Determination of the size distribution of blood microparticles directly in plasma using atomic force microscopy and microfluidics.

Microparticles, also known as microvesicles, found in blood plasma, urine, and most other body fluids, may serve as valuable biomarkers of diseases such as cardiovascular diseases, systemic inflammatory disease, thrombosis, and cancer. Unfortunately, the detection and quantification of microparticles are hampered by the microscopic size of these particles and their relatively low abundance in blood plasma. The use of a combination of microfluidics and atomic force microscopy to detect microparticles in blood plasma circumvents both problems. In this study, capture of a specific subset of microparticles directly from blood plasma on antibody-coated mica surface is demonstrated. The described method excludes isolation and washing steps to prepare microparticles, improves the detection sensitivity, and yields the size distribution of the captured particles. The majority of the captured particles have a size ranging from 30 to 90 nm, which is in good agreement with prior results obtained with microparticles immediately isolated from fresh plasma. Furthermore, the qualitative shape of the size distribution of microparticles is shown not to be affected by high-speed centrifugation or the use of the microfluidic circuit, demonstrating the relative stable nature of microparticles ex vivo.

Atomic force microscopy: a novel approach to the detection of nanosized blood microparticles.

BACKGROUND: Microparticles (MPs) are small vesicles released from cells of different origin, bearing surface antigens from parental cells. Elevated numbers of blood MPs have been reported in (cardio)vascular disorders and cancer. Most of these MPs are derived from platelets. OBJECTIVES: To investigate whether atomic force microscopy (AFM) can be used to detect platelet-derived MPs and to define their size distribution. METHODS: Blood MPs isolated from seven blood donors and three cancer patients were immobilized on a modified mica surface coated with an antibody against CD41 prior to AFM imaging. AFM was performed in liquid-tapping mode to detect CD41-positive MPs. In parallel, numbers of CD41-positive MPs were measured using flow cytometry. Mouse IgG1 isotype control was used as a negative control. RESULTS: AFM topography measurements of the number of CD41-positive MPs were reproducible (coefficient of variation=16%). Assuming a spherical shape of unbound MPs, the calculated diameter of CD41-positive MPs (dsph) ranged from 10 to 475 nm (mean: 67.5+/-26.5 nm) and from 5 to 204 nm (mean: 51.4+/-14.9 nm) in blood donors and cancer patients, respectively. Numbers of CD41-positive MPs were 1000-fold higher than those measured by flow cytometry (3-702x10(9) L(-1) plasma vs. 11-626x10(6) L(-1) plasma). After filtration of isolated MPs through a 0.22-microm filter, CD41-positive MPs were still detectable in the filtrate by AFM (mean dsph: 37.2+/-11.6 nm), but not by flow cytometry. CONCLUSIONS: AFM provides a novel method for the sensitive detection of defined subsets of MPs in the nanosize range, far below the lower limit of what can be measured by conventional flow cytometry.

Single-molecule recognition imaging microscopy.

Atomic force microscopy is a powerful and widely used imaging technique that can visualize single molecules and follow processes at the single-molecule level both in air and in solution. For maximum usefulness in biological applications, atomic force microscopy needs to be able to identify specific types of molecules in an image, much as fluorescent tags do for optical microscopy. The results presented here demonstrate that the highly specific antibody-antigen interaction can be used to generate single-molecule maps of specific types of molecules in a compositionally complex sample while simultaneously carrying out high-resolution topographic imaging. Because it can identify specific components, the technique can be used to map composition over an image and to detect compositional changes occurring during a process.