Distinct NF-kappaB regulation by shear stress through Ras-dependent IkappaBalpha oscillations: real-time analysis of flow-mediated activation in live cells.Exploring hypotheses of the actions of TGF-beta1 in epidermal wound healing using a 3D computational multiscale model of the human epidermisDevelopment of a three dimensional multiscale computational model of the human epidermis.A comparison of imaging methodologies for 3D tissue engineering.Enabling multiscale modeling in systems medicine.Data processing techniques for serial EIT spectroscopy images: a review of some preliminary results.A two-dimensional Kolmorogov-Smirnov test for binned data.Computational modeling of epithelial tissues.An integrated systems biology approach to understanding the rules of keratinocyte colony formation.Evaluating the use of optical coherence tomography for the detection of epithelial cancers in vitro.Multi-scale computational models of the airways to unravel the pathophysiological mechanisms in asthma and chronic obstructive pulmonary disease (AirPROM).Modeling the effect of exogenous calcium on keratinocyte and HaCat cell proliferation and differentiation using an agent-based computational paradigm.Agent-based computational modeling of wounded epithelial cell monolayers.Skin stem cell hypotheses and long term clone survival--explored using agent-based modellingRecording Doppler blood flow signals on magnetic tape.NIK and IKKbeta interdependence in NF-kappaB signalling--flux analysis of regulation through metabolites.Anorectal function in patients with complete spinal transection before and after sacral posterior rhizotomy.Three-dimensional electrical impedance tomography.Neonatal lungs--can absolute lung resistivity be determined non-invasively?Study of the optimum level of electrode placement for the evaluation of absolute lung resistivity with the Mk3.5 EIT system.Electrical bioimpedance readings increase with higher pressure applied to the measuring probe.Detection of emboli in vessels using electrical impedance measurements--phantom and electrodes.An integrated agent-mathematical model of the effect of intercellular signalling via the epidermal growth factor receptor on cell proliferation.Formal agent-based modelling of intracellular chemical interactions.The epitheliome: agent-based modelling of the social behaviour of cells.Cole equation modelling to measurements made using an impulse driven transfer impedance system.Low frequency electrical bioimpedance for the detection of inflammation and dysplasia in Barrett's oesophagus.A simulator for testing blood pressure monitoring systemsContinuous 24 hour ambulatory monitoring of intragastric pH in manDetecting oesophageal-related changes using electrical impedance tomographyIdentifying oesophageal contents using electrical impedance tomographyTiming of pyloric closure in man. Studies with impedance electrodesParametric modelling for electrical impedance spectroscopy systemDetermination of the relationship between the pH and conductivity of gastric juiceUse of autoregressive-modelling techniques for the analysis of colonic myoelectrical activity in manMulti-frequency imaging and modelling of respiratory related electrical impedance changesTransport of gastric contentsCan electrical impedance tomography be used to detect gastro-oesophageal reflux?Reproducibility of electrical impedance tomographic spectroscopy (EITS) parametric images of neonatal lungsA comparison of neonatal and adult lung impedances derived from EIT images
P50
Q33212299-6DED0A6F-DA89-4B58-BC4B-F866564F7FABQ33521712-4E7295E4-550E-477F-8ADB-AC661465D43CQ33524410-FB080FCD-044C-470E-B1AE-50D7D2311A98Q33730442-88A8324B-5F77-49E2-BC23-CD67DA8F4131Q33772561-037F3395-1DD8-4AE0-989C-6078B36361FBQ36787055-ED899955-A322-4F5F-85A6-3B81EF884939Q36805392-CB79E848-78B0-477B-A0A7-3BBE2BF307EAQ37787946-00BAD67E-9EFF-402F-8397-7C48ACFE2FD5Q38621155-34549748-E6BF-4B06-96A1-CB0F8EEE5A9FQ39438150-C4462549-AE42-44C4-921A-E4537450C704Q40185991-F0FD120F-3A54-4E2E-8FAC-3DAC65C53158Q40233025-0A6BDE30-4043-4528-BCFA-1CFFD81B9856Q40506409-55582CBA-CF76-43DE-A1D6-491C298A3F7AQ41079037-E0F88267-879D-4373-AEFB-2E826C89E937Q42028951-59EA9FB7-304D-4355-8D8F-C05269913733Q43243394-AE86669F-A0DB-4CAC-A3C0-AC3136ECE89EQ43326514-92E6DBF0-D87E-4793-9D09-3AC215AF62CEQ49010680-24335706-694C-494A-95B2-02EA8A8F4611Q50108224-6414B96D-5D34-4337-889B-97A6F7711BC2Q51219350-FCBE401F-9D9F-43E1-BEBA-4917109DACEAQ51516985-B0A5C30F-1F6F-4292-A136-6D6C1736CEA4Q51517107-0BA6800D-AD58-4201-B1B7-18AF59667A3CQ51940143-FF40A78C-81C4-4EA3-B3AA-D29336502F58Q51944802-F937DC0F-0C69-4C6B-8294-A7DA373F3DA5Q51990377-6950D19B-6BAA-4238-B961-517ADE82FED5Q52080954-4ACF81B6-9886-4F4B-B1A5-4B6578A09C73Q52551012-430FE968-C7A3-4099-B591-FC812F713108Q66944695-AE68714F-7154-41E0-974C-6A5B2A638441Q69055531-EEA162BB-0CDA-4FB5-A60D-82C8CC277713Q70803003-A3DAC553-F18C-407E-AF2F-063ED43BCF36Q70996926-0C8CBA88-2AC3-4B69-8E7F-F8A70CB7D4B3Q71141600-3D2A972B-1D63-4002-95B3-BB4CD42E112EQ71330862-59591114-2BA1-4209-A879-9E6B818B3CC2Q71362859-B4FBFD8E-7E4A-4BEA-AD29-729BFBB3A502Q71486972-BE7904A9-0FB6-4FA1-989B-18941E6D2E15Q72191072-B73D7E5A-2255-4262-B30A-7164644F01ADQ72191096-826EB451-94C9-4100-B25B-A0DC9D244429Q72992311-0A119817-9D60-43B6-BA3F-D07F01B17812Q72992342-45BDE626-8E04-455B-823A-66167689510EQ73261529-09B3A866-6F38-4211-933A-65BC701D4BF7
P50
description
medical engineer
@en
onderzoeker
@nl
name
Rod Smallwood
@ast
Rod Smallwood
@en
Rod Smallwood
@es
Rod Smallwood
@fr
Rod Smallwood
@nl
type
label
Rod Smallwood
@ast
Rod Smallwood
@en
Rod Smallwood
@es
Rod Smallwood
@fr
Rod Smallwood
@nl
altLabel
R H Smallwood
@en
R Smallwood
@en
Rodney H. Smallwood
@en
Rodney Harris Smallwood
@en
Rodney Smallwood
@en
prefLabel
Rod Smallwood
@ast
Rod Smallwood
@en
Rod Smallwood
@es
Rod Smallwood
@fr
Rod Smallwood
@nl
P166
P1006
P1015
P214
P244
P1006
P1015
P106
P1153
55406004400
P1477
Rodney Harris Smallwood
@en-gb
P166
P1960
3GHX4JsAAAAJ
P21
P213
0000 0000 6740 852X
P214
P244
P271
DA02902868
P31
P3885
rod-smallwood
P409
P496
0000-0003-0134-0632