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1 ions of Vn, especially those related to bone resorption.
2 significantly larger and exhibited enhanced resorption.
3 ession and causes muscle catabolism and bone resorption.
4 s a tunable decision between deciliation and resorption.
5 d JE degeneration, PDL destruction, and bone resorption.
6 for diseases associated with excessive bone resorption.
7 ible for physiological and pathological bone resorption.
8 cial for osteoclast differentiation and bone resorption.
9 sorption but also osteocytes and perilacunar resorption.
10 low IQ, and defective kidney proximal tubule resorption.
11 se in bone formation and an increase in bone resorption.
12 adhesion, actin cytoskeletal remodeling and resorption.
13 al bone formation and increased endocortical resorption.
14 t 3 years, coincident with complete scaffold resorption.
15 obisphosphonate and potent inhibitor of bone resorption.
16 d the 3-year time point of complete scaffold resorption.
17 damage, fetal growth restriction, and fetal resorption.
18 latter is due in large part to elevated bone resorption.
19 e side effects such as hypocalcemia and bone resorption.
20 ed bone formation and slightly hindered bone resorption.
21 of IFT-B through cilia decapitation precedes resorption.
22 ml CSC neonatally had increased rates of pup resorption.
23 oclast differentiation and inflammatory bone resorption.
24 tomography analysis was used to assess bone resorption.
25 strogen deficiency leads to accelerated bone resorption.
26 Ts changes during flagellar regeneration and resorption.
27 microCT analysis was used to assess bone resorption.
28 tant gatekeepers of estrogen-controlled bone resorption.
29 tment, reduced IL-6 and RANKL, and less bone resorption.
30 undergoes continual cycles of formation and resorption.
31 ific genes via NFATc1, which facilitate bone resorption.
32 ied data that provide new insights into root resorption.
33 tegerin (OPG) signaling associated with bone resorption.
34 t, and reduced bone mass with increased bone resorption.
35 d strength by uncoupling bone formation from resorption.
36 severely osteopenic because of enhanced bone resorption.
37 main HIF-regulated pathway that drives bone resorption.
38 al knockout mice alleviated progressive bone resorption.
39 increases bone formation, and decreases bone resorption.
40 , plays an essential role in regulating bone resorption.
41 anced osteoclastogenesis, and increased bone resorption.
42 to bone tissue by inducing osteoclastic bone resorption.
43 ncreasing bone formation and decreasing bone resorption.
44 t osteoclast precursors to induce local bone resorption.
45 lasts, is a major negative regulator of bone resorption.
46 1 antisense RNA to control pathological bone resorption.
47 ase increased when cells underwent flagellar resorption.
48 sertion to minimize future peri-implant bone resorption.
49 ced osteoclastogenesis and inflammatory bone resorption.
50 rtical bone osteopenia due to increased bone resorption.
51 of Ac45 in periapical inflammation and bone resorption.
52 events that are caused by osteoclastic bone resorption.
53 rrelated with the difference in palatal bone resorption.
54 Boldine inhibited the alveolar bone resorption.
55 tion factor on osteoclast formation and bone resorption.
56 t that promotes both bone formation and bone resorption.
57 ation, extracellular acidification, and bone resorption.
58 ed bone formation and osteoclast-driven bone resorption.
59 ish demonstrate that shedding involved tooth resorption, a primitive feature in bony fishes, but abse
60 teoclasts are the cells responsible for bone resorption, a process that is essential for the maintena
62 d bone, periosteal reaction, serpentine bone resorption, abscess formation, and root penetration of t
63 in vivo phenotype as its multinucleation and resorption activities determine quantifiable skeletal tr
66 ibitor reduced both osteoclast formation and resorption activity while siRNA targeting MMP9 also inhi
67 expression of osteoclastic markers and bone resorption activity, as well as decreased expression of
70 eeth with DBBM-C tended to exhibit less root resorption, although it was not statistically significan
72 sociated with a significant decrease in bone resorption and a marked reduction in number of osteoclas
73 sociated with a significant decrease in bone resorption and a marked reduction in the number of osteo
75 h an increase in osteoclastogenesis and bone resorption and an increase in the pool of monocytes.
76 ltaneously inhibits osteoclast-mediated bone resorption and attenuates dendritic cell-mediated inflam
77 tein (PTHrP) is a critical regulator of bone resorption and augments osteolysis in skeletal malignanc
78 L administered at ART initiation blunts bone resorption and BMD loss at key fracture-prone anatomical
79 L administered at ART initiation blunts bone resorption and BMD loss at key fracture-prone anatomical
80 hometry measurements revealed that both bone resorption and bone formation parameters were increased
82 osis results from the imbalance between bone resorption and bone formation, and restoring the normal
86 AT1-mTORC1 axis plays a pivotal role in bone resorption and bone homeostasis by modulating NFATc1 in
89 e remodeling, as confirmed by increased bone resorption and decreased bone formation, and significant
95 he discovery of key pathways regulating bone resorption and formation has identified new approaches t
96 t activation and unbalanced coupling between resorption and formation, which induces a thinning of tr
99 t osteoclasts (OCLs) block both pagetic bone resorption and formation; therefore, PD offers key insig
101 of periodontitis by measuring alveolar bone resorption and gingival IL-17 expression as outcomes of
102 licated in sterile inflammation-induced bone resorption and has been shown to increase the bone-resor
103 ic matrix deposition and osteoclastic tissue resorption and immunomodulation for tissue development.
104 ts PKCzeta activity, cell polarity, and bone resorption and increases secretion of bone-forming Cthrc
105 Tooth extraction results in alveolar bone resorption and is accompanied by postoperative swelling
106 hich are characterized by high rates of bone resorption and loss of bone mass, may benefit from treat
107 nistered orally, inhibited the alveolar bone resorption and modulated the Th17/Treg imbalance during
108 ntly influence hydrogel functions, including resorption and molecular delivery when injected into hea
109 ch is determined by osteoclast-mediated bone resorption and osteoblast-mediated bone formation, repre
110 lyinosinic:polycytidylic acid promotes fetal resorption and placental abnormalities in wild-type but
112 phosphonates used for treatment inhibit bone resorption and prevent bone loss but fail to influence b
113 eoclasts, VAOs are dispensable for cartilage resorption and regulate anastomoses of type H vessels.
115 (+) M2-like macrophages associated with root resorption and root surface repair processes linked to t
119 ises two processes: the removal of old bone (resorption) and the laying down of new bone (formation).
120 collagen-degrading enzyme activity, infarct resorption, and adverse structural remodeling (r>0.5).
123 xtensive peri-implantitis with advanced bone resorption, and extensive inflammation with granulation
124 ing enhanced plant growth, plant N uptake, N resorption, and fine root biomass, suggesting higher pla
126 ion, reduced osteoclast recruitment and bone resorption, and impaired osteoblast-mediated bone format
128 very high interfacial strains, marginal bone resorption, and no improvement in implant stability.
131 apsulation induces more severe alveolar bone resorption, and whether this bone loss is associated wit
133 adopting the amount of palatal alveolar bone resorption as a dependent variable demonstrated that the
134 f markers for osteoclast differentiation and resorption, as well as osteoblast-stimulating 'clastokin
136 the inflammatory response and alveolar bone resorption associated with ligature-induced periodontal
138 cient to significantly inhibit alveolar bone resorption associated with the experimental periodontal
139 ays a relevant role in inflammation and bone resorption associated with the LPS model of experimental
142 older people and may lead to increased bone resorption, bone loss, and increased falls and fractures
143 k, a process that involves osteoclastic bone resorption but also osteocytes and perilacunar resorptio
144 steoporosis drugs that not only inhibit bone resorption but also stimulate bone formation, such as po
145 HIF-2alpha knockdown did not affect bone resorption but moderately inhibited osteoclast formation
146 iency did not increase serum markers of bone resorption, but elevated serum markers of bone formation
147 NKL and BMPs, in osteoclastogenesis and bone resorption by ablating p38alpha MAPK in LysM+monocytes.
148 rmine whether boldine inhibits alveolar bone resorption by modulating the Th17/Treg imbalance during
151 estosterone (T), which thereby inhibits bone resorption by osteoclasts and stimulates bone formation
152 estosterone in bone, thereby inhibiting bone resorption by osteoclasts and stimulating bone formation
158 ctedly enhanced their tonic firing, as water resorption by supporting cells reduced the extracellular
159 one matrix, pharmacologic inhibition of bone resorption by zoledronate attenuates inflammasome activa
160 ith blood lead and plasma biomarkers of bone resorption (C-terminal telopeptides of type I collagen (
161 xisting leaf-trait databases, since nutrient resorption can cause traits of litter and green leaves t
162 h decreased fusion events, and their mineral resorption capacity was significantly reduced, indicatin
164 ymal stem cell-derived osteoblasts, and bone resorption, carried out by monocyte-derived osteoclasts.
165 mineralization inhibition, impaired mineral resorption, cellular senescence and extracellular vesicl
167 e had elevated cancellous bone formation and resorption compared to other treatment groups as well as
168 ncoupled and disorganized bone formation and resorption continued for the duration of the study resul
169 l sources of variability, including feeding (resorption decreases) and recent fracture (all markers i
171 in osteoblasts and osteocytes decreases bone resorption due to an increased secretion of Semaphorin 3
176 ever, the effect of boldine on alveolar bone resorption during periodontitis has not been elucidated
178 training session attenuated markers of bone resorption, effects that are independent of energy avail
179 during and after HIT running attenuates bone resorption, effects that are independent of energy avail
180 Osteopenia occurs where the rate of bone resorption exceeds that of bone formation, so we investi
183 at there was a significant reduction in bone resorption following 3 months of SPI supplementation tha
185 ylated on arginine residues during flagellar resorption; however, the function is not understood.
186 from the same cat with and without signs of resorption identified 1,732 differentially expressed gen
187 to assess its role in inflammation and bone resorption in a murine model of lipopolysaccharide (LPS)
188 to assess its role in inflammation and bone resorption in a murine model of lipopolysaccharide (LPS)
189 rexpression in the ethiopathogenesis of bone resorption in aggressive and chronic periodontitis.
191 Siglec-15 as a regulator of pathologic bone resorption in arthritis and highlight its potential as a
194 mass in mice and osteoclast multinucleation/resorption in humans with strong correlation between the
197 rgement and recovery points to a reduced CSF resorption in microgravity as the underlying cause.
198 itive feedback mechanism that amplifies bone resorption in pathologic conditions of accelerated bone
199 vides a potential strategy for treating bone resorption in patients with myeloma by counteracting tum
201 markers (BTMs) demonstrated presence of bone resorption in PIM; between comparable diagnostic ranges
204 zed osteopenia associated with enhanced bone resorption in the cancellous bone compartment and with s
206 dysbiosis led to a local inhibition of bone resorption in the presence of ligature-induced periodont
207 The importance of osteoclast-mediated bone resorption in the process of osseointegration has not be
209 on or viability, it efficiently blocked bone resorption in vitro and in vivo and consequently amelior
210 rbate synovial inflammation in vivo and bone resorption in vitro, suggesting that LTB4 and BLT1 could
211 nt doses of CMC2.24 on inflammation and bone resorption in vivo and also to describe on the effects o
212 a significant role in inflammation and bone resorption in vivo and that Caspase-1 has a pro-resorpti
213 ic drug-eluting stents, followed by complete resorption in ~3 years with recovery of vascular structu
214 tly decarboxylated and activated during bone resorption, inactivation of furin in osteoblasts in mice
215 press genes required in osteoclasts for bone resorption, including cathepsin K (Ctsk), and lactation
216 ivalis plays a key role in the alveolar bone resorption induced during periodontitis, and this bone l
217 odel of P. gingivalis-induced calvarial bone resorption, injection of mmu-miR-155-5p or anti-mmu-miR-
223 in the central region of each pouch undergo resorption, leaving behind the region at the rim to form
224 as well as a transient decrease in the bone resorption marker C-telopeptide of type I collagen (CTX-
227 ent and modeling, rather than excessive bone resorption, may be the underlying pathophysiology of the
228 emodeling due to balanced bone formation and resorption mediated by osteoblasts and osteoclasts, resp
229 Our data indicate that the increase in bone resorption observed in states of estrogen deficiency in
230 plants demonstrated a peri-implant mean bone resorption of 2.96 mm increased bone loss, yielding a cu
232 ing this process is that osteoclast-mediated resorption of a quantum of bone is followed by osteoblas
234 two novel mouse models show that the lack of resorption of BB xenografts renders them inadequate for
235 ary to determine the time taken for complete resorption of bone graft materials and their replacement
236 der, characterized by defective osteoclastic resorption of bone that results in increased bone densit
237 poorly understood but are thought to involve resorption of ciliary components into the cell body.
241 s in embryonic/neonatal lethality with rapid resorption of homozygous mutants, hampering additional s
245 hickness and find the factors related to the resorption of the palatal alveolar bone caused by tooth
248 alendronic acid, a potent inhibitor of bone resorption, optimally linked through a differentially hy
250 l (e.g. the nutrient uptake from litter, the resorption, or the storage of nutrients in the biomass),
253 resorbable scaffold (MgBRS) presents a short resorption period (<1 year) and have the potential of be
256 ic cell adhesion in the external apical root resorption process and the specific role of alpha/beta i
258 gradation of ARL13b that occurs during cilia resorption, raising the possibility that the sensitivity
261 ta T cells but were designed to inhibit bone resorption rather than treating cancer and have limited
262 The ZOL arm had a 65% reduction in bone resorption relative to the placebo arm at 24 weeks (0.11
263 hways; and (3) regulatory mechanisms of root resorption repair by cementum at the proteomic and trans
264 en (CTX-I) are markers of bone formation and resorption, respectively, that are recommended for clini
265 mechanism for progenitor recruitment to bone resorption sites and Cxcl9l and Cxcr3.2 as potential dru
267 to increase differentiation and promote bone resorption, supporting the tenet that irisin not only st
269 of P. gingivalis induced less alveolar bone resorption than the encapsulated W50 wild-type strain.
271 in the bone promote osteoclast-mediated bone resorption that releases TGF-beta, which restrains T(h)1
273 t alveolar bone, hyperloading activates bone resorption, the peak of which is followed by a bone form
275 codes netrin 1), which is required for canal resorption, to be ectopically expressed at the canal rim
278 re: complications such as ankylosis and root resorption up to the tooth exfoliation have occurred fre
289 raditionally thought to occur solely through resorption, we show that an acute loss of IFT-B through
291 ased by 25-40%, and the osteoclasts and bone resorption were suppressed by 50% in NTAP-Ti in vivo.
292 nt hypernucleated osteoclasts, enhanced bone resorption when cultured on bone slices, and altered mRN
294 mab fully inhibits teriparatide-induced bone resorption while allowing for continued teriparatide-ind
297 eting senescent cells were due to lower bone resorption with either maintained (trabecular) or higher
299 loss mediated by excessive osteoclastic bone resorption without affecting osteoblastic activity in bo