4 article(s) from Schneider, Marc
- Full Research Paper
- Published 31 Oct 2022
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Figure 1: Schematic showing the roll-to-roll fabriction of a thin nanofur film by the example of PP and COC. ...
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Figure 2: Photos showing the essential fabrication steps of thin nanofur. (a) Extrusion line with rolling uni...
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Figure 3: (a) SEM picture of a side cut of a PP nanofur film (view angle 84°). (b) A water droplet of 1 µL on...
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Figure 4: (a) Nanofur produced with a gap size set 50 µm below the nominal material thickness. Many long hair...
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Figure 5: Contact angles measured along a 25 m long foil of nanofur produced in the described roll-to-roll pr...
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Figure 6: Comparison between nanofur produced by classical hot embossing and R2R nanofur. Even though morphol...
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Figure 7: (a) Schematic side view of the nanopads indicating their functionality. Two perforated polypropylen...
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Figure 8: Schematic of the nanopad fabrication steps. (a) First, circular cut-outs are produced using a circu...
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Figure 9: Fabrication of nanopads from polypropylene nanofur film. (a) In the first step, circular pieces are...
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Figure 10: Oil absorption as a function of the time for pads filled with cotton and different oils. The higher...
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Supp. Info
- Full Research Paper
- Published 16 Aug 2022
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Figure 1: 2D and 3D height images of gelatin nanoparticles crosslinked for 0.5 h. Images were taken at 37 °C ...
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Figure 2: Young’s moduli of gelatin nanoparticles and crosslinking time. (A) Highlighting the linear dependen...
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Figure 3: Influence of loading on the resulting particle elasticity. (A) FITC-dextran 70 kDa and lysozyme loa...
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Figure 4: Percentage of cell viability after 4 h and 24 h exposition to 0.001 to 1 mg/mL gelatine nanoparticl...
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- Full Research Paper
- Published 19 Nov 2019
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Figure 1: The effect of the flow rate ratio (0.05–1.0) and flow speed of the aqueous phase (10–100 µL/min) on...
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Figure 2: Illustration the impact of increasing the flow rate ratio on the mixing pattern and the geometry of...
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Figure 3: Effect of different PLGA concentrations (1–10 mg/mL) on NP size and PDI at different flow rate rati...
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Figure 4: Effect of adjusting the diameter of the focusing channel (100 µm, 180 µm and 280 µm) on NP size and...
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Figure 5: Effect of stabilizer concentration (0.1% and 1% of F68) on NP size and size distribution compared t...
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Figure 6: Effect of solvent nature (acetonitrile (ACN), dimethyl sulfoxide (DMSO) and acetone) on NP size and...
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Figure 7: Effect of using different mixing channel lengths (1 cm, 2 cm and 5 cm) on the NP size and size dist...
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Figure 8: Illustration of nucleation and growth mechanism of nanoprecipitation along the focus mixing channel...
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Figure 9: Comparison of the NP size after encapsulation using different approaches, namely the microfluidic s...
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Figure 10: Encapsulation efficiency of curcumin using the different approaches.
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Figure 11: Size and size distribution of nanoparticles stabilized with different types of Pluronic before and ...
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Figure 12: xz-micrographs taken in confocal laser scanning microscopy study of the penetration of differently ...
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Scheme 1: Sketch of the reaction scheme for PLGA labelling with rhodamine B. The carboxy group of the fluores...
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Figure 13: Design and flow pattern of the microfluidic system.
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