ライフサイエンスコーパス: interstitial fluid

1 that are functionally incapable of draining interstitial fluid.

2 n the steady-state Abeta levels in the brain interstitial fluid.

3 iologically relevant analytes present in the interstitial fluid.

4 y readily gain access to and function within interstitial fluid.

5 thin extracellular matrix under perfusion of interstitial fluid.

6 es between the cerebrospinal fluid (CSF) and interstitial fluid.

7 llowed by excessive entry of Ca(2+) from the interstitial fluid.

8 specific tissues, including lymph nodes, and interstitial fluid.

9 vective exchange of cerebrospinal fluid with interstitial fluid.

10 n are enveloped in their microenvironment by interstitial fluid.

11 the cells followed by Ca(2+) entry from the interstitial fluid.

12 y), resulting in the release of ATP into the interstitial fluid.

13 ation by altering Abeta clearance from brain interstitial fluid.

14 rgeting tumor cells based on the cues in the interstitial fluid.

15 high soluble Hsp27 levels in patients' tumor interstitial fluid.

16 tween models of different cell types via the interstitial fluid.

17 s present at significant levels in blood and interstitial fluid.

18 for non-invasive lithium drug monitoring in interstitial fluid.

19 ed on the optical quantitation of glucose in interstitial fluid.

20 greater than that measured between lumen and interstitial fluid.

21 ral cells under conditions characteristic of interstitial fluid.

22 n a CGM is substantially delayed relative to interstitial fluid.

23 attoos can be used to monitor metabolites in interstitial fluid.

24 biofluids, such as sweat, tears, saliva and interstitial fluid.

25 hat can simultaneously sample skin cells and interstitial fluid.

26 essures that is related to the volume of the interstitial fluid.

27 ar clearance of fluorescent dextran from the interstitial fluid.

28 y cellular lipids, relative to cytosolic and interstitial fluids.

29 As, messenger RNAs, or DNA between cells via interstitial fluids.

30 of APP were reduced, resulting in decreased interstitial fluid Abeta levels and attenuated amyloid d

31 tophan methylamide (GM 6001) increased brain interstitial fluid Abeta levels and elimination of half-

32 APP expression and soluble and interstitial fluid Abeta levels were unchanged, suggesti

33 differences in the elimination half-life of interstitial fluid Abeta measured by in vivo microdialys

34 usterin(-/-) mice had elevated CSF and brain interstitial fluid Abeta, as well as significant differe

35 nic controls and the significant decrease of interstitial fluid Abeta, but not the effects on amyloid

36 e inflammation is often accompanied by local interstitial fluid accumulation expressed as edema.

37 stitial buffer capacity and disproportionate interstitial fluid accumulation.

38 space into brain parenchyma to exchange with interstitial fluid (also known as the glymphatic system)

39 ered a significant and transient increase in interstitial fluid amyloid-beta40 levels in old plaque-b

40 The lymphatic network that transports interstitial fluid and antigens to lymph nodes constitut

41 s in a buffer that mimics the composition of interstitial fluid and blood plasma, LJM-3064 rapidly sw

42 leared in part through the exchange of brain interstitial fluid and cerebrospinal fluid along a brain

43 el accounts for vascular, transvascular, and interstitial fluid and drug transport as well as the dia

44 are a promising technique to probe the brain interstitial fluid and estimate the extracellular concen

45 lactate detection was assessed in artificial interstitial fluid and in human serum, both spiked with

46 tion of a pro-inflammatory cytokine in mouse interstitial fluid and of urinary biomarkers in patient

47 Abeta generation, its circulation within the interstitial fluid and perivascular drainage pathways an

48 Comparison of nutrient levels in tumor interstitial fluid and plasma revealed that the nutrient

49 iquely adapted for the continuous removal of interstitial fluid and proteins and is an important entr

50 levels and shortened half-life in the brain interstitial fluid and reduced amyloid plaque load in th

51 s of CED in enhancing the convective flow of interstitial fluid and reducing the drug concentration d

52 tem comprises blind-ended tubes that collect interstitial fluid and return it to the circulatory syst

53 method was successfully used for analysis of interstitial fluid and serum samples after a subcutaneou

54 lymph nodes, conduits are known to transport interstitial fluid and small molecules from afferent lym

55 RATIONALE: The transport of interstitial fluid and solutes into lymphatic vessels is

56 the hypothesis that perivascular drainage of interstitial fluid and solutes out of brain tissue is dr

57 bservations in the human brain indicate that interstitial fluid and solutes, such as amyloid-beta (Ab

58 The flow of interstitial fluid and the associated interstitial fluid

59 Unlike the blood, the interstitial fluid and the deriving lymph are directly b

60 show that osmolarity differences between the interstitial fluid and the external environment trigger

61 ngiva is supplied with lymphatics that drain interstitial fluid and transport immune cells to the lym

62 in knowledge of their roles in clearance of interstitial fluid and waste from the brain, particularl

63 c vessel function with decreased drainage of interstitial fluids and reduced dietary fat absorption.

64 vant samples including breath, urine, blood, interstitial fluid, and biopsy samples are summarized.

65 ire mouse CNS--brain and spinal cord tissue, interstitial fluid, and CSF--while having no effect on b

66 dwelling sensor needle to measure glucose in interstitial fluid, and device-integrated sweat stimulat

67 These two ions are key components of the interstitial fluid, and their concentrations change in a

68 system to account for its permeation by the interstitial fluid, and we include fluid pumping as well

69 e demonstrate that Abeta levels in the brain interstitial fluid are dynamically and directly influenc

70 der physiological condition using artificial interstitial fluid at pH 7.4, whereas the one with wildt

71 hatic system is responsible for transporting interstitial fluid back to the bloodstream, but unlike t

72 most tissues, lymphatic vessels drain excess interstitial fluid back to the venous circulation.

73 ss of the lymph pump system impacts not only interstitial fluid balance but other aspects of overall

74 molecular analysis in sweat, tears, saliva, interstitial fluid, blood, wound exudate as well as exha

75 Analysis of hippocampal interstitial fluid by in vivo microdialysis revealed a s

76 microfluidic system enhanced the exchange of interstitial fluids by 567-fold, which increased the rat

77 im through viscous fluids, such as blood and interstitial fluid, by undulating their bodies as travel

78 e calcium efflux pumps and a low-bone-marrow interstitial fluid calcium concentration.

79 kling EV molecular alterations secreted into interstitial fluids can provide an alternative, non-inva

80 changes that report on acidification of the interstitial fluid caused by an accelerated glycolysis.

81 ure of the physiological environment (blood, interstitial fluid, cell cytoplasm, etc.), and the durat

82 whether the glymphatic system, a brain-wide interstitial fluid-cerebrospinal fluid exchange describe

83 These data suggest that interstitial fluid channeling precedes and may even dire

84 il has been developed, and it shows that (1) interstitial fluid channels form before lymphatic endoth

85 zed barrier organ that must tightly regulate interstitial fluid clearance and prevent infection in or

86 suggest that the skin contains a hypertonic interstitial fluid compartment in which MPS cells exert

87 e access of macromolecules to the peripheral interstitial fluid compartment.

88 gned to serve this need by collecting dermal interstitial fluid containing biomarkers without the dan

89 t such that the glucose concentration of the interstitial fluid could be measured by spectroscopicall

90 ammatory morphology, mRNA changes, and brain interstitial fluid cytokine levels.

91 on, organelles, macromolecules) bathed in an interstitial fluid (cytosol).

92 The powder sucked interstitial fluid, dissolved slowly, and diffused into

93 glycocalyx and that the oncotic pressure of interstitial fluid does not directly determine fluid bal

94 degraded by cerebrovascular cells along the interstitial fluid drainage pathway.

95 sel stiffening, dysfunctional blood flow and interstitial fluid drainage, white matter rarefaction, i

96 could potentially be used to monitor how the interstitial fluid dynamics affect cancer microenvironme

97 s and measurement of minute amounts of human interstitial fluid extracted by iontophoresis.

98 to regulate the movement of immune cells and interstitial fluid, facilitate immune crosstalk, and ult

99 Interstitial fluid flow aligned microvessels generated f

100 mphatic regeneration by uniquely correlating interstitial fluid flow and lymphatic endothelial cell m

101 mor growth is characterized by both abnormal interstitial fluid flow and the associated interstitial

102 ferential sprouting toward paths of draining interstitial fluid flow as might occur to connect capill

103 Interstitial fluid flow in and around the tumor tissue i

104 Interstitial fluid flow in the lacunar canalicular syste

105 Because of the importance of interstitial fluid flow in tumor physiology, we also exa

106 ding is critical for skeletal integrity, and interstitial fluid flow is an important stimulus for ost

107 medium, the physical property that dictates interstitial fluid flow is the hydraulic permeability.

108 e explants showed that intermediate level of interstitial fluid flow selectively decreased cytokine-i

109 ocity, we used a simple model of peritumoral interstitial fluid flow to calculate the fluid flow velo

110 Interstitial fluid flow within blood clots is a biophysi

111 strong influence on mechanical response and interstitial fluid flow within the matrix.

112 g for blood flow, transcapillary fluid flux, interstitial fluid flow, and lymphatic drainage.

113 Mechanical loading of bone induces interstitial fluid flow, leading to fluid shear stress (

114 including neuropilins (NRPs), which regulate interstitial fluid flow.

115 is provides a link between gel mechanics and interstitial fluid flow.

116 creted by maternal intestinal cells into the interstitial fluid for transport of heme to extraintesti

117 Importantly, the interstitial fluid forms part of the microenvironment th

118 TIONALE: Lymphatic vessels function to drain interstitial fluid from a variety of tissues.

119 from arteries and veins that serves to drain interstitial fluid from surrounding tissues and plays a

120 pothesized to represent impaired drainage of interstitial fluid from the brain and may reflect underl

121 he blood vascular network and that it drains interstitial fluid from the brain.

122 individual microneedle shafts melted away by interstitial fluid from the epidermis and upper dermis,

123 egrated Lab-on-PCB wearable patch extracting interstitial fluid from the patient via integrated micro

124 ree of polymer cross-linking, and to collect interstitial fluid from the skin of rats.

125 pen flow microperfusion technique to extract interstitial fluid from the subcutaneous tissue.

126 function of the lymphatic system is to drain interstitial fluid from tissue.

127 m is the preferred route for the drainage of interstitial fluid from tissues and also serves as a con

128 Since the interstitial fluid glucose level is representative of th

129 range and limit of detection compatible with interstitial fluid glucose levels of diabetic patients a

130 under continuous flow proved compatible with interstitial fluid glucose levels of diabetic patients.

131 ockdown produced profound suppression of VMH interstitial fluid glutamine concentrations in the basal

132 t with insulin sensitization, adipose tissue interstitial fluid glycerol concentrations fell under hy

133 nsulinemia failed to suppress adipose tissue interstitial fluid glycerol release (180 +/- 50 micromol

134 Interstitial fluid has long been considered to be unaffe

135 tic vasculature is essential for maintaining interstitial fluid homeostasis, and dysfunctional lympha

136 minimally invasive glucose monitoring in the interstitial fluid in the dermal region, in contrast to

137 Whereas the relatively minor role of free interstitial fluid in the fluid mechanics and perfusion

138 ) often corresponds with the accumulation of interstitial fluid in the retina [i.e., the development

139 trated ascending vasa recta (AVRs) drain the interstitial fluid in this location, but this function h

140 the sensors in whole blood, saliva, urine or interstitial fluids in detail.

141 mg), cortisol concentrations within adipose interstitial fluid increased (4.3 +/- 1.1 vs. 14.2 +/- 2

142 In turn, convective fluxes of interstitial fluid increased the rate of beta-amyloid cl

143 The amount of interstitial fluid, indicated by the wet-to-dry ratio, i

144 used into the epidermis in a day against the interstitial fluid influx.

145 Lymphatic vessels in meninges drain interstitial fluid into the deep-cervical lymph nodes.

146 acinar cells, to drive transcellular flux of interstitial fluid into the labyrinth of the salivary du

147 mal potentiometric detection of potassium in interstitial fluid is presented here.

148 tivated by NMDA receptors and regulate brain interstitial fluid (ISF) Abeta levels in opposite direct

149 In mice, brain interstitial fluid (ISF) Abeta levels were decreased by

150 Extracellular, interstitial fluid (ISF) Abeta levels were measured in t

151 vity regulates the regional concentration of interstitial fluid (ISF) Abeta, which drives local Abeta

152 f this study, catecholamines from myocardial interstitial fluid (ISF) and aortic and coronary sinus p

153 ellular space by convective exchange between interstitial fluid (ISF) and cerebrospinal fluid (CSF) a

154 The sleep-wake cycle regulates interstitial fluid (ISF) and cerebrospinal fluid (CSF) l

155 cellular tau from various sources, including interstitial fluid (ISF) and CSF from an AD transgenic m

156 ation increases levels of tau in mouse brain interstitial fluid (ISF) and human cerebrospinal fluid (

157 ogical insulin clamp significantly increased interstitial fluid (ISF) and plasma Abeta compared with

158 within the brain is an important pathway for interstitial fluid (ISF) and solute transport.

159 ent did not suppress Ang II levels in the LV interstitial fluid (ISF) despite marked inhibition of AC

160 ess, but also body posture, might affect CSF-interstitial fluid (ISF) exchange efficiency.

161 ar pathway for cerebrospinal fluid (CSF) and interstitial fluid (ISF) exchange that facilitates effic

162 vascular pathway for cerebrospinal (CSF) and interstitial fluid (ISF) exchange.

163 The physiological lag between blood and interstitial fluid (ISF) glucose is a major challenge fo

164 The accuracy of continuous interstitial fluid (ISF) glucose sensing is an essential

165 D uses an osmotic gradient to withdraw brain interstitial fluid (ISF) in a controlled manner via an i

166 curacy real-time measurement of glycaemia in interstitial fluid (ISF) is reported.

167 hat is likely responsive to changes in brain interstitial fluid (ISF) levels of Abeta.

168 aracterized soluble Abeta oligomers in brain interstitial fluid (ISF) of awake, freely moving APP/PS1

169 erebral microdialysis to obtain serial brain interstitial fluid (ISF) samples in 18 patients who were

170 t a novel method of quickly acquiring dermal interstitial fluid (ISF) samples using a Lorentz-force a

171 (NE) and epinephrine (Epi) into the cardiac interstitial fluid (ISF) space in experimentally induced

172 function significantly reduced the levels of interstitial fluid (ISF) tau in PS19 mice expressing P30

173 om the adjacent subarachnoid space and brain interstitial fluid (ISF) via the glymphatic system.

174 duced by neurons and released into the brain interstitial fluid (ISF), a process regulated by synapti

175 le Abeta levels and Abeta half-life in brain interstitial fluid (ISF), as measured by in vivo microdi

176 Abeta is released by neurons into the brain interstitial fluid (ISF), in which it can convert into t

177 ther tau is normally released into the brain interstitial fluid (ISF), its concentration in ISF in re

178 in 4 (AQP4) facilitated exchange of CSF with interstitial fluid (ISF), may provide a clearance pathwa

179 n vivo monitoring of glucose directly in the interstitial fluid (ISF), the continuous monitoring of k

180 o, we used microdialysis to sample the brain interstitial fluid (ISF), which contains the most solubl

181 glucose, and lactate within the hippocampal interstitial fluid (ISF).

182 ntents between cerebrospinal fluid (CSF) and interstitial fluid (ISF).

183 in blood and 11.9 +/- 1.5 mM in subcutaneous interstitial fluid (ISF).

184 rdens and soluble Abeta in brain lysates and interstitial fluid (ISF).

185 beta is subsequently released into the brain interstitial fluid (ISF).

186 sampling, representative of skeletal muscle interstitial fluid (ISF).

187 continuous sensing of lactate in the dermal interstitial fluid (ISF).

188 rfusion by the cerebrospinal fluid (CSF) and interstitial fluid (ISF).

189 The magnesium particles react with the interstitial fluid, leading to an explosive-like rapid p

190 .0001, and P<0.0001, respectively) and renal interstitial fluid levels of AT(2)R downstream signaling

191 ishes proliferative properties of myocardial interstitial fluid (MIF) by enhancing expression of matr

192 asurements were made in myocardial tissue or interstitial fluid (MIF) from dogs undergoing repetitive

193 by altering the chemical composition of the interstitial fluid near the surface of the aggregate.

194 Further, by comparing interstitial fluid nutrient levels between autochthonous

195 nged the half-life of soluble Abeta in brain interstitial fluid of awake animals, 3) raised the conce

196 etabolism of sAbeta by astrocytes and in the interstitial fluid of mice that received apoE infusions

197 e glucose concentration was monitored in the interstitial fluid of six separate rats.

198 ical hyperinsulinemia on the response of the interstitial fluid of skeletal muscle to intravenously i

199 from postmortem cortical extracts and brain interstitial fluid of tau-transgenic mice, as well as hu

200 sing substances either into the blood or the interstitial fluid of the brain.

201 showed that T0 decreased Abeta levels in the interstitial fluid of the hippocampus, supporting the co

202 ain and spinal cord, where it exchanges with interstitial fluid of the parenchyma.

203 lexes (sIL-15 complexes) are abundant in the interstitial fluid of tumors with expression preceding t

204 oncentrations found in the cerebrospinal and interstitial fluids of the human brain, and the mechanis

205 drogen peroxide formation selectively within interstitial fluids of tumors but not in blood.

206 Abeta oligomers were sequestered from brain interstitial fluid onto brain membranes much more rapidl

207 diffusion coefficient of tranexamic acid in interstitial fluid (plasma).

208 ghts a surprising and unrecognized role that interstitial fluid plays in setting the discharge rate,

209 lect the ability of ponezumab to mobilize an interstitial fluid pool of amyloid-beta40 in brain.

210 We assessed interstitial fluid pressure (IFP) and tissue biopsies be

211 has been hypothesized that tumors with high interstitial fluid pressure (IFP) and/or hypoxia respond

212 draining lymphatic vasculature and decrease interstitial fluid pressure (IFP) by reducing vascular p

213 total tissue pressure (TTP) increasing above interstitial fluid pressure (IFP) directly with collagen

214 s can decrease tumor vessel permeability and interstitial fluid pressure (IFP) in a process of vessel

215 High interstitial fluid pressure (IFP) in colorectal cancer m

216 low of interstitial fluid and the associated interstitial fluid pressure (IFP) in solid tumors and su

217 Elevated interstitial fluid pressure (IFP) in tumors can cause me

218 Interstitial fluid pressure (IFP) is elevated in tumors

219 t drug delivery is complicated by high tumor interstitial fluid pressure (IFP), irregular vascular di

220 l interstitial fluid flow and the associated interstitial fluid pressure (IFP).

221 d rodent solid tumors often exhibit elevated interstitial fluid pressure (IFP).

222 71 with the stromal PDGFr-beta reduced tumor interstitial fluid pressure (P(IF)) by >50% and in so do

223 Bevacizumab decreased tumor interstitial fluid pressure and blood flow.

224 DC101 significantly decreased the interstitial fluid pressure and did not change the funct

225 Elevated interstitial fluid pressure and solid stress within tumo

226 ion, vascular volume, microvascular density, interstitial fluid pressure and the number of viable, ci

227 of both freely mobile fluid and gel fluid to interstitial fluid pressure by performing simultaneous,

228 Elevated interstitial fluid pressure can present a substantial ba

229 and that therapies should seek to develop an interstitial fluid pressure gradient.

230 mph nodes by controlling edema formation and interstitial fluid pressure in the presence of LPS.

231 th Starling's hypothesis relating the higher interstitial fluid pressure in the tumor with flux acros

232 vessels through normalization decreases the interstitial fluid pressure in tumours, thus allowing sm

233 This can increase the interstitial fluid pressure inside tumours and reduce bl

234 to literature, we show that reducing tumour interstitial fluid pressure is not essential to increase

235 Fibroids had an average elevated interstitial fluid pressure of 4mmHg compared to -1mmHg

236 polymerase eta-deficient mice and found that interstitial fluid pressure was already elevated in the

237 A reduction in interstitial fluid pressure was also observed.

238 ed using Evans blue dye as the infusate, and interstitial fluid pressure was measured.

239 y 2.5-fold (immunohistochemistry), and tumor interstitial fluid pressure was suppressed by approximat

240 ses (compression and tension), (ii) elevated interstitial fluid pressure, (iii) altered material prop

241 Elevated interstitial fluid pressure, a hallmark of solid tumors,

242 ted that PDGFR-beta inhibition reduces tumor interstitial fluid pressure, and thus increases the upta

243 s, such as oxygen availability, changing pH, interstitial fluid pressure, and tissue stiffness.

244 ve been studied including cut-off pore size, interstitial fluid pressure, and tumor tissue microstruc

245 wn to exhibit high vascular permeability and interstitial fluid pressure, but the transport pathways

246 o transport in these fibroids is likely high interstitial fluid pressure, correlating with high colla

247 the tumor reduces its compact structure and interstitial fluid pressure, increases blood perfusion,

248 ascular permeability without effecting tumor interstitial fluid pressure, leading to increased delive

249 DC101 (a VEGF-receptor-2 antibody) decreases interstitial fluid pressure, not by restoring lymphatic

250 d; increased diffusional distances, elevated interstitial fluid pressure, regions of dense extracellu

251 Compression of lymphatic vessels elevates interstitial fluid pressure, whereas compression of bloo

252 Solid tumors are characterized by high interstitial fluid pressure, which drives fluid efflux f

253 nvironment-characterized by hypoxia and high interstitial fluid pressure--fuels tumor progression and

254 lature characteristics, collagen levels, and interstitial fluid pressure.

255 reduced lymph flow velocities and increased interstitial fluid pressure.

256 plastic reaction generates inordinately high interstitial fluid pressures (IFPs), exceeding those pre

257 The relationship between interstitial fluid pressurization and ECM remodeling in

258 suggested that condylar cartilage relies on interstitial fluid pressurization to a greater extent th

259 ce of soluble Abeta40 and Abeta42 from brain interstitial fluid prior to Abeta deposition.

260 s an increase in chymase activity in cardiac interstitial fluid, providing an alternate pathway for A

261 tercurrent exchange and efficient removal of interstitial fluid resorbed from the loop of Henle and c

262 measurement of analytes in biofluids such as interstitial fluid, saliva, tears and sweat.

263 system to the blood vasculature that returns interstitial fluid, salts, small molecules, resorbed fat

264 a metabolomic comparison of the bone marrow interstitial fluid samples from leukemia patients before

265 sharp gradient of S1P between blood and the interstitial fluids seems to be essential to ensure the

266 Pgp inhibitor, Abeta levels within the brain interstitial fluid significantly increased within hours

267 Lymphatic vessels transport interstitial fluid, soluble Ag, and immune cells from pe

268 influx from the perivascular spaces into the interstitial fluid space rapidly transport solutes and c

269 uch as amyloid-beta peptide (Abeta) from the interstitial-fluid space of the brain to the bloodstream

270 rocyte injury, microcirculatory disease, and interstitial fluid stasis.

271 pond to potential interferences found in the interstitial fluid, such as fructose, vitamin C and lact

272 deep substance of the brain, mixes with the interstitial fluid surrounding neurons and glia, and pla

273 rocess in which serotonin accumulates in the interstitial fluid surrounding the mammary secretory epi

274 and efficiently sample fluids such as sweat, interstitial fluids, tear and saliva for the electrochem

275 Prenodal lymph is generated from the interstitial fluid that surrounds organs, and thus conta

276 ould result in an accumulation of ATP in the interstitial fluid that would be related with a rise in

277 ions of >118 metabolites in plasma and tumor interstitial fluid, the extracellular fluid that perfuse

278 It has been proposed that flow of interstitial fluid through the brain's interstitial spac

279 barrier and dissolve upon contact with skin interstitial fluid thus releasing the nanoparticles into

280 The tumor interstitial fluid (TIF) encompasses the secretome and h

281 ure regulates fluid homeostasis by returning interstitial fluid to blood circulation.

282 ulsion between NPs when the dimers move from interstitial fluid to cytosol.

283 ept that neurons continuously acquire C from interstitial fluid to permit plasma membrane turnover an

284 efficiently simulate vascular blood flow and interstitial fluid transport in silico for validation ag

285 or immune surveillance and the regulation of interstitial fluid transport in the endocrine pancreas a

286 ness, to quantify and understand the role of interstitial fluid transport, lymphatic-convective drain

287 ls, combined with proteomic information from interstitial fluid, unraveling novel inflammatory player

288 irm the possibility of monitoring lithium in interstitial fluid using a wearable sensor.

289 monitoring of glucose concentrations in the interstitial fluid using near IR as the interrogating me

290 but little is known about how tumor IFP and interstitial fluid velocity (IFV) are affected by change

291 permeability was calculated by measuring the interstitial fluid velocity through the clots at a const

292 and a fast pulse, that is, traveling at the interstitial fluid velocity, or only a retarded shock.

293 interstitial exclusion, is of importance for interstitial fluid volume regulation.

294 endothelial area, microvascular volume, and interstitial fluid volume.

295 Lymphatic vasculature drains interstitial fluids, which contain the tissue's waste pr

296 e hyperaemia of substances released into the interstitial fluid, with emphasis on whether they are en

297 to known interfering species present in the interstitial fluid, with resolution and sensitivity (1.5

298 y, are appropriate for potassium analysis in interstitial fluid within both clinical and harmful leve

299 ference-free ethanol detection in artificial interstitial fluid without compromising its sensitivity,

300 e heart, and relieves congestion by clearing interstitial fluid without excessively reducing blood vo