If the molecule was expected to be more like a branched polysaccharide, the 8nm would correspond to an estimated 207kDa. The swelling behavior of the nanogels at different glucose concentrations revealed definite glucose sensitivity of P(NIPAM-Dex-PBA) particles. Dynamic light scattering (DLS) was performed to investigate the hydrodynamic radius of the dextran carriers ( Figure 1 A ). FITC-dextran (MW=2000kDa) and bovine serum albumin (BSA) were obtained from Sigma-Aldrich (St. Louis, MO, USA). Journal of Polymer and Biopolymer Physics Chemistry. Media viscosity was doubled by the addition of 1.5% wt/vol dextran, and the effect of increasing media viscosity on isolated platelets at 10 10 6 cells/mL was examined at 9600/s after 30 seconds of shear. While the diffusivity of FITC-dextrans in hydrogels decreased with increasing solute size, the diffusivity of FITC-PEGs increased with increasing solute size, suggesting that a generalized hydrodynamic radius-based model is not universally applicable for solute diffusion in hydrogels. For example, small changes in the length of a rod-shaped particle 25 . The hydrodynamic radius of the dextran carriers was investigated by dynamic light scattering (DLS), and the result is shown in Figure 1 A. Utilizing vesicles containing fluorescently labeled dextran with a vesicle-to-suspended bilayer fusion assay, we can observe the release the release of the dextran through the bilayer as the pore opens and expands beyond the hydrodynamic radius of the dextran. Information on size and conformation is adduced from viscosity, sedimentation and diffusion studies. 66 Figure 4.4 Effective hydrodynamic radius determined by size exclusion chromatography using dextran standards for Serotypes A and B and the protein . Molecular weight, M W Hydrodynamic diameter D h This to some changes in hydrodynamic radius and electrostatic protein is the main protein of plasma with concentration binding of the biomolecule.1 of about 3.5-5.0 g/dL, and supplies 80% of the colloid After PEGylation the hydrodynamic radius of the osmotic pressure of plasma (25-33 mm Hg).9,10 molecule increases which causes reduced renal . We then incubated each formulation with each of seven solutes: fluorescein, three sizes of FITC-dextran, a globular, highly branched polysaccharide (4, 20, 70 kDa), and three sizes of FITC-PEG, a linear synthetic polymer (5, 20, 40 kDa). The hydrodynamic radius R h was calculated according to the Einstein viscosity relation, modeling the . Monosaccharide analysis revealed that the polysaccharide comprised only glucose units. 2 the X-ray scattering intensity, I(q), is plotted against q for the case of dextran T500 in water, formamide, ethanolamine, and their mixtures with 25% ethanol. In the screenshot, the calculator is shown for 8nm radius. Dextran showed considerable hyperpermeability, and even when the ratio of molecular radius (a The Mark-Houwink. To quantitate this effect, we measured the pressure gradient, flow rate, and the radius of the red blood cell core in suspensions flowing through tubes of 172-microns radius at mean linear flow rates (U) from 50 to 0.15 tube diameters.sec-1. This observation led to the realization that adminis- . E . In dilute aqueous buffers, the 10 kDa dextran has a hydrodynamic radius (Rh) of 2.3 nm. Regarding the size of the crowding agents with respect to the size of the 25.5 kDa enzyme -CT of hydrodynamic radius, R H, of 2.45 nm, 10 kDa Dextran has a hydrodynamic radius of about 2.44 nm, and the R H of 5 kDa PEG is of similar size and amounts to 2.29 nm. Boston, MA 02115. Business: (617) 432 - 2000. Hydrodynamic properties of a series of ionic polysaccharides with different charge density but the same molecular weight have been evaluated in salt-free aqueous solution and aqueous/organic solvent mixtures by means of capillary viscometry. S1B) and speed of diffusion in the TATS is reduced. As synovial permeability is dependent on the size of the molecule , , ADA permeates slightly faster across the ex-vivo membrane than the 150 kDa dextran since, despite a comparable MW, it has a reported smaller hydrodynamic radius than the polysaccharide due to its secondary folding . Low molecular weight dextran diffuses relatively fast compared to the higher molecular weight as seen by the higher diffusion coefficients in Table 1. In dilute solution the behavior of DEAEdextran was compared with that of unsubstituted dextran and the molecular weight M dependences of the radius of gyration Rg, hydrodynamic radius Rh, intrinsic viscosity [], second virial coefficient A2 and zaverage diffusion coefficient Dz were determined. In other words, dextran molecules were able to pass through membrane pores with a smaller diameter than the molecule itself. Molecular weight (M. v) and hydrodynamic properties can be calculated from there. The molecular size, expressed as the hydrodynamic radius, was determine with the Stokes-Einstein equation and reported values of the diffusion coefficient . The relationships for DEAEdextran . The radius of dextran (70 kDa) was ~6 nm, and the radius increased to ~9.8 nm after modifications. Using a dextran with a nominal molecular mass of 10 kDa, the hydrodynamic radius of the fluorescent molecule is increased (in accordance with Stoke's law), and t increases proportionally (by 10 kDa / 3 kDa 3 1.5; Fig. At 200 g/L, the occupied dextran volume ratio is calculated to be 4.9, using a hydrodynamic radius of 27 nm, indicating that in water dextran exists as a hydrated and compact structure. Solute Hydrodynamic Radius (r s) The Solute Hydrodynamic Radius . Dead volume of column was calculated by elution volume of dextran-blue which was 5.28 mL. The sizes of dextran molecules in solution can be expressed either as the radius of gyration, R2 , or as the hydrodynamic radius Rh (Stoke's radius). A High concentrations of Ficoll and dextran exhibit a network-like structure. Size-exclusion chromatography (SEC), also known as molecular sieve chromatography, is a chromatographic method in which molecules in solution are separated by their size, and in some cases molecular weight. American journal of physiology. the hydrodynamic radius ( rh) of individual samples of dextran, polyvinylpyrrolidone, and polyoxyethylene over a range of molecular weights (1500-2,000,000) were calculated from their intrinsic viscosities using the einstein viscosity relation and directly measured by quasi-elastic light scattering, and the effect of each polymer sample on rbc . . In Fig. The study of biopolymers as dextran in aqueous solution, is effectively determined by intrinsic viscosity [ ] measurements at different temperatures. 14. 26 The area (A) under this curve is reported to give a quantitative measure of hydrogel permissivity for the range of hydrodynamic radii assayed. The percentage of F-dextran passed through CM, CM-np25, CM-np200, , and as controls; More pronounced effects of ECM digestions were found deeper in tumor tissue. If the shape of a particle changes in a way that affects the diffusion speed, then the hydrodynamic size will change. 3. In experimental systems with such porous membranes, the agreement between data and theory was poor for dextran, whereas it was much better for Ficoll. 1991), Dextran-40 and Dextran-70 with hydrodynamic radius of 44.5 50 and 58 64 , respectively (Granath, 1958; Venturoli & Rippe, 2005). F-Dextran (kDa) 4 10 70 Estimated hydrodynamic radius (nm) 1.08 - 1.71 1.59 - 2.41 3.66 - 7.04 Fig S1. To quantitate this effect, we measured the pressure gradient, flow rate, and the radius of the red blood cell core in suspensions flowing through tubes of 172-microns radius at mean linear flow rates (U) from 50 to 0.15 tube diameters.sec-1. First, we introduce our model and method, including the nonuniform concentration The polyelectrolytes investigated contain quaternary ammonium salt groups, N-ethyl-N,N-dimethyl-2-hydroxypropylammonium chloride, attached to a dextran . Minimally Invasive Transdermal Delivery of Iron-Dextran ABHISHEK JULURI,1 NARESH MODEPALLI,1 SEONGBONG JO,1 MICHAEL A. REPKA,1 H. NANJAPPA SHIVAKUMAR,2,3 S. NARASIMHA MURTHY1 . The data are plotted as a function of the inverse of the Stokes (hydrodynamic) radius R H of the dextrans considered rather than their molecular weight. Ficoll and dextran molecules have different molecular shapes in solution, so that the hydrodynamic radius of the molecules are different at similar molecular weight. The solutions were assumed to be dilute enough to ensure . At room temperature, MION exhibit superparamagnetic behavior with an . (Fig. 41 Although FITC-dextran 150 kDa has the same MW, it has a radius of 85 due to its linear structure. Fig 9 shows the dependence of diffusion rate on dextran size and polymerization temperature (tabulated data, including concentration and pH dependence, can be found in S4 Table). Fig. CROUGHAN, SAYRE, AND WANG: VISCOUS REDUCTION OF TURBULENT DAMAGE IN ANIMAL CELL CULTURE 865 f zyx Because there was no hydrodynamic damage and no mass transport limitations, the effects of dextran supple- mentation were solely chemical and not physical. 42 Comparing both compounds, the permeation of Avastin across porcine skin in vitro, was approximately two-fold greater than FITC-dextran 150 kDa. The hydrodynamic radius of 2-NBDG glucose was too small to measure. In dilute solution the behavior of DEAEdextran was compared with that of unsubstituted dextran and the molecular weight M dependences of the radius of gyration R g, hydrodynamic radius R h, intrinsic viscosity [], second virial coefficient A 2 and zaverage diffusion coefficient D z were determined. Student Computing within the HMS IT Department provides technical support for the HMS Quad network and the online email client, Outlook Web Access, and maintains student workstations for HMS/HSDM/DMS pre-doctoral students. used to separate molecules on the basis of size and shape (hydrodynamic radius). There is a formula that used to calculate the radius (in Angstrom) from the molar mass (in g/mol) of dextran, a=0.33* (MM^0.46) where, a and MM are radius and molar mass, respectively. B, C The proteins BSA and lysozyme can be described as hard sphere systems with BSA (B) having a larger hydrodynamic radius than lysozyme (C), leading to differences in the dimensions of void volume. The study of biopolymers as dextran in aqueous solution, is effectively determined by intrinsic viscosity [] measurements at different temperatures. Collagenase and cathepsin C increased diffusion . Here, the estimate for the molecular weight of a molecule similar to a linear polysaccharide would be expected to be 88kDa. Dextran showed considerable hyperpermeability, and even when the ratio of molecular radius ( ae) to pore radius ( rp) ( ae / rp) approached unity, dextran was able to pass through the membrane ( 7 ). For A = 1 equation describes the theoretically expected form of the partition ratios of spherical, non-interacting molecules in a network of randomly oriented planes [].In this case the factor s represents the mean surface area of the network . It is usually applied to large molecules or macromolecular complexes such as proteins and industrial polymers. Z-average hydrodynamic radius (R H) was estimated using the Stokes-Einstein Equation (2), where D 0 is the diffusion coefficient of the nano-objects determined from the slope of the q 2 dependence of relaxation rate (<> = Dq 2), k B is the Boltzmann constant, T is the absolute temperature and s is the viscosity of the solvent (water). GpIb blocking antibody AN-51 reduced platelet . Dynamic light scattering (DLS) was performed to investigate the hydrodynamic radius of the dextran carriers (Figure Figure11A). This is much smaller than the hydrodynamic radius of either dextran coil (r s = 14 or 27 nm) and does not greatly exceed the persistence lengths (l p = 1.8 or 1.5 nm). Chemical analysis showed that each core has 25 +/- 6 dextran molecules (10 kD) attached, resulting in a unimodal hydrodynamic radius of 20 nm by laser light scattering. . This diffusivity was then converted to estimate the hydrodynamic radius (R h). Dextran is a branched polysaccharide, composed of -D-glucopyranosyl residues. All samples were prepared in calcium and magnesium free phosphate buffered saline (PBS). dextran reduced RBC aggregation and low-shear viscosity after infusion into experimental animals or hospitalized patients (Thorsen and Hint, 1950; Bergan et al., 1965; Hint, 1969). 56 The linkage that the enzyme dextranase breaks down is indicated by the black arrow. Our results indicate that the behavior of biological molecules under conditions of molecular crowding is not always Measurement of Hydrodynamic Radius of ID Particle size (hydrodynamic radius) of the ID col-loid was measured by dynamic light scattering (DLS) Molecular weight (M v ) and hydrodynamic properties can be calculated from there. and the drug release was dependent on the composition of dextran . The radius of dextran (70 kDa) was ~6 nm, and the radius increased to ~9.8 nm after modifications. Do large pores in the glomerular capillary wall account for albuminuria in nephrotic states? The molecular data collected for the dextran samples, including the molecular weight moments (M n, M w, and M z), hydrodynamic radius (R h) , intrinsic viscosity ([]) , are summarized in Table 1, corroborating the trend illustrated in Figure 2. 1. The hydrodynamic 57 radius of the dextranase is 7 nm. Size exclusion chromatography is called gel filtration chromatography because the gel essentially allows for the filtering of molecules from a sample based upon molecular size. Dynamic light scattering study confirmed the mono-disperse nature of dextran with hydrodynamic radius of 900 nm. This result was also confirmed by transmission electronic microscopy (TEM) ( Figure 1 B) that identified a diameter of ~20 nm. FRAP experiments on each combination . The data in Figure 2 therefore illustrate the chemical effects of dextran on cell growth. However, a similar analysis applied to the measured . The hydrodynamic radius (Rh) of individual samples of dextran, polyvinylpyrrolidone, and polyoxyethylene over a range of molecular weights (1,500-2,000,000) were calculated from their intrinsic viscosities using the Einstein viscosity relation and directly measured by quasi-elastic light scattering, and the effect of each polymer sample on RBC . Hydrodynamic volume, radius of gyration, and viscometric constants, K and a, for dextran, with a wide molecular weight range were calculated using experimental reported average-molecular weights (M, Mw), and intrinsic viscosity, [], data in water and 0.05M NaSO. Summary: This study demonstrates that there is only small conformational dependence for the fractional clearance, as studied in the isolated perfused kidney, of random coil dextran as compared to the spherical Ficoll when these probes are standardized on the basis of effective hydrodynamic radii by gel exclusion chrotography. The Mark-Houwink parameters indicate the dependence with temperature (T) in the range from 20 to The hydrodynamic diameter of a non-spherical particle is the diameter of a sphere that has the same translational diffusion speed as the particle. The paper is organized as follows. and the hydrodynamic results showed that the macroporous chitin microspheres has a higher permeability of (4.290.34) . Dextran behaves as a random coil in water and formamide solutions on the basis of the Mark-Houwink-Sakurada constant being in the range 0.5< < 0.8 and the molecular weight dependence of the hydrodynamic coil radius, Rcoil MW1/2. The dependence of the tumor's apparent permeability on the molecular size of the dextran, expressed as the hydrodynamic radius, is shown in Fig. . Data fits using the random coil form factor P() are also . However, unlike other techniques, the larger molecules elute first. The hydrodynamic radius of the FITC-dextran tracer was determined using dynamic light scattering to be 19.50 1.29 nm (mean SEM, n = 3), which is in good accordance with reported values . hydrodynamic radius, among other parameters for characterizing the physics and chemistry properties of dextran in solution. 54 we estimated that the hydrodynamic radii of 3-5 kDa dextran, 20 kDa dextran, and 70 kDa dextran are 2 55 nm, 5 nm, and 6 nm, respectively. Labeled dextrans are hydrophilic polysaccharides most commonly used in microscopy studies to monitor cell division, track the movement of live cells, and to report the hydrodynamic properties of the cytoplasmic matrix. conventional hydrodynamic pore models for diffusion of hard spheres in cylindrical tubes (7). A few percent . Dynamic light scattering (DLS) was performed to investigate the hydrodynamic radius of the dextran carriers (Figure 1A). FITC-dextran, 10 kDa and 70 kDa, were purified using a gel filtration . Molecular weight (Mv) and hydrodynamic properties can be calculated from there. 2 nanoparticles can be delivered to a Authors have also found that under the process condition described s above 50 nm SiO. Dextran consists of -D glucose units with a majority of (16) glucosidic linkages between them. 1)[5]. These two parameters differ significantly as shown in table 1 below. The plot is fitted linearly (adjusted R2 = 0.99909), in agreement with the predicted power relationship of the hydrodynamic radius, R h, with the number of monomers, N, in a polymer chain, R h N-.1 The exponent, , is determined by the polymer and the solvent. The Mark-Houwink parameters indicate the dependence with temperature (T) in the range from 20 to 50C, ie with increasing T a increases and kM-H decreases. By plugging this value of Rh and the measured diffusion coefficient into the Stokes-Einstein equation, [they] obtain an apparent viscosity value that is comparable to those of the other small probes. The radius of dextran (70 kDa) was ~6 nm, and the radius increased to ~9.8 nm after modifications. This result was also confirmed by transmission electronic microscopy (TEM) (Figure 1B) that identified a diameter of ~20 nm . where r h represents the hydrodynamic radius of the test molecules, r f the cross-sectional fiber radius of the PEG chains and A is a numeric factor. The size of the molecular aggregates was determined by converting the light scattering signal into a hydrodynamic radius using the Stokes-Einstein equation . All samples were prepared in . by Julijana Vuchkova, Maria Koltun, Kerryn Greive, Wayne D Comper. Dextran consists of -D glucose units with a majority of (16) glucosidic linkages between them. Typically, when an aqueous solution is used to transport the sample through . Some parts of dextran might take on an entangled and overlapped conformation. The radius of natural dextran (70 kDa) Nanomaterials 2016, 6, 34 3 of 8 was around 6 nm, and the radius increased to around 9.95 nm (intensity-based distributions) after Washed red blood cells were suspended in 1.5% buffered dextran 110 at hematocrits of 34-52%. For larger macromolecules, collagen digestion increased by ~2-fold the diffusion of albumin and 500 kDa FITC-dextran (hydrodynamic radius ~ 30 nm) at a depth of 0.5 mm, and increased the percentage fluorescence recovery . 260 Longwood Avenue, TMEC Room 158. delivery of large dextran molecules: i)10 kDa in size (8 nm hydrodynamic radius) to a depth of 600 m and 70 ii) kDa in size (49 nm hydrodynamic radius) up to a depth of 150 m within one hour (data not shown). The hydrodynamic radius of the dextran carriers was investigated by dynamic light scattering (DLS), and the result is shown in Figure1A. . 17 The viscosity of the aqueous dextran solutions decreased with temperature, and the activation energy was calculated to be 16,849.2 J/mol with a 10 wt % dextran (weight-average molecular weight =. ( c ) Zeta potential of 0.1 M dextran coated cerium oxide nanoparticles dispersed in . This suggests that, on the length scale of the agarose fiber spacings, dextran molecules entrapped in 8% gels might resemble straight rods, as in Fig. The nanogels had an average hydrodynamic radius of about 150 nm, and particle size increased with increasing content of dextran. For an estimate of the size of each probe, the hydrodynamic radius was calculated based on the Stokes-Einstein equation (Cussler 2009). The hydrodynamic radii of the functionalized nanoparticles suspended in water measured by dynamic light scattering technique assuming the bulk value for viscosity, were 91, 100, 106, and 132 nm, respectively. Student Computing. The study of biopolymers as dextran in aqueous solution, is effectively determined by intrinsic viscosity [] measurements at different temperatures. R is the radius of ion exchangers, and c is BSA concentration in the bulk . However, in the case of dextran solutions, the protein is likely to possess a higher hydrodynamic radius due to the probable stronger attractive interaction between protein and dextran molecules. The coil radius of gyration, R g, is the main fitting parameter.In addition to R g, a scale factor and a (constant) background term are involved in the data fitting.. Renal physiology. 61-63 Compared to the hydrophilic coil-like polysaccharide dextran, PEG is . By measuring the ac magnetic loss, we determined the effective sizes to be 105, 113, 122, and 136 nm, respectively. The rates of . In this study, we develop a novel method for the study of fusion pore dynamics. This is particularly for molecules with the same effective . of FITC-dextran in PBS buffer. the hydrodynamic radius (rh) of individual samples of dextran, polyvinylpyrrolidone, and polyoxyethylene over a range of molecular weights (1,500-2,000,000) were calculated from their intrinsic viscosities using the einstein viscosity relation and directly measured by quasi-elastic light scattering, and the effect of each polymer sample on rbc 2018).The Stokes radius of iRFP713 in unfolded state is equal to 55 2 (Uversky, 2002). A few percent of R (13) glucosidic linkages provides side chains which appear to be short. HMS IT Department. Although in our experiment no difference was found between . The formation of this layer is known to be accompanied by a decrease in hydrodynamic resistance to flow. The labeled dextran is commonly introduced into the cells via microinjection. Hydrodynamic radius was determined based on the retention time of fractions on size exclusion chromatography (SEC), and also according to the previously reported equations. Figure 4.3 Effective hydrodynamic radius determined by size exclusion chromatography using dextran standards for Serotypes A, B, and C and thyroglobulin as a function of Debye length. The labeled dextran is commonly introduced into the cells via microinjection. The radius of natural dextran (70 kDa) was around 6 nm, and the radius increased to around 9.95 nm (intensity-based distributions) after modifications. The molecular mass of dextran as determined by the gel filtration and copper bicinchoninate method was approximately, 800 kDa. Concentrations were first normalized by dividing values with gel weight, then normalized concentrations were plotted against published values for each molecular weight dextran hydrodynamic radius. MW characterization of HA used in confocal-FRAP studies . Because of the flexibility of the dextran layer, the radius is only 8 nm in nonaqueous reverse micelles. you can see. This is an estimate, and typically this is . K av values were calculated using equation [1]. (b) Hydrodynamic radius of 0.1 M dextran coated cerium oxide nanoparticles dispersed in PBS at pH 6 and pH 9. To provide a model for glomerular filtration of random-coil macromolecules, the equilibrium partitioning of random coils between cylindrical pores and bulk solution was simulated using Monte Carlo calculations, and those results were combined with a hydrodynamic theory for restricted motion of solvent-filled polymer coils in pores. Avastin, a globular protein has a hydrodynamic radius of 46 . Labeled dextrans are hydrophilic polysaccharides most commonly used in microscopy studies to monitor cell division, track the movement of live cells, and to report the hydrodynamic properties of the cytoplasmic matrix. 5 a , which motivates the . hydration of proteins. Read more related scholarly scientific articles and abstracts. The study of biopolymers as dextran in aqueous solution, is effectively determined by . 19-cm column as the stationary phase and water as the mobile phase) to confirm the absence of any free FITC label. Grafting diethylaminoethyl dextran to macroporous cellulose microspheres: A protein anion exchanger of high capacity and fast uptake rate . The hydrodynamic radius of the FITC-dextran tracer was determined using dynamic light scattering to be 19.501.29nm (mean SEM, n=3), which is in good accordance with reported values [18]. The estimated hydrodynamic radius for F-dextran of different mass obtain using the hydrodynamic radius estimator of Zetasizer software.
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