ライフサイエンスコーパス: neurosurgery

1 procedures such as intravascular surgery and neurosurgery.

2 with the National Hospital for Neurology and Neurosurgery.

3 y to the National Hospital for Neurology and Neurosurgery.

4 ely and before discharge following resective neurosurgery.

5 compared with those occurring after primary neurosurgery.

6 and pneumorrhachis are rare complications of neurosurgery.

7 ol for assisting clinical decision-making in neurosurgery.

8 (SN), in seven subjects undergoing invasive neurosurgery.

9 agnosis, prognosis and outcome prediction in neurosurgery.

10 , 995 facial surgery/otolaryngology, and 595 neurosurgery.

11 otential for guiding margin detection during neurosurgery.

12 cortex (M1) arm area in patients undergoing neurosurgery.

13 e field of basic neuroscience and functional neurosurgery.

14 actors predispose patients to pain following neurosurgery.

15 patients with severe SAH, who underwent open neurosurgery.

16 on of comprehensive epilepsy evaluations and neurosurgery.

17 urred in 376 (0.9%), and 60 (0.1%) underwent neurosurgery.

18 electrophysiologic monitoring in functional neurosurgery.

19 tion, contaminated medical products, and via neurosurgery.

20 eneficial for BBB protection during elective neurosurgeries.

21 ant 6.6%, oral-maxillofacial surgery 0%, and neurosurgery 0.5% (all p < 0.01).

22 al specialty: general, 12.5%; urology, 9.0%; neurosurgery, 10.5%; orthopedic, 9.6%; otolaryngology, 9

23 acing a claim each year ranged from 19.1% in neurosurgery, 18.9% in thoracic-cardiovascular surgery,

24 ologist, National Hospital for Neurology and Neurosurgery (1966-98); physician, Moorfields Eye Hospit

25 ean 29 years) including 9 tubal ligations, 3 neurosurgeries, 3 cholecystectomies, 3 hysterectomies, 3

26 ral-maxillofacial surgery (5.5 +/- 4.2), and neurosurgery (4.47 +/- 9.8) (all p< 0.01).

27 63.3%, oral-maxillofacial surgery 58.4%, and neurosurgery 53.1% (all p < 0.01).

28 , orthopedics (7.9%), otolaryngology (7.0%), neurosurgery (7.0%), critical care (6.0%), and urology (

29 oracic, upper abdominal, neck, vascular, and neurosurgery), age, functional status, weight loss, chro

30 th 326 (30.9%) of 1055 patients allocated to neurosurgery, an absolute risk reduction of 7.4% (95% CI

31 marmoset care and handling, and small-animal neurosurgery; an assistant for monitoring the animal and

32 with monolateral NK from 1 to 19 years after neurosurgery and 20 age- and sex-matched healthy partici

33 Subspecialization in pediatric neurosurgery and critical care has resulted in more favo

34 deep brain stimulation hardware, and general neurosurgery and head trauma.

35 genic diet, hypothermia, emergency resective neurosurgery and multiple subpial transection, transcran

36 e been widely adopted in specialties such as neurosurgery and otorhinolaryngology.

37 ls (Annals of Surgery, Journal of Neurology, Neurosurgery and Psychiatry, Journal of Heart and Lung T

38 medical management, endovascular procedures, neurosurgery and radiotherapy.

39 tion of the EZ is crucial for candidates for neurosurgery and requires unambiguous criteria that eval

40 randomized trials and retrospective series, neurosurgery and stereotactic radiosurgery (SRS) may pro

41 cause of morbidity, the effects of resective neurosurgery and their relation to tumour pathology are

42 s to the anesthetic management of functional neurosurgery and to describe the application of an alpha

43 nd intrasurgical metastatic diagnosis, guide neurosurgeries, and monitor treatment response.

44 4544 (23%) were admitted, 83 (<1%) underwent neurosurgery, and 15 (<1%) died.

45 uro-oncology, neurology, radiation oncology, neurosurgery, and ophthalmology met to review current st

46 Patients with thrombocytopenia, recent neurosurgery, and tumor types prone to bleeding require

47 ogy, pediatric general surgery and pediatric neurosurgery are cited.

48 epilepsy and endoscopic and cerebrovascular neurosurgery are constantly being adapted to the pediatr

49 largely responsible for the establishment of neurosurgery as a separate discipline.

50 , sham surgeries) and underwent stereotactic neurosurgery at 35 days; 5 rats of each group were kille

51 o September 2013 (post-SCM) to Orthopedic or Neurosurgery at our institution.

52 , sham surgeries) and underwent stereotactic neurosurgery at post-natal day 35; 5 rats of each group

53 onal status, clinical service (neurology vs. neurosurgery), attending status (private vs. academic),

54 ediatric, reconstructive, obstetric fistula, neurosurgery, burn, general surgery, obstetric emergency

55 Resective neurosurgery carries the risk of postoperative cognitive

56 ology but also in neurology, neuroradiology, neurosurgery, clinical neuropsychology, ophthalmology, p

57 ne, immunotherapy, ketogenic diet, emergency neurosurgery, electroconvulsive therapy, cerebrospinal f

58 management with interventional therapy (ie, neurosurgery, embolisation, or stereotactic radiotherapy

59 sective thoracic surgery, abdominal surgery, neurosurgery, emergency surgery, general anesthesia, hea

60 safe and ethical conduct of any psychiatric neurosurgery, ensuring documented refractoriness of pati

61 o SSIs was $23,755 among patients undergoing neurosurgery, followed by patients undergoing orthopedic

62 We enrolled 109 adults who needed neurosurgery for acute TBI.

63 and basal ganglia in awake humans undergoing neurosurgery for movement disorders (n = 13 Parkinson's

64 Developments in functional neurosurgery for movement disorders and recent advances

65 Modern functional neurosurgery for movement disorders such as Parkinson's

66 in eight awake patients following functional neurosurgery for Parkinson's disease.

67 eld joystick in six awake patients following neurosurgery for Parkinson's disease.

68 nded woman was admitted to the Department of Neurosurgery for surgical treatment of brain tumor.

69 required specific expertise in neurology or neurosurgery for the health care professional who determ

70 amic nucleus of humans undergoing functional neurosurgery for the treatment of Parkinson's disease, w

71 lation (DBS) has virtually replaced ablative neurosurgery for use in medication-refractory movement d

72 endent at 10 years than were patients in the neurosurgery group (OR 1.34, 95% CI 1.07-1.67).

73 Early neurosurgery has a role limited to decompression of lesi

74 Functional neurosurgery has afforded the opportunity to assess inte

75 For nearly a century, functional neurosurgery has been applied in the treatment of tremor

76 intraoperative magnetic resonance imaging in neurosurgery has increased significantly within the last

77 rative use of magnetic resonance imaging for neurosurgery has increased steadily since the implementa

78 As the practice of neurosurgery has moved towards less invasive procedures

79 developments in the fields of neurology and neurosurgery have led to improved treatments for the cri

80 PET facility located within the Neurology/Neurosurgery ICU.

81 e at The National Hospital for Neurology and Neurosurgery in London who came to neuropathological exa

82 ng the period 1999-2010 at the Department of Neurosurgery in Oxford, UK.

83 e at the National Hospital for Neurology and Neurosurgery in the United Kingdom.

84 Neither rule missed neurosurgery in validation populations.

85 ve future directions for functional lesional neurosurgery, in particularly potential trial designs, a

86 e data showed several applications of ANN in neurosurgery, including: (1) diagnosis and assessment of

87 draw mechanical ventilation in the neurology/neurosurgery intensive care unit are based primarily on

88 ,109 nonelective admissions to the neurology/neurosurgery intensive care unit who received mechanical

89 cal ventilation from patients in a neurology/neurosurgery intensive care unit.

90 or ciTBI (death from traumatic brain injury, neurosurgery, intubation >24 h, or hospital admission >o

91 The prevalence of ciTBI (defined as death, neurosurgery, intubation for >24 hours, or hospitalizati

92 me measures were ciTBIs (resulting in death, neurosurgery, intubation for >24 hours, or hospitalizati

93 Finally, the future of ANNs in neurosurgery is explored.

94 erience of dexmedetomidine use in functional neurosurgery is limited to small case-series.

95 Three areas of vascular neurosurgery literature have recently generated signific

96 iseases, National Hospital for Neurology and Neurosurgery, London, UK.

97 s at the National Hospital for Neurology and Neurosurgery, London.

98 .7%]), otolaryngology (n = 470 [11.2%]), and neurosurgery (n = 2067 [8.4%]) were specialties with the

99 ology, endovascular surgical neuroradiology, neurosurgery, neurointensive care, anesthesiology, nursi

100 rounds (i.e., interventional neuroradiology, neurosurgery,neurology, peripheral interventional radiol

101 Neurosurgery, obstetrical, cardiac, and outpatient surge

102 radigm shift from 'radical' prostatectomy to neurosurgery of the prostate.

103 re require a united input from neurology and neurosurgery, oncology, and palliative care.

104 ISPAOCT system has potential applications in neurosurgery, ophthalmological surgery, and other micros

105 Many specialties such as gynecology, neurosurgery, ophthalmology, and chest disorders were su

106 t includes specialists from plastic surgery, neurosurgery, ophthalmology, otolaryngology, oromaxillof

107 al, within 2 years) between cases undergoing neurosurgery or gynecological surgery INTERPRETATION: It

108 f life (p <.001), and being cared for by the neurosurgery or neurology services (p =.002).

109 e moment of death; and c) being cared for by neurosurgery or neurology services.

110 nded the National Hospital for Neurology and Neurosurgery or the Royal Free Hospital, London, UK, wer

111 ments for the subspecialties of dermatology, neurosurgery, orthopedic surgery, and urology ranged fro

112 Pennsylvania physicians in general surgery, neurosurgery, orthopedic surgery, obstetrics/gynecology,

113 m order until all 5 clusters-cardiothoracic, neurosurgery, orthopedic, general, and urologic surgery

114 surgical specialty groups: general, urology, neurosurgery, orthopedic, otolaryngology, plastic, thora

115 n at the National Hospital for Neurology and Neurosurgery over the past 10 years.

116 yzed surgery types, deep SSIs and SSIs among neurosurgery patients are associated with the highest ri

117 ranial electrical brain stimulation in awake neurosurgery patients is a powerful means to determine t

118 cal stimulation functional mapping (ESFM) in neurosurgery patients, we identified three subjects who

119 e sedation in the ICU (adult and pediatric), neurosurgery, pediatric procedural sedation, awake fiber

120 tensive care, emergency medicine, neurology, neurosurgery, pulmonology) who may also participate in t

121 ally The National Hospital for Neurology and Neurosurgery Queen Square and University College London,

122 Despite recent advances in neurosurgery, radiation, and chemotherapy, the prognosis

123 izing in anesthesiology, orthopedic surgery, neurosurgery, radiology, cardiovascular surgery, obstetr

124 sthesiology, surgery, internal medicine) and neurosurgery residents.

125 ritical care attending staff and fellows and neurosurgery residents.

126 ation to in vivo case examples from clinical neurosurgeries revealed changes to the localization and

127 he authors reviewed the medical records of a neurosurgery specialty clinic to identify patients with

128 WBRT, neurosurgery, SRS, and medical therapy each have a role

129 Given the risks inherent in any psychiatric neurosurgery, such procedures should be conducted at spe

130 h Parkinson's disease were studied following neurosurgery that implanted high-frequency stimulating e

131 impairment, which resulted from experimental neurosurgery to control seizures, was the subject of stu

132 ns in slices of brain tissue resected during neurosurgery to investigate spike timing-dependent synap

133 have contributed peer-reviewed articles on a neurosurgery topic that remains controversial: the value

134 al aortic aneurysm repair, thoracic surgery, neurosurgery, upper abdominal surgery, peripheral vascul

135 ediatric, reconstructive, obstetric fistula, neurosurgery, urology, ENT, craniofacial, burn, and gene

136 etween the proportion of patients in need of neurosurgery with GCS scores of 3 to 8 and those with GC

137 intraoperative magnetic resonance imaging in neurosurgery with special emphasis on the quality of ava

138 hy onto intraoperative scans acquired during neurosurgery, with the potential to reduce the risk of V