Details

Autor(en) / Beteiligte

• Graf, Christina
• Nordmeyer, Daniel
• Sengstock, Christina
• Ahlberg, Sebastian
• Diendorf, Jörg
• Raabe, Jörg
• Epple, Matthias
• Köller, Manfred
• Lademann, Jürgen
• Vogt, Annika
• Rancan, Fiorenza
• Rühl, Eckart

Titel

Shape-Dependent Dissolution and Cellular Uptake of Silver Nanoparticles

Ist Teil von

• Langmuir, 2018-01, Vol.34 (4), p.1506-1519

Ort / Verlag

United States: American Chemical Society

Erscheinungsjahr

2018

Quelle

Alma/SFX Local Collection

Beschreibungen/Notizen

• The cellular uptake and dissolution of trigonal silver nanoprisms (edge length 42 ± 15 nm, thickness 8 ± 1 nm) and mostly spherical silver nanoparticles (diameter 70 ± 25 nm) in human mesenchymal stem cells (hMSC’s) and human keratinocytes (HaCaT cells) were investigated. Both particles are stabilized by poly­vinyl­pyr­rolidone (PVP), with the prisms additionally stabilized by citrate. The nanoprisms dissolved slightly in pure water but strongly in isotonic saline or at pH 4, corresponding to the lowest limit for the pH during cellular uptake. The tips of the prisms became rounded within minutes due to their high surface energy. Afterward, the dissolution process slowed down due to the presence of both PVP stabilizing Ag{100} sites and citrate blocking Ag{111} sites. On the contrary, nanospheres, solely stabilized by PVP, dissolved within 24 h. These results correlate with the finding that particles in both cell types have lost >90% of their volume within 24 h. hMSC’s took up significantly more Ag from nanoprisms than from nanospheres, whereas HaCaT cells showed no preference for one particle shape. This can be rationalized by the large cellular interaction area of the plateletlike nanoprisms and the bending stiffness of the cell membranes. hMSC’s have a highly flexible cell membrane, resulting in an increased uptake of plateletlike particles. HaCaT cells have a membrane with a 3 orders of magnitude higher Young’s modulus than for hMSC. Hence, the energy gain due to the larger interaction area of the nanoprisms is compensated for by the higher energy needed for cell membrane deformation compared to that for spheres, leading to no shape preference.