp
110 The RANKL/RANK pathway is critical for both osteoclast formation and function, and these effects are
111 Motif 1, in contrast to its minimal role in osteoclast formation and function, plays a predominant r
112 eas Motif 2 and Motif 3 are highly potent in osteoclast formation and function, they exert a moderate
124 ctivator of NF-kappaB ligand (RANKL)-induced osteoclast formation and functional activity in a STAT6-
125 nding of the molecular mechanisms regulating osteoclast formation and functions and their interaction
127 ompared to wild-type controls due to reduced osteoclast formation and increased osteoblast numbers, r
128 -kappaB activation, IKKalpha and IKKbeta, in osteoclast formation and inflammation-induced bone loss.
130 nt impact on prostate cancer cell viability, osteoclast formation and osteoblast differentiation.
131 vivo function of chondrocyte-produced OPG in osteoclast formation and postnatal bone growth has not b
132 These results suggest that Phlpp1 suppresses osteoclast formation and production of paracrine factors
133 eoclast precursors but indirectly stimulates osteoclast formation and promotes bone resorption by sti
135 ydroxamate-based MMP9 inhibitor reduced both osteoclast formation and resorption activity while siRNA
138 differentiated into osteoclasts showed that osteoclast formation and resorptive activity were attenu
140 ense knockdown of SOCS-3 strongly suppressed osteoclast formation and significantly blunted the respo
142 echanism underlying its complex functions in osteoclast formation and survival, thus laying a foundat
143 Thus, miR-29 is a positive regulator of osteoclast formation and targets RNAs important for cyto
144 h that STAT3 is essential for gp130-mediated osteoclast formation and that the target of STAT3 during
145 rthermore, AAV-sh-Ac45 significantly reduced osteoclast formation and the expression of proinflammato
146 nderlying BMSC support of MM cell growth and osteoclast formation and therefore represents a therapeu
147 actor-kappaB ligand (RANKL) is essential for osteoclast formation and thought to be supplied by osteo
148 mpounds, 1d and 5d, suppressed RANKL-induced osteoclast formation and TRAP activity dose-dependently.
150 the PRF/BCP displayed an inhibitory role in osteoclasts formation and its molecular mechanism of act
151 X-308 induced potent (60%-80%) inhibition of osteoclast formation, and a 10- to 100-fold lower concen
152 arthritis, and clinical signs of arthritis, osteoclast formation, and bone erosion were assessed.
153 four other TLR2 ligands on bone resorption, osteoclast formation, and gene expression in wild type a
154 tics of synovial inflammation, bone erosion, osteoclast formation, and growth of bony spurs was perfo
155 n on RA and mouse myeloid cell chemotaxis or osteoclast formation, and in addition, to uncover the si
156 57 also showed potent inhibitory activity on osteoclast formation, and it was confirmed by a cell via
158 ibial and femoral metaphyses, an increase in osteoclast formation, and radiologic evidence of osteoly
159 Darc regulates BMD negatively by increasing osteoclast formation, and that the genetic association b
160 wo distinct signaling pathways; one promotes osteoclast formation, and the other, in collaboration wi
161 ption may be mediated by its effects on both osteoclast formation at an early stage and osteoclast ge
164 -culture systems by Northern blot as well as osteoclast formation at different stages of differentiat
166 cluding monocyte and macrophage recruitment, osteoclast formation, bone resorption, and cortical and
167 Our results suggest that estrogen modulates osteoclast formation both by down-regulating the express
168 ycin (17-AAG) causes bone loss by increasing osteoclast formation, but the mechanism underlying this
170 ed osteoclastogenesis and that it can induce osteoclast formation by a mechanism independent of RANKL
171 loid hematopoietic precursor cells decreases osteoclast formation by altering expression of the trans
174 lays an important role in the suppression of osteoclast formation by IL-4 and may explain the benefic
175 mechanism whereby TRAF6 negatively regulates osteoclast formation by intracytoplasmic sequestration o
179 activation of p55r, exogenous TNF stimulates osteoclast formation by p55r(+/+)p75r(-/-), but not p55r
180 and these fluids induced significantly less osteoclast formation compared with that of the wild-type
182 valis differentially modulates RANKL-induced osteoclast formation contingent on the state of differen
183 e stimulatory effects of annexin II on human osteoclast formation, demonstrating that the receptor me
185 y parathyroid hormone (PTH) to undergo rapid osteoclast formation/differentiation with bone resorptio
187 We report that RANKL and TNF can induce osteoclast formation directly from NF-kappaB p50/p52 dou
189 Here, we examined whether IL-1 can induce osteoclast formation directly from OCPs overexpressing c
190 uggested that RANKL-induced NO inhibition of osteoclast formation does not occur via NO activation of
192 RSV notably inhibited the TNF-alpha-induced osteoclast formation, endothelial cell phenotypic change
193 endent, constitutively active TSHR abrogates osteoclast formation even under basal conditions and in
194 tant to RANK downregulation and committed to osteoclast formation, even though they retain phagocytic
196 presence and absence of RANKL, LIGHT induced osteoclast formation from both human peripheral blood mo
197 OCPs on bone secreted IL-1, which induced osteoclast formation from c-Fos-expressing OCPs in the l
200 solated osteoclast precursors but stimulated osteoclast formation from those pretreated with RANKL in
201 L), a TNF-related molecule, is essential for osteoclast formation, function and survival through inte
206 ice, and the A(1)R antagonist DPCPX inhibits osteoclast formation (IC(50)=1 nM), with altered morphol
207 ability of osteoclast-derived EVs to inhibit osteoclast formation in 1,25-dihydroxyvitamin D3-stimula
210 tion of an activity that directly stimulates osteoclast formation in a manner independent of the key
211 and impacts chondrocyte differentiation and osteoclast formation in a manner that likely requires lo
213 nd RANKL-stimulated NF-kappaB activation and osteoclast formation in an osteoclast cellular model, RA
215 NKL) produced by osteocytes is essential for osteoclast formation in cancellous bone under physiologi
216 o administration of TNF-alpha prompts robust osteoclast formation in chimeric animals in which ss-gal
218 oclasts stimulate angiogenesis, we modulated osteoclast formation in fetal mouse metatarsal explants
222 LPS P. gingivalis and Pam2 robustly enhanced osteoclast formation in periosteal/endosteal cell cultur
223 dramatic approximately fourfold increase in osteoclast formation in response to incubation for 6 day
224 osteoblastic IL-6 production and functional osteoclast formation in the absence of osteoblasts or RA
225 Finally, osteoblast-derived VEGF stimulated osteoclast formation in the final remodeling phase of th
226 the mimetics, OP3-4, significantly inhibited osteoclast formation in vitro (IC(50) = 10 microm) and e
227 IL-37 exhibit a dose-dependent inhibition of osteoclast formation in vitro (~78.9% and 97.7% inhibiti
228 show that TNF limits RANKL- and TNF-induced osteoclast formation in vitro and in vivo by increasing
230 molecule mimic of osteoprotegerin to inhibit osteoclast formation in vitro and limit bone loss in an
231 ghly potent in promoting osteoblast-mediated osteoclast formation in vitro, a process essential to bo
232 MM cell interactions strongly contributed to osteoclast formation in vitro, because osteoclastogenesi
233 IKKalpha is required for RANK ligand-induced osteoclast formation in vitro, it is not needed in vivo.
237 ith sense PYK2 and caused: 1) a reduction in osteoclast formation in vitro; 2) inhibition of cell spr
238 r factor kappaB (NF-kappaB), is required for osteoclast formation in vivo and mice lacking both of th
240 NF-kappaB p52, nor does it appear to induce osteoclast formation in vivo in the absence of RANKL.
241 cells in varying states of TNF-alpha-driven osteoclast formation in vivo, we generated chimeric mice
243 promoted 1,25-dihydroxyvitamin D3-dependent osteoclast formation in whole mouse marrow cultures, and
244 ind, in contrast to the significant level of osteoclast formation in wild type marrow, osteoclastogen
246 umor cells, and (c) tumor cells that support osteoclast formation independent of RANKL secrete other
250 f these events is not sufficient to restrain osteoclast formation, inhibit resorption, or stop bone l
253 ts formed in the cocultures, suggesting that osteoclast formation is mediated by osteoclast different
255 crophage infiltration, synovial hyperplasia, osteoclast formation, joint destruction, cathepsin activ
257 NOTCH1 and NOTCH3 collaborate in regulating osteoclast formation, NOTCH1 is the dominant paralog.
259 Also, recipients of ABB exhibited increased osteoclast formation on the alveolar bone surface and si
260 our results indicate that IFN-gamma inhibits osteoclast formation only early in osteoclast differenti
261 ion, we evaluated the effects of TGF-beta on osteoclast formation, OPG protein secretion, mRNA expres
262 pecific genes (p < 0.05) alongside decreased osteoclast formation (p < 0.0001) in inflammatory (RANKL
263 1beta (P < 0.01 ), TNF-alpha (P < 0.05), and osteoclast formation (P < 0.01) occurred in the presence
264 eoclasts within the metaphyseal bone and the osteoclast formation potential of marrow cells on day 9.
265 n, and methotrexate, also directly increased osteoclast formation, potentially in an Hsf1-dependent m
266 activity of the conditioned medium; however, osteoclast formation stimulated by conditioned medium wa
267 dition of exogenous OPG completely inhibited osteoclast formation stimulated by EGF-like ligands, whi
268 f either dominant negative protein abolished osteoclast formation stimulated by IL-6 + soluble IL-6 r
269 vated by cytokines that induce resistance to osteoclast formation, such as IFN-gamma and M-CSF, and t
271 sis, immune cell function and bone-resorbing osteoclast formation, the expression of TRAIL in human m
272 stration, indicating that osteocytes control osteoclast formation through a PPR-mediated mechanism.
274 produced by breast cancer cells that induces osteoclast formation through upregulation of RANK ligand
275 and (RANKL) and supported MM cell growth and osteoclast formation to a much lower extent than normal
276 er LIGHT can regulate RANKL/cytokine-induced osteoclast formation, to identify the mechanism by which
277 vial fibroblasts and macrophages in abnormal osteoclast formation, using the recently described BXD2
278 dicate that C-PC has the potential to reduce osteoclast formation via blocking the degradation of cyt
279 on of eNOS/Akt pathway and markedly inhibits osteoclast formation via down-regulation of ERK/c-fos an
281 en cells with exogenous RANKL and found that osteoclast formation was 50% lower in PGHS-2(-/-) than i
284 The effect of LIGHT on human and murine osteoclast formation was assessed in the presence and ab
285 ability of recombinant MIP-1alpha to induce osteoclast formation was determined by tartrate resistan
288 IL-6 than those from C57BL/6 mice, abnormal osteoclast formation was not due to enhanced sensitivity
290 , observed by micro-computed tomography, and osteoclast formation were decreased in Mk2(-/-) mice com
291 ffects of endogenously produced cytokines on osteoclast formation were determined with neutralizing a
293 els of prostaglandin E(2), and periarticular osteoclast formation were inhibited by turmeric extract
294 interactions between DEX and D3 on RANKL and osteoclast formation were present in BMC from mice with
295 induced a heat shock response also enhanced osteoclast formation, whereas HSP90 inhibitors that did
297 mmatory response and was a potent inducer of osteoclast formation, while P. endodontalis was not.
299 rom CAST binds chemokines, known to regulate osteoclast formation, with reduced affinity compared wit
300 ur data show that enoxacin directly inhibits osteoclast formation without affecting cell viability by