ライフサイエンスコーパス: craniotomy

1 2%) underwent delayed cranial surgery (DC or craniotomy).

2 ring and Spearman rho = -0.066 [P = .83] for craniotomy).

3 d seizure were partial seizures and previous craniotomy.

4 lectrical stimulation by a mid-line circular craniotomy.

5 interventional neurorehabilitation following craniotomy.

6 niectomy (DC), and 17 of 148 (11%) underwent craniotomy.

7 isation and promote functional recovery post-craniotomy.

8 ding non-ICU postoperative care for elective craniotomy.

9 tients receiving non-ICU care after elective craniotomy.

10 ICU postoperative care pathways for elective craniotomy.

11 spital length of stay in patients undergoing craniotomy.

12 onitor and only 134 of 335 (45.6%) underwent craniotomy.

13 nes for intracranial pressure monitoring and craniotomy.

14 al pressure monitoring and 6.7% to 76.2% for craniotomy.

15 utyl cyanoacrylate and 2 via a right frontal craniotomy.

16 nt in the weeks and months after the initial craniotomy.

17 reatment of acute and chronic pain following craniotomy.

18 and chronic pain is common in patients after craniotomy.

19 ir, coronary artery bypass graft surgery, or craniotomy.

20 the adjacent and contralateral regions or by craniotomy.

21 rface of profoundly deaf signer during awake craniotomy.

22 d from 0.3% for hip replacement to 10.7% for craniotomy.

23 ciplinary standardized teams to enable awake craniotomies.

24 rtion of hospitals met the minimum caseload: craniotomy (33%), pediatric heart surgery (25%), repair

25 e spleen/pelvis/liver/other (9%), neck (9%), craniotomy (4%), and aortic endostenting (6%).

26 ying membrane potential changes over a large craniotomy (50 mm2) that encompassed both the sensory an

27 A midline craniotomy (5mm diameter) was performed extending 2mm an

28 There were 111 craniotomies, 68 biopsies, 12 intracranial cyst evaluati

29 ling of the mortality rate were 64 cases for craniotomy, 77 for esophageal resection, 86 for pancreat

30 After craniotomy, a temperature probe was inserted into deep w

31 Craniotomy, according to the results from trials, does n

32 Delayed decompressive craniectomy or craniotomy after initial conservative treatment (n=982)

33 rdization compared with treatment with awake craniotomy after standardization.

34 did not improve the neurologic outcome after craniotomy among good-grade patients with aneurysmal sub

35 omprised 536 patients, of whom 134 had awake craniotomies and 402 had asleep resection.

36 ions on MR images who subsequently underwent craniotomy and biopsy and in eight volunteers (aged 21-5

37 being increasingly used as an alternative to craniotomy and clipping for some ruptured intracranial a

38 s: endovascular detachable-coil treatment or craniotomy and clipping.

39 gnetic resonance imaging scanning, and awake craniotomy and cortical stimulation as means to maximize

40 The time interval from injury to craniotomy and direct admission to a neurosurgical unit

41 ungal etiology was made following a parietal craniotomy and excisional biopsy by observation of septa

42 The surgery involves tracheal intubation, craniotomy and fixation of Luer fittings, and induction

43 Following craniotomy and fractionated radiation therapy with concu

44 survivals were observed among those who had craniotomy and initiated AT with a modest (27-37 days) o

45 elivery to the brain, while not feasible via craniotomy and intracerebral injection, is possible if t

46 issue penetration of visible light, invasive craniotomy and intracranial implantation of tethered opt

47 ng, thus allowing brain mapping during awake craniotomy and microelectrode recording during implantat

48 erapy vs radiation therapy and ICI following craniotomy and microsurgical brain metastasis resection.

49 s of leukocytes in mouse models of S. aureus craniotomy and PJI complemented with patient samples fro

50 This is especially relevant for craniotomy and prosthetic joint infections (PJI), both o

51 ses such as glioblastomas which require both craniotomy and radiological treatment monitoring.

52 Craniotomy and resection of this area showed only necrot

53 ients with supratentorial GBM that underwent craniotomy and resection.

54 nts undergoing major abdominal surgeries and craniotomies, and (2) the effect of PEEP is differed by

55 nd included clinical deterioration, need for craniotomy, and death.

56 r, coronary artery bypass graft surgery, and craniotomy, and for RS of 4 postoperative complications

57 Cerebral angiogram, craniotomy, and gastrostomy were independently associate

58 ry bypass graft surgery, elective colectomy, craniotomy, and hip fracture) conditions using risk-adju

59 ld Health Organization score, performance of craniotomy, and number of brain metastases did not influ

60 nted in the rectus sheath within 24 hours of craniotomy, and retrieved after a 24-hour in situ incuba

61 lving patients undergoing cardiac, vascular, craniotomy, and spinal surgery at 2 academic medical cen

62 peritoneal or ventriculoatrial shunts, prior craniotomy, and systemic chemotherapy.

63 females, 22-57 age range) underwent either a craniotomy, Anterior Temporal Lobectomy (ATL), or a less

64 cranial microsurgery, wherein small to large craniotomies are performed on the overlying skull for in

65 Craniotomies are performed to treat a variety of intracr

66 ine vascular network in murine brain without craniotomy as well as that in the murine dorsal skin.

67 is high for patients with any indication for craniotomy, as compared with the background population.

68 nary artery bypass graft (CABG) surgery; and craniotomy at 8 centers between January 1, 2010, and May

69 Treatment with an awake craniotomy before standardization compared with treatmen

70 lateral lesions who underwent elective awake craniotomies between January 2016 and December 2021 were

71 ly warrant surgical evacuation by means of a craniotomy (bone flap replaced) or decompressive craniec

72 tericin B lipid complex, itraconazole, and a craniotomy but later died from secondary complications c

73 Craniotomy by itself induced a generalized increase in A

74 ingle or multiple operating room burr holes, craniotomy, corticosteroids as a main or adjuvant therap

75 Craniotomy (crani) was performed in 3.6% of all HI (1% o

76 nm) is an alternative but currently requires craniotomy, cranial windows and skull thinning technique

77 pproaches combined into two classifications: craniotomy/craniectomy and external ventricular draining

78 nderwent urgent neurosurgical interventions (craniotomy/craniectomy or intracranial monitor/drain ins

79 Craniotomy created through the base of the skull has imp

80 -17 minutes in hypotensive patients, and for craniotomy decreased from 88+/-54 to 67+/-49 minutes.

81 l)lysine (CML)-mouse serum albumin (MSA), on craniotomy defect healing in normal animals was then ass

82 e healing and bone formation in standardized craniotomy defects created in BALB/cByJ mice was determi

83 The results indicated that craniotomy defects in diabetic animals healed approximat

84 ts (RAGE) by immunohistochemistry in healing craniotomy defects in diabetic animals.

85 cal site infection remains a complication of craniotomy despite the use of prophylactic antibiotics a

86 00% success rates within 2 minutes and large craniotomies encompassing most of the dorsal cortex in l

87 a reservoir placement through a burr hole or craniotomy, endoscopic resection, trans-sphenoidal resec

88 Craniotomy exposed the parietal cortex for orthogonal po

89 pentobarbital anesthesia and tracheostomy, a craniotomy exposed the parietal cortex for visualization

90 is (BM) recurrence in patients who underwent craniotomy followed by adjuvant stereotactic radiosurger

91 To model this bypass, a midline craniotomy followed by interhemispheric (IH) pial remova

92 drilling the sutures in patients undergoing craniotomies for a variety of neurosurgical procedures.

93 ize this 'Craniobot' for performing circular craniotomies for coverslip implantation, large craniotom

94 aniotomies for coverslip implantation, large craniotomies for implanting transparent polymer skulls f

95 Craniotomies for tumor resection performed with preopera

96 al trial, patients were scheduled to undergo craniotomy for AGT determination after receiving a 1-hou

97 ost commonly performed surgical procedure is craniotomy for amygdalohippocampectomy (AH).

98 10-2014, and included patients who underwent craniotomy for brain metastasis, identified using ICD-9-

99 associated with 30-day readmission following craniotomy for brain metastasis.

100 owing discharge after an index admission for craniotomy for brain metastasis.

101 utcomes and prognosis of patients undergoing craniotomy for brain tumor.

102 ranial activity of SG in patients undergoing craniotomy for breast cancer with brain metastases (BCBM

103 perative brain tonometry at the time of open craniotomy for epilepsy surgery.

104 ents undergoing left (10) or right (2) awake craniotomy for epilepsy under local anesthesia.

105 ad neuro-ophthalmic findings after pterional craniotomy for meningioma removal or aneurysm clipping.

106 ients with cerebral metastases who underwent craniotomy for metastasis resection during the course of

107 males (mean age 60+/-12 years) who underwent craniotomy for newly diagnosed, histologically confirmed

108 erial ventriculitis following a suboccipital craniotomy for resection of an ependymoma in the 4th ven

109 ry brain injury in 24 patients who underwent craniotomy for severe traumatic brain injury.

110 poral cortex of 12 patients undergoing awake craniotomy for surgical treatment of epilepsy during tes

111 r probes, and a 5 mm diameter right temporal craniotomy for the NADH probe.

112 tical surface of 7 patients undergoing awake craniotomy for tumor excision, we investigated receptive

113 ire prolonged intensive care unit stay after craniotomy for tumor resection.

114 erwent biopsy (endoscopic endonasal vs. open craniotomy) for isolated pituitary stalk thickening were

115 rative procedures either remained unchanged (craniotomy, fracture fixation) or decreased (celiotomy).

116 A total of 228 patients were assigned to the craniotomy group and 222 to the decompressive craniectom

117 Wound complications occurred in 3.9% of the craniotomy group and in 12.2% of the craniectomy group.

118 had occurred in 30.2% of the patients in the craniotomy group and in 32.2% of those in the craniectom

119 randomization was performed in 14.6% of the craniotomy group and in 6.9% of the craniectomy group.

120 was performed in a higher proportion of the craniotomy group, but more wound complications occurred

121 uma in all regions studied in the impact and craniotomy groups.

122 Open craniotomy haematoma evacuation has not been found to ha

123 re for postoperative care following elective craniotomy has historically been ICU admission.

124 rare case of a deaf signer undergoing awake craniotomy has revealed that sensorimotor cortex is func

125 ohort study of adults who underwent elective craniotomy, hip replacement, knee replacement, spinal pr

126 omy, cholecystectomy, ventral hernia repair, craniotomy, hip replacement, or knee replacement.

127 anesthetic management of patients undergoing craniotomies in the awake state.

128 vacuation was done in 336 (24%) patients, by craniotomy in 245 (73%) of those patients and by decompr

129 cruit, enroll, and complete TMS acutely post-craniotomy in a high seizure risk population.

130 There was one craniotomy in a patient whose CT scan was initially inte

131 s; and time to emergence from propofol after craniotomy in glyt1-/- mutants and their siblings.

132 mally invasive surgical delivery that avoids craniotomy in porcine models and cadavers.

133 Local RvE1 treatment of uniform craniotomy in the parietal bone significantly accelerate

134 e aggressive resection in six, and a smaller craniotomy in two.

135 ROS profile, which led to the exploration of craniotomy infection in NADPH oxidase 2 knockout mice.

136 Craniotomy infection is characterized by complex spatial

137 al activity, which may explain, in part, why craniotomy infection persists in the presence of PMN inf

138 RNA sequencing in a mouse model of S. aureus craniotomy infection, this study revealed the complex tr

139 t for promoting S. aureus persistence during craniotomy infection.

140 acute disease in a mouse model of S. aureus craniotomy infection.

141 ofilm containment, but not clearance, during craniotomy infection.

142 ikely influences the chronicity of S. aureus craniotomy infection.

143 of these immune populations during S. aureus craniotomy infection.

144 in vitro and in vivo using a mouse model of craniotomy infection.

145 atment of complex brain tumors needing awake craniotomies is associated with significant costs.

146 Acute and chronic pain following craniotomy is frequent and underrecognized.

147 umulative risk of de novo epilepsy following craniotomy is high for patients with any indication for

148 The role for transbasal craniotomy is well established in both benign tumors and

149 ks of postoperative risk of epilepsy after a craniotomy is widely believed to be raised.

150 etic particle delivery that does not require craniotomy, is amenable to reperfusion therapy, can be c

151 is a highly invasive procedure, requiring a craniotomy larger than the implant area to place the dev

152 that postoperative non-ICU care for elective craniotomies led to length of stay reduction ranging fro

153 nd precisely remove the skull from a desired craniotomy location.

154 7 days) or a longer delay (>= 38 days) after craniotomy may be the preferred timing in the elderly GB

155 ser extent and magnitude were present in the craniotomy only group.

156 days after cerebral cortex impact injury or craniotomy only in adult male Sprague-Dawley rats.

157 to the impact and in both hemispheres after craniotomy only.

158 bral perfusion in real time in patients with craniotomies or burr holes.

159 nically implanted with a glass window over a craniotomy or a thinned-skull surface, the postsurgical

160 netic neuromodulation in live mice without a craniotomy or brain implants.

161 file of H-SRT alone or in addition to repeat craniotomy or concomitant chemotherapy.

162 umatic acute subdural hematoma who underwent craniotomy or decompressive craniectomy, disability and

163 l hematoma were randomly assigned to undergo craniotomy or decompressive craniectomy.

164 (n=39) or Paratrend (n=4) PO2 probes during craniotomy or in the intensive care unit.

165 r invasive routes of administration, such as craniotomy or intracarotid arterial infusion of noxious

166 e of edema-directed therapies, decompressive craniotomy, or 3-month Glasgow Outcome Scale.

167 tients either underwent awake mapping during craniotomy, or asleep resection, as per treating physici

168 copic resection, trans-sphenoidal resection, craniotomy, or multiple procedure types.

169 ntact skull thinning and open small to large craniotomies over the dorsal cortex.

170 The study was based on 8948 first-time craniotomy patients in Denmark 1 January 2005 to 31 Dece

171 15 major abdominal surgery patients and 5063 craniotomy patients.

172 In elective craniotomy, perioperative anemia was associated with inc

173 e index patient ultimately required an awake craniotomy procedure to confirm safe resection margins i

174 After pterional craniotomy, ptosis, diplopia, and vertical gaze limitati

175 , the CV-Craniobot enables rapid and precise craniotomies, reducing surgery time compared to human pr

176 Performing craniotomies requires skill, time, and precision to avoi

177 Here, we present a computer vision-guided craniotomy robot (CV-Craniobot) that uses machine learni

178 ened, the extent of resection increased, and craniotomy size decreased.

179 ntified in human brain metastases from eight craniotomy specimens and in primary cultures of astrocyt

180 f the immune response was performed on eight craniotomy specimens where a granuloma surrounded each T

181 Although surgical site infections after a craniotomy (SSI-CRAN) are a serious problem involving si

182 Although surgical site infections after a craniotomy (SSI-CRANs) are a serious problem that involv

183 Craniotomies tailored to limit cortical exposure, even w

184 edures, including deep brain stimulation and craniotomies that require tissue removal near elegant co

185 With this small craniotomy, the frontal sinus was kept intact, thus keep

186 tate and implanted through a small burr-hole craniotomy, then expanded on the surface of the brain fo

187 nomic evaluation of standardization of awake craniotomy, there was a generalized reduction in length

188 face (BCI) implants have previously required craniotomy to deliver penetrating or surface electrodes

189 r resection or epilepsy treatment requires a craniotomy to gain access to the brain.

190 received a cortical impact through a 6.3 mm craniotomy under halothane anesthesia.

191 maging of mouse cerebral vasculature without craniotomy utilizing the intrinsic photoluminescence of

192 urred at 3 months and at 6 months with awake craniotomy versus asleep resection in patients younger t

193 In the overall matched cohort, awake craniotomy versus asleep resection resulted in fewer neu

194 Craniotomy was associated with higher complication rates

195 A frontoparietal bilateral craniotomy was created.

196 A craniotomy was performed over the ventral medulla to exp

197 A left fronto-parietal craniotomy was performed, with an intraoperative awake l

198 1.39; 95% CI, 1.04-1.74; P = 0.01); however, craniotomy was superior to minimally invasive procedures

199 dy population (major abdominal surgeries and craniotomies), we found an association between applicati

200 Wide craniotomies were applied in 11 pigs (weight, approximat

201 or = 60% who were eligible for cytoreductive craniotomy were enrolled.

202 ng to standard protocols including emergency craniotomy where necessary.

203 direct implantation into the brain via open craniotomy, which can lead to inflammatory tissue respon

204 te infections, including those arising after craniotomy, which is performed to access the brain for t

205 with a history of brain radiation therapy or craniotomy who underwent 1.5-T and 3-T same-plane T1-wei

206 perform small (2- to 4-millimeter diameter) craniotomies with near 100% success rates within 2 minut

207 rmany included individuals who had undergone craniotomy with brain metastasis resection from January

208 l perfusion was assessed in 9 dogs through a craniotomy with CEU at baseline and during hypercapnia a

209 Patients were to be treated 18 hours before craniotomy with intravenous doses that ranged between 40

210 l brain injury was induced via right frontal craniotomy with resection of the right frontal lobe.

211 ed outcomes for patients undergoing elective craniotomies without postoperative ICU care.

212 e whether intraoperative cooling during open craniotomy would improve the outcome among patients with