ライフサイエンスコーパス: subdural

1 hile, Brain computed tomography demonstrated subdural abscess in right parietal area.

2 Using subdural and depth recordings from epileptic patients, w

3 ence of diffuse cerebral oedema, presence of subdural and extradural hematoma; however in isolation t

4 A sensor was tested subdural and in vitro, simulating a supine infant with a

5 Although complications such as intracystic, subdural, and extradural hematomas are well known after

6 n death was induced by sudden inflation of a subdural balloon catheter with continuous monitoring of

7 Brain death was induced by inflation of a subdural balloon in ten mongrel dogs weighing 23 to 30 k

8 s were skull fractures (36% of cases), acute subdural bleeding (72%) and retinal haemorrhages (71%);

9 correlated with the increasing volume of the subdural blood clot (sham: 9+/-3 mm3; 200 microl: 81+/-1

10 ter and again at 2 h after completion of the subdural blood infusion.

11 e (ICP) was monitored in all patients with a subdural catheter (Camino Systems, San Diego, CA) for up

12 g studies revealed a large mixed-attenuation subdural collection in the right frontal region with pro

13 aminations showed no white matter changes or subdural collections.

14 sies, 12 intracranial cyst evaluations, four subdural drainages, and five transsphenoidal pituitary r

15 e and interictal spike frequency measures on subdural ECoG recording may both be useful in predicting

16 High density scalp EEG and subdural ECoG recordings provide an opportunity to map t

17 Subdural ECoG signals were recorded while each patient v

18 ured local cortical activity using arrays of subdural electrocorticographic (ECoG) electrodes in huma

19 Subdural electrocorticographic (ECoG) recordings in pati

20 human functional brain mapping, we recorded subdural electrocorticographic (ECoG) signals in five cl

21 wed by 2-stage epilepsy surgery with chronic subdural electrocorticographic monitoring, and were seiz

22 quency measures obtained from extraoperative subdural electrocorticography (ECoG) recording could pre

23 sequently recorded cortical physiology using subdural electrocorticography during a spatial-attention

24 tentials from hand sensorimotor cortex using subdural electrocorticography during a visually cued, in

25 ation surgery, we use the novel technique of subdural electrocorticography in combination with subtha

26 To address this, we utilized subdural electrocorticography to study cortical oscillat

27 We do so using invasive subdural electrode arrays from a population of 16 patien

28 imeslicing), in a subject in whom indwelling subdural electrode arrays had been placed for clinical p

29 with motor movement across 22 subjects with subdural electrode arrays placed for identification of s

30 graphy (ECoG) signals measured directly from subdural electrode arrays that were implanted in patient

31 It can help guide subdural electrode implantation and narrow the search fo

32 Thirteen patients had undergone subdural electrode implantation for the surgical managem

33 After subdural electrode implantation, we used DCS to localize

34 propofol-anaesthetized juvenile swine using subdural electrode strips (electrocorticography) and int

35 preading depolarizations were monitored with subdural electrode strips and regional cerebral blood fl

36 corticography [duration: 54 h (34, 66)] from subdural electrode strips was analysed over Days 0-3 aft

37 electrocorticographic recordings obtained by subdural electrode-strip monitoring during intensive car

38 ECoG from 63 subdural electrodes (500 Hz/channel) chronically implant

39 cy oscillations were seen in recordings from subdural electrodes adjacent to the microelectrode array

40 s by stimulating a part of the brain through subdural electrodes and recording the cortical evoked po

41 These patients had chronic implantation of subdural electrodes covering part of the lateral and med

42 42 years) underwent invasive monitoring with subdural electrodes for epilepsy surgery.

43 EEG studies from subdural electrodes have demonstrated a face-specific ev

44 ecorded high gamma (62-100 Hz) activity from subdural electrodes implanted for seizure monitoring.

45 ctrical stimulation of chronically implanted subdural electrodes in 34 patients (mean age, 12.2 years

46 cortex (M1), using electocorticography from subdural electrodes in four patients while they performe

47 re recorded from human temporal cortex using subdural electrodes in order to investigate in greater a

48 face perception in a patient implanted with subdural electrodes in the right inferior temporal lobe.

49 using electrocorticographic recordings from subdural electrodes over frontal and temporal cortices.

50 ed brain-computer interface that consists of subdural electrodes placed over the motor cortex and a t

51 ctrodes, and the precise localization of the subdural electrodes was defined by MRI co-registration.

52 The exact location of the subdural electrodes was determined on high-resolution th

53 nd verb generation in 11 humans in whom 1210 subdural electrodes were implanted.

54 Subdural electrodes were placed over the prefrontal cort

55 lated visual cortex in humans implanted with subdural electrodes while recording from other brain sit

56 ored by invasive electrocorticography (ECoG; subdural electrodes) and noninvasive scalp EEG during in

57 ified with intracranial recordings (depth or subdural electrodes).

58 s performed by electrical stimulation of the subdural electrodes, and the precise localization of the

59 rect cortical stimulation (DCS) of implanted subdural electrodes.

60 on that a greater proportion of patients had subdural empyema and hemiparesis in 2011-2013.

61 %), two intraventricular masses (0.05%), two subdural fluid collections (0.05%), and two other tumors

62 magnetic resonance imaging findings include subdural fluid collections, enhancement of the pachymeni

63 ing of the brain, pituitary enlargement, and subdural fluid collections.

64 Chronic subdural haematoma causes serious morbidity and mortalit

65 ients aged 18 years and older with a chronic subdural haematoma for burr-hole drainage were assessed

66 a drain after burr-hole drainage of chronic subdural haematoma is safe and associated with reduced r

67 The results indicate that following acute subdural haematoma, a rapid cellular redistribution of a

68 ors, if any, are associated with presence of subdural haematoma.

69 2 h or 4 h following production of an acute subdural haematoma.

70 Subdural haematomas are thought to be uncommon in babies

71 Subdural haematomas occurred in two patients.

72 onates; to study the natural history of such subdural haematomas; and to ascertain which obstetric fa

73 Presence of unilateral and bilateral subdural haemorrhage is not necessarily indicative of ex

74 All babies with subdural haemorrhage were assessed clinically but no int

75 lso to have a skull fracture, a thin film of subdural haemorrhage, but lack extracranial injury.

76 s in symptomatic neonates and babies in whom subdural haemorrhages are detected fortuitously.

77 We aimed to establish the frequency of subdural haemorrhages in asymptomatic term neonates; to

78 They tend to have larger subdural haemorrhages, and where traumatic axonal injury

79 Nine babies had subdural haemorrhages: three were normal vaginal deliver

80 in >/=2% of patients were hematuria (2%) and subdural hematoma (2%).

81 ere 128 subarachnoid hemorrhage (33.4%), 134 subdural hematoma (35.0%), and 121 intraparenchymal hemo

82 agonist, BAY X3702, in a rat model of acute subdural hematoma (ASDH).

83 Among 10010 patients with subdural hematoma (mean age, 69.2 years; 3462 women [34.

84 The rat subdural hematoma (SDH) model produces a zone of ischemi

85 In that series, one patient died of subdural hematoma 380 days after implant.

86 ceiving apixaban who developed a spontaneous subdural hematoma and declining mental status that impro

87 There were 6 cases of subdural hematoma and intracranial injury reported in fo

88 ticularly among those >80 yrs of age (36% of subdural hematoma cohort), in lower income patients, in

89 Neurosurgical intervention for subdural hematoma decreased from 41% in 1998 to 31% in 2

90 Subdural hematoma evacuation was associated with decreas

91 The increased incidence of subdural hematoma from 2000 to 2015 appears to be associ

92 Incidence of subdural hematoma has been reported to be increasing.

93 The prevalence and total cost for subdural hematoma has increased significantly in the las

94 Subdural hematoma incidence and antithrombotic drug use

95 bdural hematoma risk and determine trends in subdural hematoma incidence and antithrombotic drug use

96 The overall subdural hematoma incidence rate increased from 10.9 per

97 dural hematoma with antithrombotic drug use, subdural hematoma incidence rate, and annual prevalence

98 Hospitalizations for subdural hematoma increased from 59,373 (30 per 100,000

99 The prevalence of subdural hematoma increased with age (p < .001), particu

100 Subdural hematoma is a common type of intracranial hemor

101 Health resource consumption for subdural hematoma is increasing without clear evidence t

102 Subdural hematoma occurred in 18% of HI (5% of TP), with

103 Subdural hematoma occurred in 8 patients (2 in the core

104 of various ages, particularly rib fractures, subdural hematoma of the brain, and retinal hemorrhages.

105 rge disposition, length of stay, and cost of subdural hematoma over time.

106 tients aged 20 to 89 years with a first-ever subdural hematoma principal discharge diagnosis from 200

107 tion between use of antithrombotic drugs and subdural hematoma risk and determine trends in subdural

108 ritical care unit with an acute nontraumatic subdural hematoma that required emergent surgical evacua

109 f subdural hematoma; and the highest odds of subdural hematoma was associated with combined use of a

110 The risk of subdural hematoma was highest when a VKA was used concur

111 Association of subdural hematoma with antithrombotic drug use, subdural

112 rmatory cranial CT scan revealed a worsening subdural hematoma with midline shift, a single dose of f

113 echanical fall with head trauma resulting in subdural hematoma with no associated neurological defici

114 (43%, 26/60); central pontine myelinolysis, subdural hematoma, acute infarcts, and Aspergillus brain

115 in injury, primary intracerebral hemorrhage, subdural hematoma, brain tumor, central nervous system i

116 ciousness or amnesia for more than 24 hours, subdural hematoma, or brain contusion).

117 for later seizures were brain contusion with subdural hematoma, skull fracture, loss of consciousness

118 8-4.03]) were associated with higher risk of subdural hematoma.

119 A CT scan of his head revealed a subdural hematoma.

120 s old, 66% were male patients, and 62.6% had subdural hematoma; admission Glasgow Coma Scale score wa

121 drug use was associated with higher risk of subdural hematoma; and the highest odds of subdural hema

122 ognostic factors following surgery for acute subdural hematomas (ASDHs) in England and Wales over a 2

123 Subdural hematomas (SDH) can induce ischemia and neurona

124 morrhagic contusions or underlying evacuated subdural hematomas was studied.

125 djacent to cerebral contusions or underlying subdural hematomas, even brief periods of hyperventilati

126 may shorten detection time for epidural and subdural hematomas, increase sensitivity (especially for

127 Major discrepancies were four subdural hematomas, one pneumocephalus, one hemorrhagic

128 ury, only one (1%) of 70 children had spinal subdural hemorrhage at presentation; this patient had di

129 icance of the proportion of the spinal canal subdural hemorrhage in abusive head trauma versus that i

130 The comparison of incidences of spinal subdural hemorrhage in abusive head trauma versus those

131 21 years were tabulated for histopathology: subdural hemorrhage in the optic nerve sheath, intrascle

132 Spinal canal subdural hemorrhage was present in more than 60% of chil

133 maging, and 24 (63%) of 38 had thoracolumbar subdural hemorrhage.

134 t are characteristic of abusive head trauma--subdural hemorrhages, optic nerve sheath hemorrhages, an

135 As a conclusion, spontaneous subdural hygroma is a rare complication of the arachnoid

136 Subdural infusion of CA-I in rats induced cerebral vascu

137 tempted to mimic the actions of glutamate by subdural infusion of the selective glutamate receptor ag

138 Initiation of EAE or subdural injection of IL-1beta induces a similar cytokin

139 Our findings provide proof-of-principle that subdural intraspinal pressure at the injury site can be

140 Perivascular, subdural meningeal and choroid plexus macrophages are no

141 xtraction had a significantly higher rate of subdural or cerebral hemorrhage (odds ratio, 2.7; 95 per

142 dence interval, 1.8 to 3.4), but the rate of subdural or cerebral hemorrhage associated with vacuum e

143 heart failure, chest pain, other angina, and subdural or extradural haemorrhage.

144 ve patients with refractory epilepsy in whom subdural or intracerebral electrodes were implanted for

145 ither spontaneous intracerebral, spontaneous subdural, or postoperative.

146 obes were inserted to simultaneously monitor subdural pressure below the injury and extradural pressu

147 pressure at the injury site was higher than subdural pressure below the injury or extradural pressur

148 k of high frequency oscillations in adjacent subdural recording sites, despite the presence of a stro

149 When applied to the broader subdural recording, this measure consistently predicted

150 Here we describe subdural recordings from epileptic patients learning to

151 ing depolarizations were first identified in subdural recordings, and EEG was then examined visually

152 recordings in conjunction with intracranial subdural recordings, we asked whether fine duration disc

153 ction of 100 or 200 microl of blood into the subdural space (SDH) or into the caudate nucleus (ICH) o

154 isation to receive a drain inserted into the subdural space and 107 to no drain after evacuation.

155 The injection of blood into the subdural space or into the brain parenchyma induced bloo

156 n of 400 microl of autologous blood into the subdural space.

157 Insertion of subdural spinal pressure probe.

158 ble, small molecules can diffuse through the subdural/subarachnoid space into the underlying neocorte

159 tal high frequency activity at the cortical (subdural) surface.

160 Seventeen neonates with ICHs (16 subdural, two subarachnoid, and six parenchymal hemorrha