ライフサイエンスコーパス: Achilles tendon

1 programme (gallbladder removal and ruptured Achilles tendon).

2 10(6), range 5-19 x 10(6) cells) into their Achilles tendon.

3 es, patellar tendon, gluteal tendons and the Achilles tendon.

4 te the mechanical role of GAGs in the ageing Achilles tendon.

5 GAGs in the tensile mechanics of the ageing Achilles tendon.

6 g tendon in a transected rabbit model of the Achilles tendon.

7 fulfil one function of the calf muscles and Achilles tendon.

8 eriod of time and leads to a compliant human Achilles tendon.

9 or muscles and elastic energy storage in the Achilles tendon.

10 NR in patients, 9.4 +/- 3.0; P < .05) of the Achilles tendon.

11 through a compliant spring representing the Achilles tendon.

12 ignificantly decreases in healthy-aged mouse Achilles tendons.

13 needle biopsies from the healing area of the Achilles tendon 6 weeks after treatment with PRP or plac

14 al role of glycosaminoglycans in the healthy Achilles tendon across age.

15 may reflect a decrease of GAG content in the Achilles tendon after ciprofloxacin intake.

16 ion through a series elastic component (SEC, Achilles tendon and foot) which limits maximal ankle sti

17 over rates of individual proteins within rat Achilles tendon and its ECM phases.

18 sensory information through vibration of the Achilles tendons and additional finger touch (contact fo

19 hus we attribute this stiffness to the foot, Achilles' tendon and aponeurosis rather than the activat

20 ted heart attack, ruptured gut, and ruptured Achilles tendon) and three in the comparison group (tran

21 magnitude and distribution within the whole Achilles tendon are affected by individual tendon geomet

22 and repetitively loaded tendons such as the Achilles tendon are more susceptible to injury, and inju

23 t of normal development, bone grows into the Achilles tendon as the calcaneus enlarges.

24 y determines the spring-like behavior of the Achilles tendon, as well as estimates of mass-specific t

25 underwent 7-T MR imaging examinations of the Achilles tendon at baseline and 10 days and 5 months aft

26 These differences may be facilitated by the Achilles tendon (AT), which is comprised of subtendons t

27 AT) induces morpho-mechanical changes to the Achilles tendon (AT).

28 sibly affecting the load transmission to the Achilles tendon (AT).

29 Here we identify that the Achilles tendon-bone insertion is characterized by an in

30 mal tensile load (MTL) (P = 0.0524) than the Achilles tendon, but a similar ultimate tensile strength

31 his was attributed to a displacement of both Achilles tendon by 0.6-1.1 cm (P < 0.01) and all instant

32 were obtained from 20 patients with ruptured Achilles tendon by means of ultrasound-guided needle bio

33 that the geometric equilibrium state of the Achilles tendon can coincide with minimization of the to

34 The unique structure of the Achilles tendon, combining three smaller sub-tendons, en

35 rop, scapular winging, mild facial weakness, Achilles tendon contractures, and diminished or absent d

36 score) was significantly correlated with the Achilles tendon CSA and vascular calcification, this sco

37 Using a rat full-cut Achilles tendon defect model, we demonstrate that scaffo

38 tion of inflammation is poorly understood in Achilles tendon disorders.

39 The elastic stretch-shortening cycle of the Achilles tendon during walking can reduce the active wor

40 of a subcutaneous dry needle, did not reduce Achilles tendon dysfunction at 6 months.

41 We demonstrate that the compliant Achilles tendon elicited a series of adaptations from di

42 Although plantar flexor muscle mechanics and Achilles tendon energy storage have been explored during

43 stologic analysis was performed on cadaveric Achilles tendon entheses to determine whether regional v

44 A total of 20% Achilles tendon entheses, 45% plantar aponeurosis enthes

45 This study combined ultrasonography of the Achilles tendon enthesis at different stages of spondyla

46 tissue hypotrophy and impaired maturation of Achilles tendon enthesis in Sparc (-/-) mice.

47 Thirty-seven patients with SpA and Achilles tendon enthesitis (20 with early SpA and 17 wit

48 Bone erosion in association with Achilles tendon enthesitis in SpA is anatomically uncoup

49 Using an in-vitro cell culture system, rat Achilles tendon fibroblasts were treated with glycolalde

50 xplanations require that the passive tissue (Achilles' tendon, foot) transmitting the calf muscle ten

51 ally applied daily to the skin overlying the Achilles tendons for four weeks prior to the initiation

52 An Achilles tendon, for example, transmits force, elastical

53 Substantially unrealistic Achilles tendon forces and moments generated around the

54 Using transcriptome analysis of skin and Achilles tendons from Col5a1 haploinsufficient (Col5a1+/

55 sub-tendon sliding and its role in the whole Achilles tendon function is limited.

56 In young Achilles tendons, glycosaminoglycans influence the elast

57 all genes, the normal, painful, and ruptured Achilles tendon groups each had a distinct mRNA expressi

58 proliferation, correlating with longitudinal Achilles tendon growth.

59 cal suture significantly improves functional Achilles tendon healing in a rabbit model, resulting in

60 emporal and spatial progression of HO during Achilles tendon healing.

61 following tendon injury in a mouse model of Achilles tendon healing.

62 properties at the calcaneal insertion of the Achilles tendon in young mice.

63 Thirteen Achilles tendons in 10 cadavers (four male, six female;

64 ation, 58 years +/- 9) were compared with 20 Achilles tendons in 10 control subjects without FH (two

65 nkle extensor muscle architecture (e.g., the Achilles tendon) in the evolution of hominin running ene

66 From P7 to P28, the Achilles tendon increased in length, whereas the patella

67 t loading and activity while recovering from Achilles tendon injuries.

68 Here, we show that after Achilles tendon injury in mice, there is new nerve growt

69 ion of tendon-like tissues in a rat model of Achilles tendon injury.

70 altered regional material properties at the Achilles tendon insertion in young mice in the absence o

71 The Achilles tendon insertion is associated with a complex o

72 und no changes to regional properties at the Achilles tendon insertion or midsubstance in middle-aged

73 The Achilles tendon is among the most commonly injured tendo

74 nt arm of the m. triceps surae tendon (i.e., Achilles tendon), is positively correlated with the ener

75 volar flexor tenosynovitis (trigger finger), Achilles tendon lesions, and occupational medicine issue

76 Operator (LASSO) regression to predict peak Achilles tendon load and walking speed.

77 op a wearable paradigm to accurately monitor Achilles tendon loading and walking speed using wearable

78 ensors to accurately predict (MAPE <= 12.6%) Achilles tendon loading and walking speed while ambulati

79 res of shear wave propagation as a proxy for Achilles tendon loading during walking.

80 The tensiometers also detected Achilles tendon loading of 4 to 7 MPa in late swing.

81 hear wave tensiometers were used to estimate Achilles tendon loading when walking at speeds ranging f

82 tral response of collagen type I from bovine Achilles tendon matched that of the rat-tendon cryosecti

83 ence of any material property changes to the Achilles tendon midsubstance.

84 At any given ankle angle, Achilles tendon moment arm length during MVC increased b

85 lexor maximum voluntary contraction (MVC) on Achilles tendon moment arm length.

86 flexor MVC would be calculated using resting Achilles tendon moment arm measurements.

87 e support for the relationship between short Achilles tendon moment arms and increased elastic energy

88 Achilles tendon moment arms were measured at ankle angle

89 maging signal and the GAG CEST effect in the Achilles tendon of healthy volunteers.

90 brillar matrix in native (unfixed), hydrated Achilles tendon of sheep and chickens.

91 Primary tenocytes from Achilles tendon of Sprague-Dawley rats 1 week after coll

92 Sections of small spurs from the Achilles tendons of elderly humans were also examined fo

93 ongly adheres to patellar, supraspinatus and Achilles tendons of live rats, boosted healing and reduc

94 We enzymatically digested GAGs from the Achilles tendons of young, middle-aged and old C57BL/6 m

95 s after injury, previous rupture of the same Achilles tendon, or being unable to complete the questio

96 Ten patients, mean age 47 with mid-portion Achilles tendon pain and swelling for more than 6 months

97 nts were older than 18 years with midportion Achilles tendon pain for more than 3 months as confirmed

98 c or structural properties across age in the Achilles tendon, paired with no changes to fibril realig

99 Achilles tendon pathologies are prevalent, impacting ~6%

100 oduce mechanical work through elastic (e.g., Achilles tendon, plantar fascia) or viscoelastic (e.g.,

101 Fascia and Achilles tendon primarily consist of similar collagen ty

102 ens the gastrocnemius muscle by 5% while the Achilles tendon remains virtually unaffected.

103 ats either received bilateral SynAb surgery (Achilles tendon resected), or bilateral sham surgery, or

104 Outcomes included Achilles tendon rupture (ATR), Achilles tendinitis (AT),

105 being treated non-operatively for a primary Achilles tendon rupture at the participating centres wer

106 Achilles tendon rupture is a common debilitating medical

107 In the Achilles tendon rupture model, combining ESM with PRP en

108 The primary outcome was patient-reported Achilles tendon rupture score (ATRS) at 9 months, analys

109 Patients with Achilles tendon rupture who have non-operative treatment

110 ement of patients treated non-surgically for Achilles tendon rupture.

111 approach of one author for the management of Achilles tendon rupture.

112 Whether surgical repair of an acute Achilles' tendon rupture by an open-repair or minimally

113 imally invasive surgery in adults with acute Achilles' tendon rupture who presented to four trial cen

114 In patients with Achilles' tendon rupture, surgery (open repair or minima

115 and reduced scar formation in a rat model of Achilles-tendon rupture, and sustainably released the co

116 efficacy of an ESM-PRP scaffold in treating Achilles tendon ruptures, employing in vitro and in vivo

117 Achilles tendon specimens (n = 16) were collected from i

118 Histologic sections of rat Achilles tendons, stained with toluidine blue or Masson'

119 d type I collagen matrix derived from bovine Achilles tendon that promotes fibroblast ingrowth and ne

120 iled unpaired t test in three regions of the Achilles tendon: the insertion area, the middle portion,

121 munohistochemical response of ruptured human Achilles tendon to PRP.

122 We performed RNA-seq analysis using Achilles tendons to investigate the molecular changes un

123 outcome was the change from baseline in the Achilles' tendon Total Rupture Score (scores range from

124 The mean changes in the Achilles' tendon Total Rupture Score were -17.0 points i

125 Mice underwent hindlimb Achilles' tendon transection and dorsal burn injury (bur

126 was to investigate the response of ruptured Achilles tendon treated with PRP.

127 nd soleus activity were recorded during 33-s Achilles tendon vibration and simultaneous 20-Hz bouts o

128 The spring function of the Achilles tendon was evaluated using specific net work, a

129 Collagen type I from bovine Achilles tendon was imaged for SHG in the backscattered

130 omized to heavy loading or mild loading, the Achilles tendon was transected, and animals were treated

131 from each region, as well as from the whole Achilles tendon, was compared between patients and healt

132 Achilles tendon wave speed, tendon moment arms, tendon c

133 For intact ex vivo SHG imaging of Achilles tendon, we observe a significant contribution o

134 rts) in 26 consecutive cases of tears of the Achilles tendon were compared with surgical findings.

135 sions of the middle and distal thirds of the Achilles tendons were evaluated histologically.

136 racted from apolipoprotein E deficient mouse Achilles tendons were incubated with catK and catL eithe

137 ea, volume, and fat-water separation) of the Achilles tendons were obtained at baseline and in patien

138 Achilles tendon, when degenerated, exhibits lower stiffn

139 ankle moment arms place larger loads on the Achilles tendon, which should result in a greater amount

140 partial-thickness tears or tendinosis of the Achilles tendon with 92% accuracy.

141 ps between tendon tensile mechanics in human Achilles tendon with accumulation of advanced glycation

142 Materials and Methods Forty-eight Achilles tendons with clinically apparent xanthomas in 2

143 Bony spurs can develop in the Achilles tendon without the need for preceding microtear

144 pose To investigate the fat-water content of Achilles tendon xanthomas at baseline and after treatmen

145 Conclusion Most of the enlargement of Achilles tendon xanthomas is due to an increase in water

146 core on electron-beam CT (EBCT), and size of Achilles tendon xanthomas.

147 lycosaminoglycans decrease across age in the Achilles tendon, yet their effect on structural properti