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Multimode afm nanoscope 4 system

Manufactured by Veeco
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The MultiMode AFM NanoScope IV system is a laboratory equipment product designed for atomic force microscopy (AFM) applications. It is capable of high-resolution imaging and analysis of surface topography at the nanoscale level. The system provides functionalities for the characterization of various materials and samples.

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Nanoscope IV Multimode AFM Nanoscope IV AFM NanoScope MultiMode Multimode AFM Nanoscope IV

4 protocols using multimode afm nanoscope 4 system

1

AFM Imaging of RNA Samples

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AFM images were taken using a MultiMode AFM NanoScope IV system (Veeco), as per previously reported methods.70 (link) Briefly, the RNA samples were diluted with TMS buffer to a final concentration of 3–5 nM. Then, a droplet of samples (5–10 μL) was immediately deposited on the specifically modified APS mica surface,71 (link),72 (link) excess samples were washed with DEPC-treated water and dried under a flow of argon gas. AFM images in air were acquired using a MultiMode AFM NanoScope IV system (Veeco/Digital Instruments, Santa Barbara, CA, USA) operating in tapping mode.
Jasinski D.L., Khisamutdinov E.F., Lyubchenko Y.L, & Guo P. (2014). Physicochemically Tunable Polyfunctionalized RNA Square Architecture with Fluorogenic and Ribozymatic Properties. ACS Nano, 8(8), 7620-7629.
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2

Atomic Force Microscopy of RNA Nanotubes

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The RNA nanotubes were imaged by AFM, following previously described methods [55 (link)]. Briefly, RNA nanotubes were placed on the APS-modified mica surface and excess samples were washed with DEPC water and dried before imaging. AFM imaging was performed by using the MultiMode AFM NanoScope IV system (Veeco) operated in tapping mode.
Li H., Wang S., Ji Z., Xu C., Shlyakhtenko L.S, & Guo P. (2019). Construction of RNA nanotubes. Nano research, 12(8), 1952-1958.
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3

Imaging RNA Tetragon and Half-Adder Complexes

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The RNA tetragon and RNA half-adder complexes were imaged with MultiMode AFM NanoScope IV system (Veeco Instruments Inc., Plainview, NY, USA), following previous methods [65 (link)].
Goldsworthy V., LaForce G., Abels S, & Khisamutdinov E.F. (2018). Fluorogenic RNA Aptamers: A Nano-platform for Fabrication of Simple and Combinatorial Logic Gates. Nanomaterials, 8(12), 984.
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4

Purifying and Imaging Nucleic Acid Polygons

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The samples of each RNA and DNA polygons were purified using gel electrophoresis prior to imaging. The assembled DNA and RNA polygons (2 μM concentration of each strand, in 50 μL TMS buffer) were subjected to the 6% native PAGE. After band visualization by UV-shadowing, the gel pieces with corresponding nucleic acid complexes were cut and eluted overnight into 200 μL of TMS buffer. The samples were concentrated using a 3KDa molecular-weight cutoff filter device (Ultracel-3, Millipore) and resuspended into 100 μL of TMS buffer. AFM imaging was conducted at RT using silicon probes (NCH 320 kHz resonance frequency and 42 N/m spring constant, www.nanoworld.com) on the MultiMode AFM NanoScope IV system (Veeco), following the well-developed protocol.74 (link)
Benjes C.M, & Brown J.F. (2001). Database-generated Web pages: the Norris Medical Library experience. Bulletin of the Medical Library Association, 89(2), 222-224.
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