ライフサイエンスコーパス: jugular

1 veins were the internal mammary and internal jugular.

2 ctions/1,000 catheter days (0.45%), internal jugular: 0/1,000 (0%), and femoral: 2.98/1,000 (1.44%; p

3 eter-related bloodstream infection (internal jugular 1.0 vs. femoral 1.1 per 1,000 catheter-days; haz

4 , major catheter-related infection (internal jugular 1.8 vs. femoral 1.4 per 1,000 catheter-days; HR,

5 2.18]; P = 0.34), and colonization (internal jugular 11.6 vs. femoral 12.9 per 1,000 catheter-days; H

6 zation/1,000 catheter days (0.45%), internal jugular: 2.00/1,000 (1.05%), and femoral: 5.96/1,000 (2.

7 al venous catheter insertion: mean (internal jugular) = 50.6%, SD = 23.4%; mean (subclavian) = 48.4%,

8 um passing score at posttest: mean (internal jugular) = 93.9%, SD = 10.2; mean (subclavian) = 91.5%,

9 randomized order in 6 anesthetized dogs via jugular access.

10 Femoral and internal jugular accesses lead to similar risks of catheter infec

11 the subclavian vein, 10,958 in the internal jugular and 3,188 in the femoral vein for a total of 113

12 c flashlight guidance for access to internal jugular and basilic veins was demonstrated in a cadaver.

13 ble, controversy exists between the internal jugular and femoral sites for the choice of central-veno

14 enous cannulation, particularly for internal jugular and femoral sites, and for diagnosis of deep ven

15 eously from the brachial artery and internal jugular and femoral veins with plasma and RBC nitric oxi

16 s and catheter colonization between internal jugular and femoral was suppressed by the use of chlorhe

17 A bridging vein drained the right jugular and right subclavian veins and joined the left b

18 intubation; 0.4% and 2.3% pneumothorax with jugular and subclavian central venous catheter insertion

19 pleted simulation-based training in internal jugular and subclavian central venous catheter insertion

20 In ICU patients, internal jugular and subclavian may, similarly, decrease catheter

21 ltrasound guidance to cannulate the internal jugular and subclavian of a human torso mannequin using

22 n the number of redirections at the internal jugular and subclavian sites, relative risk 0.4 (95% CI,

23 dothelial cells (ECs) at the junction of the jugular and subclavian veins.

24 he blood vessels only at the junction of the jugular and subclavian veins.

25 m infection risk was comparable for internal jugular and subclavian, higher for femoral than subclavi

26 Ten studies (3250 subclavian, 3053 internal jugular, and 1554 femoral vein) met the inclusion criter

27 22 primary outcome events in the subclavian, jugular, and femoral groups, respectively (1.5, 3.6, and

28 The subclavian, internal jugular, and femoral sites were studied.

29 and colonization at the subclavian, internal jugular, and femoral sites.

30 etween the three sites (subclavian, internal jugular, and femoral) in adult ICU patients.

31 within two distinct ganglia, the nodose and jugular, and whose properties allow for differing respon

32 METHODS AND An ex vivo porcine carotid jugular arteriovenous shunt was established and connecte

33 A jugular associated cannula-associated deep vein thrombos

34 The absence of benefit of internal jugular before Day 5 was related to a higher skin coloni

35 ith central venous catheters of the internal jugular, brachial, or subclavian veins were eligible for

36 cally, they are located in the region of the jugular bulb and middle ear.

37 ntracranial pressure monitor, placement of a jugular bulb catheter, placement of a pulmonary artery c

38 found between samples from the arterial and jugular bulb catheter.

39 ood samples were taken from the arterial and jugular bulb catheter.

40 e of a fracture near a dural venous sinus or jugular bulb or a high index of clinical suspicion.

41 ther indicators of brain oxygenation such as jugular bulb oxygen saturation and near infrared spectro

42 Jugular bulb oxygenation at the start of the study was 5

43 ddle cerebral artery, pulsatility index, and jugular bulb oxygenation between survivors and nonsurviv

44 ar bulb oxygenation remained constant with a jugular bulb oxygenation of 84.0 (77.3-86.3)% at 108 hrs

45 Upon rewarming, the jugular bulb oxygenation remained constant with a jugula

46 e cerebral artery in combination with normal jugular bulb oxygenation values suggests a reduction in

47 Jugular bulb oxygenation was measured at the same interv

48 Median jugular bulb saturation at the start of the study was 61

49 erebral venous blood gases were drawn from a jugular bulb venous catheter.

50 nts of PaO2, arterial oxygen content (CaO2), jugular bulb venous oxygen tension (PVO2), venous oxygen

51 g to the transverse sinus, sigmoid sinus, or jugular bulb, those of the petrous temporal bone had a h

52 h-mobility group box-1 concentrations in the jugular bulb, whereas soluble intercellular adhesion mol

53 kull fractures extending to a dural sinus or jugular bulb.

54 kull fractures extending to a dural sinus or jugular bulb.

55 racture extending to a dural venous sinus or jugular bulb.

56 is media with cholesteatoma, and high-riding jugular bulb.

57 y depicted thrombosis of 98 dural sinuses or jugular bulbs in 57 (40.7%) of the 140 patients with sku

58 d lungs caused action potential discharge in jugular but not nodose C-fibres.

59 Airway-specific nodose and jugular C-fibre neurons express mRNA coding for the S1P

60 The jugular C-fibres also responded strongly to serotonin wi

61 ctional P2X receptors, whereas lung specific jugular C-fibres do not.

62 on potential discharge in nodose, but not in jugular C-fibres.

63 osteichthyans (facial nerve exiting through jugular canal, endolymphatic ducts exiting posterior to

64 ular facets are paired but lie dorsal to the jugular canal, representing a hitherto unobserved combin

65 nd six patients (46.2%) had both femoral and jugular cannula-associated deep vein thrombosis.

66 ed femoral arterial and venous plus internal jugular cannulation and direct aortic cross-clamping.

67 gs, we modified our previously described rat jugular catheter model and validated the importance of i

68 US guidance increased the use of internal jugular catheter placement and decreased artery puncture

69 nd on the 9th day they were implanted with a jugular catheter.

70 Lactating sows were fitted with jugular catheters and subsequently fed either 1.05 or 2.

71 Male B6 mice were implanted with jugular catheters and trained to lever press for cocaine

72 serial plasma samples were obtained through jugular catheters and were analyzed for LH levels using

73 umber of previous ultrasound-guided internal jugular catheters was 25 (interquartile range, 9-40), an

74 s met the minimum passing score for internal jugular central venous catheter insertion and 11 (14%) o

75 eeded the minimum passing score for internal jugular central venous catheter insertion and only 11 of

76 nterquartile range) number of total internal jugular central venous catheters placed was 27 (interqua

77 ing ultrasound-guided subclavian or internal jugular central venous catheters.

78 started on self-administered manual carotid jugular compressions.

79 More internal jugular CVCs were placed during the US period than durin

80 er studies, we compared femoral and internal jugular for the risks of catheter-related bloodstream in

81 n by 5 s noncontact vagal stimulation at the jugular foramen, through the internal jugular veins (ext

82 pathway from the proximal airways involving jugular ganglia afferents, the Pa5, and the somatosensor

83 hea and larynx have their cell bodies in the jugular ganglia and project to the airways via the super

84 Jugular ganglia neurons wire into a central circuit that

85 sis that both neural crest-derived neurones (jugular ganglia) and placode-derived neurones (nodose ga

86 g laryngeal afferent nerves arising from the jugular ganglia.

87 al sensory ganglia referred to as nodose and jugular ganglia.

88 to evoke action potential discharge in most jugular ganglion C-fibres.

89 atch-clamp recordings of capsaicin-sensitive jugular ganglion neurones retrogradely labelled from the

90 recording of capsaicin-sensitive nodose and jugular ganglion neurones retrogradely labelled from the

91 TRPV1-expressing airway-specific jugular ganglion neurons also express S1PR3 mRNA.

92 ived from the epibranchial placodes, whereas jugular ganglion neurons are derived from the neural cre

93 dings on airway-specific capsaicin-sensitive jugular ganglion neurons, acid (pH 5) induced two distin

94 acellular electrode positioned in the nodose/jugular ganglion.

95 ar free calcium in acutely dissociated vagal jugular ganglionic neurons.

96 the femoral group was similar to that in the jugular group (hazard ratio, 1.3; 95% CI, 0.8 to 2.1; P=

97 terval [CI], 1.5 to 7.8; P=0.003) and in the jugular group than in the subclavian group (hazard ratio

98 ed the posterior vessel wall of the internal jugular in a lifelike vascular access mannequin in the m

99 decompensation in patients undergoing Trans jugular intrahepatic Porto systemic shunts (TIPS) proced

100 Diagnosis of venous jugular invasion by means of traditional imaging is very

101 as internal jugular short axis 25%, internal jugular long axis 21%, subclavian short axis 64%, and su

102 ted by core needle biopsy of a left internal jugular lymph node demonstrated a reactive lymph node bu

103 lymphatic plexus that forms during mammalian jugular lymph sac development has been described as the

104 that are essential for the separation of the jugular lymph sac from the cardinal vein and formation o

105 We also show that Cx37 regulates jugular lymph sac size and that both Cx37 and Cx43 are r

106 sprouting and hemorrhage as well as enlarged jugular lymph sacs and lymphatic vessels.

107 ary transition from anterior lymph hearts to jugular lymph sacs in mammals.

108 early in mouse lymphatic development in the jugular lymph sacs, and later in development these Cxs b

109 R3 signalling and leads to overgrowth of the jugular lymph sacs/primordial thoracic ducts, oedema and

110 rphic mice also exhibited abnormally dilated jugular lymphatic vessels due to increased production of

111 Loss of AM signaling resulted in abnormal jugular lymphatic vessels due to reduction in lymphatic

112 assessments compared to residents' internal jugular (median, 37.04% items correct; interquartile ran

113 physicians performed higher on the internal jugular (median, 75.86% items correct; interquartile ran

114 an attending physician performance (internal jugular: median, 96%; interquartile range, 93.10-100.00;

115 Internal jugular might be preferred for female, nonchlorhexidine-

116 ilated, and a 3-F catheter was placed in the jugular (n = 1) or a 24-gauge catheter in the tail (n =

117 itation of laryngeal C neurons in the nodose/jugular (N/J) ganglia.

118 In contrast, jugular (neural crest-derived) nociceptive-like fibres i

119 Lung-specific jugular neurons did not express 5-HT3 receptor mRNA but

120 d metabolite were matched between portal and jugular (NS).

121 us catheters inserted either in the internal jugular or the femoral vein had greater risk to be colon

122 intensive care unit (ICU) to the subclavian, jugular, or femoral vein (in a 1:1:1 ratio if all three

123 Jugular oximetry and brain tissue oxygen pressure monito

124 were significantly elevated in portal versus jugular (P < 0.0001) for lactate (5.03 +/- 0.2 vs. 0.84

125 were of the nodose phenotype and 29% of the jugular phenotype.

126 site as compared to subclavian and internal jugular placement.

127 l site as compared to subclavian or internal jugular placement.

128 perative rapid PTH (ioPTH) testing, internal jugular PTH sampling with ioPTH testing to guide operati

129 receive afferent terminals arising from the jugular (rather than nodose) vagal ganglia and the outpu

130 ssociated with hemorrhaging and edema in the jugular region; a phenotype reminiscent of the human con

131 Colonization risk was higher for internal jugular (relative risk, 2.25 [95% CI, 1.84-2.75]; I = 0%

132 halamocortical circuit capable of regulating jugular sensory processing in the medulla.

133 e of posterior wall penetration was internal jugular short axis 25%, internal jugular long axis 21%,

134 o a higher skin colonization at the internal jugular site for catheters removed before Day 5.

135 The internal jugular site was associated with a significantly lower r

136 ort-axis and long-axis views at the internal jugular site.

137 infections between the femoral and internal jugular sites (risk ratio 1.35; 95% confidence interval

138 was compared to the subclavian and internal jugular sites combined.

139 between the femoral and subclavian/internal jugular sites in the two randomized controlled trials (i

140 nfection between the subclavian and internal jugular sites.

141 nd short axis at the subclavian and internal jugular sites.

142 The jugular (superior) ganglion neurones project C-fibres to

143 1.25-4.75]; I = 61%), and lower for internal jugular than femoral (relative risk, 0.55 [95% CI, 0.34-

144 ral dorsal root ganglia were more similar to jugular than nodose vagal neurons.

145 dissipation of pressure to, the "head" and "jugular" tubes.

146 Jugular vagal airway sensory neurons wire into a brainst

147 The nodose and jugular vagal ganglia supply sensory innervation to the

148 e vagal ganglia and neurones situated in the jugular vagal ganglia.

149 Jugular vagal inputs to SubM via the medullary paratrige

150 ensitivity in disease.SIGNIFICANCE STATEMENT Jugular vagal sensory pathways are increasingly recogniz

151 These data suggest that jugular vagal sensory pathways input to a nociceptive th

152 The internal jugular vein (IJ) is an attractive alternative access ro

153 be traveling within the ipsilateral internal jugular vein (IJ), were further adjusted before procedur

154 Unilateral invasion of the internal jugular vein (IJV) after subtotal thyroidectomy caused b

155 d duplex Doppler evaluations of the internal jugular vein (IJV) and vertebral vein.

156 ephalic (BCV), subclavian (SCV) and internal jugular vein (IJV).

157 cannulated in the carotid artery (sampling), jugular vein (infusion), and portal vein (infusion), und

158 B-mode ultrasound imaging of the internal jugular vein also proved the validity of the proposed me

159 ly elevated in blood drawn from the internal jugular vein and a peripheral vein.

160 amples were obtained from the right internal jugular vein and brachial artery to determine concentrat

161 -lumen catheter was inserted in the external jugular vein and connected to the Hemolung, an extracorp

162 ts equipped with microdialysis probes in the jugular vein and hippocampus received an intravenous inf

163 DVT was induced in the left jugular vein and PE was induced by introducing a preform

164 lerosis involving venoplasty of the internal jugular vein and the azygos vein.

165 h was significantly higher than the internal jugular vein aspect ratio (area under the curve 0.76; 95

166 a cava collapsibility index and the internal jugular vein aspect ratio showed poor correlation (R = 0

167 na cava collapsibility index or the internal jugular vein aspect ratio.

168 logical PaCO2, alpha-stat strategy increases jugular vein blood desaturation and cerebral oxygen extr

169 One hour later, jugular vein blood samples as well as intestinal samples

170 ipopolysaccharide or saline (controls) via a jugular vein cannula.

171 r lipopolysaccharide or sterile saline via a jugular vein cannula.

172 introducer sheath placement during attempted jugular vein cannulation were identified.

173 Wild-type (WT) and MyD88(-/-) mice underwent jugular vein cannulation.

174 ion (early parenteral nutrition, control) by jugular vein catheter (n = 62).

175 In a mouse model of jugular vein catheter infection, dabigatran reduced bact

176 h a lateral cerebroventricular cannula and a jugular vein catheter.

177 s following ultrasound-guided right internal jugular vein catheterization is exceedingly low.

178 s following ultrasound-guided right internal jugular vein catheterization is exceedingly low.

179 experience (p < 0.001); failure of internal jugular vein catheterization was associated with left-si

180 h multisensor telemetry devices and internal jugular vein catheters before being infected with Zaire

181 l Sprague-Dawley rats had carotid artery and jugular vein catheters chronically implanted, as well as

182 mates were implanted with carotid artery and jugular vein catheters for sampling and infusions at 4 m

183 Carotid artery and jugular vein catheters were implanted in C57BL/6J mice (

184 ection, dabigatran reduced bacterial load on jugular vein catheters, as well as metastatic kidney inf

185 ess rate of ultrasound-guided right internal jugular vein central venous catheter placement was 96.9%

186 on valve performance in the Contegra bovine jugular vein conduit.

187 We hypothesize that localized jugular vein delivery of prostacyclin-producing cells ma

188 ena cava stenosis due to a tunneled internal jugular vein dialysis catheter presented with hematemesi

189 enetrated the posterior wall of the internal jugular vein during cannulation.

190 ever, we observed with both cultured porcine jugular vein ECs and perfused veins that venous ECs can

191 actic protein-1 and interleukin-8 in porcine jugular vein ECs.

192 External jugular vein exposed to fat incorporated with PGZ had in

193 ing 7 days before end-to-side carotid artery-jugular vein fistula creation and for up to 42 days afte

194 Right carotid artery to internal jugular vein fistulas were created in C57BL/6 mice and a

195 The morphologic features of internal jugular vein flow were classified as absent, pinpoint, f

196 rast, injection of 10 mug of GsMTx4 into the jugular vein had no effect on the pressor, cardioacceler

197 Measurement of the internal jugular vein height to width ratio (aspect ratio), the i

198 oral vein in 17 patients, the right internal jugular vein in 4, and the left subclavian vein in 2 pat

199 the construct was placed around the external jugular vein in a porcine model.

200 led silicone 7-F catheters were placed via a jugular vein in eight swine.

201 astomosed the carotid artery to the internal jugular vein in normal and uremic mice and compared thes

202 Pulmonary embolism was induced by jugular vein infusion of (125)I-fibrin or fluorescein is

203 ely 2.5 mmol/l) clamps with either portal or jugular vein infusions of lactate, pyruvate, or BHB.

204 A single jugular vein injection offered survival benefits for at

205 ed infection compared to femoral or internal jugular vein insertion.

206 onically implanted in the carotid artery and jugular vein of male Sprague-Dawley rats.

207 d between the carotid artery and ipsilateral jugular vein of swine.

208 Significant differences were found in jugular vein oxygen saturation (83.2% [79.2-87.6%] vs. 8

209 7-1.18) versus 0.94 (0.89-1.05) (p = 0.027), jugular vein oxygen saturation was 79.2 (71.1-81.8) vers

210 Mean cerebral artery flow velocity and jugular vein oxygen saturation were measured at the end

211 ral artery flow velocities using Doppler and jugular vein oxygen saturation were measured in both str

212 In vivo studies on jugular vein rat thrombosis model showed that the clot l

213 enoviral vectors encoding betaARKct into the jugular vein represents a viable strategy to treat AV gr

214 observed between the right and left internal jugular vein samples.

215 Jugular vein temperature significantly decreased in anim

216 nal sepsis', 'necrobacillosis', or 'internal jugular vein thrombosis', is a rare but serious emerging

217 oid venous sinus thrombosis, along with left jugular vein thrombosis.

218 57BL/6 mice (n=35) underwent ligation of the jugular vein to induce stasis DVT.

219 Bypass grafting of the jugular vein to the common carotid artery was performed

220 o or three porcine thrombi into the external jugular vein via a surgically implanted 24-F sheath.

221 s detected in the fat depot, in the external jugular vein wall and in adjacent tissue at clinically r

222 perated area extending and invading the left jugular vein wall with hypervascular tumor thrombus.

223 mice, the carotid artery to the ipsilateral jugular vein was connected to create an AVF, and CorMatr

224 plasma peptide levels via cannulation of the jugular vein was performed after subcutaneous injection

225 d 62 (67%) in the control group, whereas the jugular vein was used in the remaining patients.

226 laced between carotid artery and ipsilateral jugular vein was used to assess effects of PGZ/fat depot

227 from fat depots transplanted perivascular to jugular vein were assessed by HPLC/MS/MS, and retention

228 heter thrombosis, catheters implanted in the jugular vein were assessed daily until they occluded, up

229 and segmental resection of the left internal jugular vein were performed, and the tumor thrombus was

230 explants placed perivascular to the external jugular vein were retained, as confirmed by MRI at one w

231 Transduction of the external jugular vein with Ad2/betaARKct (5E9, 5E10, or 5E11 part

232 recipient common carotid artery and external jugular vein without nerve approximation.

233 ined by a collapsible tube representing the "jugular vein".

234 ion of stepwise increments of intravenously (jugular vein) infused ammonia is almost totally dependen

235 s, inferior petrosal sinus, and the internal jugular vein), femoral vein, and radial artery of patien

236 catheterized mouse model (carotid artery and jugular vein), we show that AMPK regulates skeletal musc

237 avital microscopy of the carotid artery, the jugular vein, and cremasteric arterioles and venules in

238 ernative sites (subclavian vein vs. internal jugular vein, incidence density ratio 0.46; 95% confiden

239 e descending abdominal aorta) and catheters (jugular vein, peritoneal cavity, and distal abdominal ao

240 ing 25-mum plastic microspheres in the right jugular vein, producing mild or moderate pulmonary hyper

241 e: a septic thrombophlebitis of the internal jugular vein.

242 between the carotid artery and the internal jugular vein.

243 in the abdominal aorta and 1 in the internal jugular vein.

244 tricular nucleus (PVN) and a catheter in the jugular vein.

245 ch introducer sheath inserted into the right jugular vein.

246 The jugular vein/peripheral vein ratio was 1.4 in patients w

247 rTM was administered into the jugular-vein catheter before or 6 h after MRSA inoculati

248 Blood samples were collected from the jugular-vein catheter before, 6 h and 12 h after MRSA in

249 Male Sprague-Dawley rats with jugular-vein catheterization were divided into three gro

250 bclavian-vein insertions and 4 (0.5%) of the jugular-vein insertions.

251 bosis and a higher risk of pneumothorax than jugular-vein or femoral-vein catheterization.

252 at the jugular foramen, through the internal jugular veins (extracardiac vagal stimulation [ECVS]), a

253 blished a stasis-induced DVT model in murine jugular veins and also a novel model of recurrent stasis

254 morphologic features of flow in the internal jugular veins and vertebral veins were found between MS

255 A carotid artery and jugular veins had catheters chronically implanted for sa

256 us lines were introduced into right external jugular veins of 254 animals in three groups: enoxaparin

257 sverse, and sigmoid sinuses and the internal jugular veins on images obtained with the two sequences.

258 e developed a puncture injury model in mouse jugular veins that combines high-resolution, multimodal

259 ft internal carotid artery and both internal jugular veins were cannulated and a flow probe was place

260 and 21 days, AVFs or contralateral internal jugular veins were processed for PCR, immunofluorescence

261 ive for extracting the JVP from the anterior jugular veins, in a contact manner.

262 measure the JVP at the external and internal jugular veins.

263 place pledgeted sutures by means of a trans-jugular venous approach.

264 For both protocols, arterial and internal jugular venous blood samples were collected at rest and

265 Internal jugular venous blood was drawn from both left and right

266 Simultaneous arterial and jugular venous bulb blood gas samples were recorded pros

267 fusion pressure, mean arterial pressure, and jugular venous bulb oxygen saturation.

268 group, the mean brain tissue oxygen tension, jugular venous bulb oxygen tension, and cerebral perfusi

269 There were significant differences in the jugular venous bulb oxygen tension-brain oxygen tension

270 perfusion pressure led to a decrease in the jugular venous bulb oxygen tension-brain oxygen tension

271 brain hypoxia, there is an elevation in the jugular venous bulb oxygen tension-brain oxygen tension

272 , 11]; p < 0.001) and in the relationship of jugular venous bulb oxygen tension-brain oxygen tension

273 group, the mean brain tissue oxygen tension, jugular venous bulb oxygen to brain tissue oxygen tensio

274 moral as compared to subclavian and internal jugular venous catheterization has not been systematical

275 ue oxygenation, 2) intracranial pressure, 3) jugular venous continuous oximetry, 4) regional saturati

276 ic rate for oxygen and the arterial-internal jugular venous differences for glucose and lactate are s

277 In a subset of subjects' arterial-to-jugular venous differences were obtained to examine the

278 gns of congestion by -0.10 ( P=0.005) signs, jugular venous distention (odds ratio, 0.60; P=0.01), an

279 iation of the number of signs of congestion (jugular venous distention, edema, rales, and third heart

280 mericas with available physical examination (jugular venous distention, rales, and edema) at baseline

281 Videos show giant systolic pulsations during jugular venous examination and severe tricuspid regurgit

282 ing a mini-osmotic pump for continuous 4-day jugular venous infusion of sEVs and determined their eff

283 ng cerebral vascular conductance, increasing jugular venous noradrenaline, and falling arterial carbo

284 lood flow (ultrasound) and the radial artery-jugular venous oxygen content difference (cannulation).

285 of cerebral blood flow and the radial artery-jugular venous oxygen content difference, was reduced by

286 (ultrasound) and the radial artery-internal jugular venous oxygen content difference.

287 sensitivity, 82%; 95% CI, 72%-92%), elevated jugular venous pressure (pooled sensitivity, 76%; 95% CI

288 roup interactions: patients without elevated jugular venous pressure and those without ascites showed

289 will not have dyspnea, tachycardia, elevated jugular venous pressure, or cardiomegaly on chest radiog

290 x, higher diastolic blood pressure, elevated jugular venous pressure, recent weight gain, and lower b

291 luid bolus administration with monitoring of jugular venous pressure, respiratory rate, and arterial

292 The jugular venous pulse (JVP) is the reference physiologica

293 ble of measuring weak pulsations of internal jugular venous pulses stemming from a human neck.

294 Convective heat transfer through jugular venous return and the circle of Willis was simul

295 Paired arterial and jugular venous samples were taken before and after arres

296 tudies, somatosensory evoked potentials, and jugular venous saturation (SjO2) measurements were obtai

297 Although jugular venous saturation monitoring remains a useful me

298 ies, extra-cranial blood flows, and arterial-jugular venous substrate differences were measured durin

299 rs inserted in the subclavian vein (internal jugular vs. subclavian: hazard ratio 3.29; 95% confidenc

300 ted bloodstream infections when the internal jugular was compared to the femoral site, recent studies

301 The long-axis view for the internal jugular was more efficient than the short-axis view with