Method of imaging low density lipoproteins by atomic force microscopy

Chouinard, Julie A.; Khalil, Abdelouahed; Vermette, Patrick

doi:10.1002/jemt.20492

Cited by 8 publications

(10 citation statements)

References 25 publications

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“…Previous AFM studies have reported the sizes of the whole LDL fraction as 17 nm measured by Legleiter et al 16 and 23 AE 3 nm measured by Chouinard et al 19 The value reported by Legleiter et al 16 is within the range of our AFM measurements of LDL: 16.2 AE 1.4 nm for sd-LDL and 20.6 AE 1.9 nm for large LDL. On the other hand, Chouinard et al 19 just measured the scales of LDL particles without calculations in the topographical images, which would gives larger sizes of LDL particles than those by our analytical procedure.…”

supporting

confidence: 86%

“…On the other hand, Chouinard et al 19 just measured the scales of LDL particles without calculations in the topographical images, which would gives larger sizes of LDL particles than those by our analytical procedure. A previous study that used EM reported LDL particle sizes at 20-27 nm, 27 similar to those measured by EM in this study: 20.4 AE 1.4 nm for sd-LDL and 23.2 AE 1.4 nm for large LDL.…”

mentioning

confidence: 99%

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Measurement of single low-density lipoprotein particles by atomic force microscopy

et al. 2013

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Background: The size of lipoprotein particles is relevant to the risk of coronary artery disease (CAD). Methods: We investigated the feasibility of atomic force microscopy (AFM) for evaluating the size of large low-density lipoprotein (LDL) and small dense LDL (sd-LDL) separated by ultracentrifugation. The measurements by AFM in tapping mode were compared to those by electron microscopy (EM).Results: There was a significant difference in particle sizes determined by AFM between large LDL (20.6 AE 1.9 nm, mean AE SD) and sd-LDL (16.2 AE 1.4 nm) obtained from six healthy volunteers (P < 0.05). The particle sizes determined by EM for the same samples were 23.2 AE 1.4 nm for large LDL and 20.4 AE 1.4 nm for sd-LDL. The difference between large LDL and sd-LDL detected by EM was also statistically significant (P < 0.05). In addition, the particle sizes of each lipoprotein fraction were significantly different between AFM and EM: P < 0.05 for large LDL and P < 0.05 for sd-LDL. Conclusions: AFM can differentiate between sd-LDL and large LDL particles by their size, and might be useful for evaluating risk for CAD.

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confidence: 86%

mentioning

confidence: 99%

Measurement of single low-density lipoprotein particles by atomic force microscopy

et al. 2013

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“…Without the elimination process, the mean sizes were overestimated, which suggests that the larger size often estimated with DLS can be attributed to the existence of large particles such as aggregates. In the LDL particle cases, the mean sizes were 21.7 nm and 23.6 nm for sdLDL and lLDL, respectively, which agreed well with those reported in the literature [24,25]. These results suggest the effectiveness of the data processing technique proposed here.…”

Section: Elimination Of Large Scatterer Effectsupporting

confidence: 90%

Fraction estimation of small, dense LDL using autocorrelation function of dynamic light scattering

Trirongjitmoah¹,

Sakurai²,

Iinaga³

et al. 2010

Opt. Express

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Small, dense low-density lipoprotein (sdLDL) in total LDL is strongly related with the cardiovascular risk level. An optical technique using dynamic light scattering (DLS) measurement is useful for point-ofcare testing of sdLDL. However, the sdLDL fraction estimated from the particle size distribution in DLS data is sensitive to noise and artifacts. Therefore, we derived analytical solutions in a closed form to estimate the fraction of scatterers using the autocorrelation function of scattered light from a polydisperse solution. The effect of the undesired large particles can be eliminated by the pre-processing of the autocorrelation function. The proposed technique was verified using latex standard particles and LDL solutions. Results suggest the feasibility of this technique to estimate the sdLDL fraction using optical scattering measurements.

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“…the thickness of their LDL samples) was measured. In most previous AFM studies [5,[15][16][17], however, the average heights of individual LDL particles deposited on a substrate are generally less than 10 nm (e.g. 8.9 ± 1.9 nm at pH 7.4 in our current study).…”

Section: Effect Of Oxidation On the Stiffness Of Ldl Particlescontrasting

confidence: 58%

Dynamic AFM detection of the oxidation-induced changes in size, stiffness, and stickiness of low-density lipoprotein

Wang

Luo

et al. 2020

J Nanobiotechnol

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Background Low-density lipoprotein (LDL) is an important plasma lipoprotein transporting lipids to peripheral tissues/cells. The oxidation of LDL plays critical roles in atherogenesis and its oxidized form (oxLDL) is an important risk factor of atherosclerosis. The biomechanical properties of LDL/oxLDL are closely correlated with the disease. To date, however, the oxidation-induced changes in size and biomechanical properties (stiffness and stickiness) of LDL particles are less investigated. Methods In this study, copper-induced LDL oxidation was confirmed by detecting electrophoretic mobility, malondialdehyde production, and conjugated diene formation. Then, the topographical and biomechanical mappings of LDL particles before/after and during oxidation were performed by using atomic force microscopy (AFM) and the size and biomechanical forces of particles were measured and quantitatively analyzed. Results Oxidation induced a significant decrease in size and stiffness (Young’s modulus) but a significant increase in stickiness (adhesion force) of LDL particles. The smaller, softer, and stickier characteristics of oxidized LDL (oxLDL) partially explains its pro-atherosclerotic role. Conclusions The data implies that LDL oxidation probably aggravates atherogenesis by changing the size and biomechanical properties of LDL particles. The data may provide important information for a better understanding of LDL/oxLDL and atherosclerosis.

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Method of imaging low density lipoproteins by atomic force microscopy

Cited by 8 publications

References 25 publications

Measurement of single low-density lipoprotein particles by atomic force microscopy

Measurement of single low-density lipoprotein particles by atomic force microscopy

Fraction estimation of small, dense LDL using autocorrelation function of dynamic light scattering

Dynamic AFM detection of the oxidation-induced changes in size, stiffness, and stickiness of low-density lipoprotein

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