ライフサイエンスコーパス: surgical wound

1 at Van-ICG@PLT preferentially accumulates at surgical wound.

2 ymptomatic with good healing of the perianal surgical wound.

3 e removal of the sinus cavity with a minimal surgical wound.

4 ected into gingival tissue approximating the surgical wound.

5 keratitis developing adjacent to a previous surgical wound.

6 ation pathway, and thrombin formation in the surgical wound.

7 vered from skin, soft tissue, abscesses, and surgical wounds.

8 VEGF) to the angiogenic environment of human surgical wounds.

9 tive collagenase compared with that of acute surgical wounds.

10 adult periodontitis as well as with healing surgical wounds.

11 f infection were respiratory tract (53%) and surgical wound (25%).

12 strain has an extraordinary capacity to heal surgical wounds, a complex trait that maps to at least s

13 n four mouse infection models, including the surgical wound, abscess, burn wound, and acute pneumonia

14 Routine application of iNPWT to the closed surgical wound after emergency laparotomy did not preven

15 d in the fibrin gel and scavenge H(+) in the surgical wound, allowing polarization of tumour-associat

16 timated to comprise approximately 28% of all surgical wounds and are frequently complex to manage.

17 pressure-stimulated cell adhesion to murine surgical wounds and blocked pressure-induced FAK and Akt

18 t pressure-stimulated tumor cell adhesion to surgical wounds and enhance tumor-free survival.

19 Fluid from acute surgical wounds and from nonhealing pressure ulcers was

20 e a potential source of bacterial entry into surgical wounds and may contribute to surgical site infe

21 mmatory responses in infected and uninfected surgical wounds and were as effective, (or even better),

22 in the management of genitourinary injuries, surgical wounds, and complications.

23 ced angiogenesis in s.c. sponges, in healing surgical wounds, and in the myocardium of mice 7 days af

24 Patients in the surgical wound-associated group were more likely to use

25 Thrombin is primarily produced in the surgical wound, but mechanisms are unclear.

26 Iatrogenic tumor cell implantation within surgical wounds can compromise curative cancer surgery.

27 nsistencies in the practice of perioperative surgical wound care, increases patients' risk of surgica

28 d accelerated wound healing by comparison to surgical wound closures.

29 the control group experienced more than one surgical wound complication (P=0.014), and the relaparot

30 irolimus demonstrated a significantly higher surgical wound complication rate, but graft and patient

31 ophenolate mofetil who were pair-matched for surgical wound complication risk factors.

32 We studied postoperative surgical wound complications in 15 kidney recipients rec

33 Surgical wound complications were defined as any complic

34 alization for uterine infection, obstetrical surgical wound complications, and cardiopulmonary and th

35 tion with postpartum hemorrhage, obstetrical surgical wound complications, and pelvic injury.

36 The primary outcome measure was surgical wound complications.

37 essant, has been anecdotally associated with surgical wound complications.

38 Surgical wound contamination with pressure-activated Co2

39 Surgical wound cultures and resistance data were obtaine

40 Of 445 NSTIs identified, 85% had surgical wound cultures within 48 hours of admission.

41 und bed tissue biopsy were collected at each surgical wound debridement.

42 A surgical wound drainage cannot prevent epidural hematoma

43 r as a result of pathogens gaining access to surgical wounds either hematogenously, through drains, o

44 d a standard approach for managing high-risk surgical wounds, especially in gastrointestinal procedur

45 Surgical wound fluid form all time points stimulated mar

46 Surgical wound fluid samples (n = 70) were collected dai

47 VEGF levels in surgical wound fluid were lowest on POD 0, approximating

48 Sterile post-surgical wound fluids were found to contain a high degre

49 of residual tumors in the proximity of acute surgical wounds has been reported; however, the mechanis

50 Most surgical wounds heal by primary intention, that is to sa

51 as methyl mercaptan may play a role in both surgical wound healing and periodontal disease by advers

52 Surgical wound healing by secondary intention (SWHSI) pr

53 aged 18 years or older and had at least one surgical wound healing by secondary intention, which was

54 ents' views and experiences of living with a surgical wound healing by secondary intention.

55 The risks of surgical wound healing complications in transplant recip

56 nduced thermal preconditioning would enhance surgical wound healing that was correlated with hsp70 ex

57 To study the effects of COX-2 on colonic surgical wound healing.

58 inical implications for hemostat use in post-surgical wound healing.

59 itro to better understand the role of EMD in surgical wound healing.

60 ed periodontal bone loss and diminished post-surgical wound healing; however, the pathogenesis of thi

61 Patients with a surgical wounds healing by secondary intention (an open

62 tion: Do antiseptics and antibiotics benefit surgical wounds healing by secondary intention (SWHSI)?

63 dy aimed to derive a better understanding of surgical wounds healing by secondary intention and to fa

64 Surgical wounds healing by secondary intention can be di

65 Surgical wounds healing by secondary intention can have

66 significant tissue loss), and are known as 'surgical wounds healing by secondary intention'.

67 irst inception cohort study in patients with surgical wounds healing by secondary intention.

68 tial reactions, particularly to "unexpected" surgical wounds healing by secondary intention.

69 racrine stimulation loop induced by the post-surgical wound-healing response.

70 effects of EMD on healing of an oral mucosa surgical wound in rats.

71 fection in patients at risk of bacteremia or surgical wound infection but failed to reach their clini

72 We developed a minipig deep surgical wound infection model offering 3 independent ef

73 o elicit strong inflammatory responses; in a surgical wound infection model with Pseudomonas aerugino

74 reus strain in both the s.c. abscess and the surgical wound infection models in WT mice.

75 nistration of such drug in a murine model of surgical wound infection significantly reduced the bacte

76 CD4(+) alphabeta T cells homed to the surgical wound infection site of WT animals.

77 omodulator in the treatment of MSSA and MRSA surgical wound infection through enhancement of the loca

78 extraintestinal infections (pneumonia, deep surgical wound infection, and vertebral osteomyelitis wi

79 c. abscess formation, hindpaw infection, and surgical wound infection, S. aureus multiplied in the ti

80 During S. aureus surgical wound infection, the presence of IFN-gamma at t

81 The primary endpoint was the rate of surgical wound infection.

82 using a clinically relevant murine model of surgical wound infection.

83 hypothermia both increases susceptibility to surgical-wound infection and lengthens hospitalization.

84 is common during major surgery, may promote surgical-wound infection by triggering thermoregulatory

85 Empyema was most common (42%), followed by surgical wound infections (29%), mediastinitis (16%), st

86 may be a significant component in some mixed surgical wound infections and that surgical management a

87 ide updated guidelines for the prevention of surgical wound infections based upon review and interpre

88 onchial wash, blood, sinus drainage, and two surgical wound infections from separate patients in Texa

89 The development and treatment of surgical wound infections has always been a limiting fac

90 r years, bloodstream, respiratory tract, and surgical wound infections predominated.

91 Surgical wound infections remain a significant source of

92 of mixed wound infection, from a pool of 400 surgical wound infections that we have studied, in which

93 ptible S. aureus which frequently cause deep surgical wound infections.

94 rees C in the normothermia group (P < 0.001) Surgical-wound infections were found in 18 of 96 patient

95 The extent of the ability of surgical wound infiltration with local anesthetic agents

96 ), Warthin's tumor of the parotid gland (1), surgical wound inflammation (2), leiomyoma of the uterus

97 Surgical wounds of specific depths were created in pig s

98 ion and neovascularization in full-thickness surgical wounds on rat oral mucosa.

99 edical conditions, such as those with burns, surgical wounds or people with cystic fibrosis.

100 hibit or kill gram-positive or gram-negative surgical wound pathogens.

101 infectious keratitis adjacent to a previous surgical wound progressed into endophthalmitis.

102 s emerged as an advanced method for managing surgical wounds, promoting faster healing by enhancing t

103 The post-surgical wound rapidly healed and was characterized by f

104 CAM was placed in surgical wounds related to implant surgery.

105 red after eradication of infection and final surgical wound repair.

106 the urinary tract, indwelling catheters, and surgical wound sites.

107 Partial-thickness surgical wounds were created in live swine (an animal wh

108 s with 10(5) CFU of P. aeruginosa before the surgical wounds were hermetically closed.

109 Physical symptoms, including pain and the surgical wound, were recurrent items of concern.

110 ial in minimizing bacterial contamination of surgical wounds when used in guided tissue regeneration

111 Postoperative pain and delayed healing in surgical wounds, which require complex management strate

112 a post-operative dressing of the incisional surgical wound with a sterile absorbent cover.

113 d a postoperative dressing of the incisional surgical wound with a sterile absorbent cover.

114 We discovered that co-infection of murine surgical wounds with Pseudomonas aeruginosa results in c