ライフサイエンスコーパス: bone fracture

1 to alleviate the side effects of eczema and bone fracture.

2 n growth velocity and reduced frequencies of bone fracture.

3 were death, heart failure, weight gain, and bone fracture.

4 adverse cardiovascular events and atraumatic bone fracture.

5 of adverse outcomes such as ketoacidosis and bone fracture.

6 stated when at least one observer suggested bone fracture.

7 ions that are the consequence of spontaneous bone fracture.

8 (oim) resulted in a significant reduction of bone fracture.

9 ention, edema, congestive heart failure, and bone fracture.

10 uid retention, congestive heart failure, and bone fracture.

11 ical illness have an increased prevalence of bone fractures.

12 e abnormalities that result in bone loss and bone fractures.

13 is not consistent with the high frequency of bone fractures.

14 cases at birth to mild cases with increased bone fractures.

15 d bone mass and become highly susceptible to bone fractures.

16 ers and frequently associate with pathologic bone fractures.

17 a new anabolic treatment for unconsolidated bone fractures.

18 with DS are increasingly more susceptible to bone fractures.

19 formation in patients with osteoporosis and bone fractures.

20 hich may have contributed to the increase in bone fractures.

21 tions and weight-bearing exercise to prevent bone fractures.

22 vasion occurs during endochondral healing of bone fractures.

23 lytic lesions in the ribs led to spontaneous bone fractures.

24 ith increasing incidence of osteoporosis and bone fractures.

25 In the Medicare analysis, risk of bone fracture admissions at osteoporosis-related sites w

26 n, who are at high risk for osteoporosis and bone fractures after total body irradiation precondition

27 pathologic phenotype is multiple spontaneous bone fractures-akin to those occurring in mouse models o

28 ity than either soft-tissue trauma or closed-bone fracture along with hemorrhage.

29 in K1) intake is a potential risk factor for bone fracture, although the mechanisms of this are unkno

30 ion between protein and risk of osteoporotic bone fractures among individuals has not been examined i

31 d of musculoskeletal conditions ranging from bone fracture and arthritis to skeletal cancer.

32 It is associated mainly with long bone fracture and bone marrow fat passage to the systemi

33 g pain severity, and was detectable for long-bone fracture and nephrolithiasis as well as among child

34 e clivus fracture without additional cranial bone fracture and neurologic deficit in the literature.

35 homocysteine (tHcy) may be a risk factor for bone fracture and osteoporosis.

36 , as it is associated with intractable pain, bone fracture and paralysis resulting from spinal cord c

37 The combination of closed-bone fracture and soft-tissue trauma before hemorrhage l

38 th seven affected members exhibited frequent bone fractures and florid osseous dysplasia (p.Cys356Tyr

39 air quality is a modifiable risk factor for bone fractures and osteoporosis, especially in low-incom

40 The number of bone fractures and the renal safety profile were similar

41 The probability of bone fractures and time to first fracture were not diffe

42 f connective tissue characterized by brittle bones, fractures and extraskeletal manifestations.

43 followed by facial or orbital fracture, long bone fracture, and chest injury.

44 d with premature mortality, injurious falls, bone fracture, and disability.

45 or-induced bone destruction, delayed time to bone fracture, and increased the use of the tumor-bearin

46 ity and use, delay the time to tumor-induced bone fracture, and maintain body weight.

47 , including a higher incidence of bone pain, bone fractures, and new-onset osteoporosis.

48 Hospitalizations for pneumonia, bone fractures, and planned percutaneous coronary interv

49 T3 deficiency, there were few pneumatoceles, bone fractures, and teething problems.

50 deficiency is associated with bone loss and bone fractures, and the identification of vulnerable pop

51 mitant traumatic brain injury (TBI) and long bone fracture are commonly observed in multitrauma and p

52 Osteoporosis, osteopenia, and bone fracture are particularly common in these patients,

53 Osteoporosis and bone fractures are increasingly recognized complications

54 hat may play an important role in congenital bone fractures associated with type I spinal muscular at

55 She had multiple bone fractures at birth and was diagnosed with cutis lax

56 5 733; 27%) with surgical correction of long bone fractures being the most common procedure (144 997;

57 images were viewed for detection of possible bone fracture, bone edema and soft tissue injuries.

58 ESRD have a substantially increased risk of bone fractures, but the burden of fractures has not been

59 Bone fracture callus samples were collected and analyzed

60 Specifically, mouse bone fracture callus specimens were extracted into a sin

61 t increased risk of falling experienced more bone fractures caused by falling (adjusted hazard ratio

62 ed with sulfonylureas and increased risk for bone fractures compared with metformin.

63 ia, osteoporosis, and increased incidence of bone fractures, considerable effort has been devoted to

64 ability of treatment weighting, although the bone fracture end point approached statistical significa

65 isk with clopidogrel and PPI coprescription, bone fractures, enteric infections and pneumonia.

66 ough the reduction of both breast cancer and bone fracture event rates, the risks of both invasive en

67 Although bone fracture has become a serious global health issue,

68 ppression in premenopausal women) to prevent bone fractures has not been substantiated, although it s

69 , adverse effects such as heart problems and bone fractures have already been reported.

70 As many as 10% of bone fractures heal poorly, and large bone defects resul

71 micelles' therapeutic efficacy in promoting bone fracture healing as demonstrated by micro-CT and hi

72 Bone fracture healing impairment related to systemic dis

73 ivation of EP4, but not EP2 rescued impaired bone fracture healing in COX-2(-/-) mice.

74 nin signaling in the remodeling phase during bone fracture healing is currently unknown.

75 Importance: Failure of bone fracture healing occurs in 5% to 10% of all patient

76 These effects lead to improved bone fracture healing quality compared with wildtype mic

77 to both chondrocytes and osteoblasts during bone fracture healing.

78 atic injuries, in part through inhibition of bone fracture healing.

79 reduce the risk of symptomatic pathological bone fracture (HR 0.62, 95% CI 0.35-1.09), or the need f

80 y 30% higher among subjects who had suffered bone fracture in the torso (p < 0.0005).

81 to investigate therapeutic avenues to treat bone fractures in children with autism.

82 ), sensory function (hearing), mobility, and bone fractures in defining vulnerable health classes.

83 us problem worldwide; it is characterized by bone fractures in response to relatively mild trauma.

84 as to summarize the risk of osteoporosis and bone fractures in schizophrenia patients.

85 evidence supports Clostridium difficile and bone fractures in susceptible populations.

86 Osteoporosis resulting in bone fractures is a complication in patients with primar

87 ss of bone mineral density (BMD) and risk of bone fractures is undetermined.

88 total bones; P < 0.01), a greater number of bone fractures (median 4 versus 0; P < 0.01), and more f

89 evaluated and separated based on wet and dry bone fracture morphology/characteristics.

90 hird of ONJ patients also suffered from long bone fractures (n = 4) and/or avascular necrosis of the

91 nned to qualify 50 children treated for long bones fractures of the arm, forearm, thigh and lower leg

92 Different traumatic insults, i.e., bone fracture or soft-tissue trauma in conjunction with

93 and in patients with other risk factors for bone fractures or C. difficile infection.

94 juries, such as bruising, bite marks, burns, bone fractures, or trauma to the head or abdomen.

95 d more adverse effects, including infection, bone fracture, osteonecrosis, mood and behaviour problem

96 s resulted in a two-thirds reduction in long bone fractures (P < .01), with fewer fractures per mouse

97 Nonblindness was associated with nasal bone fractures (P = .047).

98 ially caused by low levels of hormones (e.g. bone fractures, poor sperm quality, and perhaps testicul

99 as been associated with an increased risk of bone fracture, raising concerns about their increasingly

100 Osteoporotic bone fracture rates are highest in countries that consum

101 Bone fracture repair was analyzed in femora of adult mic

102 is, fibrin was entirely dispensable for long-bone fracture repair, as healing fractures in fibrinogen

103 epair, the precise contribution of fibrin to bone fracture repair, whether supportive or detrimental,

104 e stage of fracture healing to ensure better bone fracture repair.

105 nd mandibular condyle development and during bone fracture repair.

106 fibrin clearance results in derangements in bone fracture repair.

107 .001), edema (35.6% vs. 24.9%, P<0.001), and bone fracture requiring surgery or hospitalization (5.1%

108 e molecular pathways ultimately impact whole bone fracture resistance.

109 Closed-bone fracture (right lower leg; external fixation) and/o

110 sess the association between insulin use and bone fracture risk in T2DM patients.

111 orbing periosteal osteoclasts, and increased bone fracture risk.

112 that the micelles would passively target to bone fracture sites associated with hematoma and inflamm

113 ity occurred with the combined insult (i.e., bone fracture/soft-tissue injury and hemorrhage) than af

114 pedic consultation should be sought for long-bone fractures, spinal cord compression, and vertebral c

115 Acute wrist injuries are predominantly bone fractures, such as those of the scaphoid, hamate ho

116 ifferences in the propensity to nontraumatic bone fracture suggest that genetic factors are important

117 In patients with long bone fractures, the presence of an RLS is associated wit

118 splatin plus gemcitabine group (pathological bone fracture, thrombocytopenia with subcutaneous haemor

119 E4 allele (APOE*E4) has been associated with bone fracture through a putative effect on vitamin K tra

120 f the presumed mechanism of fifth metatarsal bone fracture was attempted.

121 Bone fracture was observed in 5.6% of participants.

122 uma Score, initial visual acuity and frontal bone fractures were predictive of NLP (P = .006 and P =

123 During follow-up, no bone fractures were reported to have occurred; 12/368 cr