The optimal AgNP

The optimal AgNP concentration was found at 5 × 10-7 mg/μl. Under this condition, the SERS intensity was at least 5-fold higher than that of the normal Raman spectrum measured from the bacteria sample without AgNP spiking, which was proof of the effectiveness of the concept for the DEP-Bucladesine purchase assisted NP-bacteria adsorption intended to enhance the Raman signal. The minimal gap for assembled microparticles has been calculated to be roughly 10 nm (approximately

2λ, λ is the thickness of the double layer) at a conductivity of 1 mS/cm [9]; thus, the electric field is compressed, and the DEP force is locally amplified at the assembled bead-bead gaps such that the nanostructures produce an extremely high positive DEP GM6001 chemical structure force for manipulating AgNPs/nanocolloids, as shown in Figure  2a. Another assisted EPZ015938 research buy mechanism for AgNP-bacteria adsorption could be attributed to the electric field-induced dipole-dipole interaction [29, 30]. Figure  4b shows five spectra of S. aureus that were detected for five times by five different chips. This result demonstrates

good spectral reproducibility via dielectrophoresistic-assisted AgNP-bacteria sorption. Figure 4 Bacteria Raman signals and spectra of S . aureus . (a) The bacteria solution with different AgNP concentrations of 2.5 × 10-7, 5 × 10-7, and 1 × 10-6 mg/μl was adjusted to investigate the optimal AgNP condition for SERS resulting in an optimal AgNP concentration being found at 5 × 10-7 mg/μl. (b) Spectra of S. aureus that were detected via the amplified DEP AgNP-enhanced Raman five runs using five different chips. The blood cell-bacteria mixture was also used to demonstrate that our platform is capable of identifying bacteria from a diluted blood sample. Therefore, the DEP approach was also used to separate bacteria and blood cells. A voltage of Sclareol 15 Vp-p at a frequency of 1 MHz was applied to separate the bacteria and blood cells based on their different DEP behaviors. Under this electrical condition, the blood

cells were attracted to the electrode edges by the positive DEP force, while the bacteria experienced a negative DEP force and were trapped and concentrated in the middle region between the quadruple electrodes where there is a high density of bacteria aggregate to be Raman-detected, as shown in Figure  5a and inset A1. After bacteria separation and concentration, the trapped bacteria aggregate continued to experience the amplified DEP force in order to adsorb the AgNPs into the bacteria aggregate for 3 min. The Raman laser spot was then irradiated to the bacteria-NP aggregate separated from the blood cells for the purpose of SERS identification of the concentrated bacteria. The red and green lines in Figure  5b indicate the Raman spectra of the red blood cell (RBC) and RBC-bacteria mixture, respectively.

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