The Boltzmann transport equation (BTE) is widely used in modern physical kinetics [19, 20] even at nanoscales MLN2238 in vivo [21, 22]. In our previous work, we solved BTE and determined the response of the conduction electrons on an electromagnetic wave allowing for dependence of the distribution function on the wavenumber. Then,

we obtained the spatially dispersive permittivity of metal and applied a generalized Mie theory [23] to calculate spectra of light extinction by silver nanospheres. Because of excitation of the rotationless (longitudinal) plasmon-polariton waves, the frequency of the Fröhlich resonance ω=3.5 eV [24] was found to increase with decreasing the radius a, so ω=3.635 eV for particles with selleck screening library a=1.5 nm and ω=3.73 eV at a=1 nm (see Figure two of [25]; a similar dependence of ω on a as well as the formulas of [23] is found in a recent paper [26]). The blueshift by 0.15 eV and the width of the plasmon resonance calculated for a particle beam created by Hilger, Tenfelde, and Kreibig [27] were

in excellent agreement with the experimental data. We concluded that silver clusters with a<1 nm do not contribute into the extinction spectra of the beams. However, it was not possible to establish whether the contribution of these ultrathin particles into the integral extinction spectrum vanished due to MIT. Energies of the conduction electrons It is a common practice to assume that the conduction electron

energy ε in metal is a function of the continuous quasi-momentum This approach can be used to model the properties of bulk metals eltoprazine in which an electron state s can be described by a set of four quantum numbers, where is a projection of the electron spin. However, if an electron moves inside a microscopic sphere, the vector p can no longer describe an electron state. The set p x ,p y , and p z has to be replaced by a set of the radial q, angular momentum l, and magnetic m quantum numbers. Then, integrals over p should be replaced by sums over the electron states s, according to the following rule: , where V is the volume of the body and h is the Plank constant. In this study, we used discrete sets of the electron energies ε s . Shape of metal nanoparticles Every set of the electron energies ε s was obtained at a certain number N of electrons confined in a potential well of an ideal spherical shape. We used the parameters of bulk silver and gold [28], namely, the depth of the potential well U=9.8 eV and the Wigner-Seitz radius r s =0.16 nm. Because of the spherical symmetry of the electronic wave functions, different physical processes have peculiar features at magic numbers of electrons. The magic numbers, which we determined for perfect noble metal spheres, are presented in the ‘Background’ Section of this paper.

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1 kb nucleotides (HA117 Seliciclib gene) was obtained and sequenced, which indicated that the recombined plasimid pAdTrack/HA117 was constructed successfully. The pAdTrack-HA117 was homologous recombined with BJ-Adeasy in E. coli. Then, the recombined Adeasy-HA117 plasmid was identified by Pac1 cutting. One 30 kb strap and one 4.5 kb strap could be seen by agarose gel electrophoresis, which proved that the homologous recombination was successful (Figure 1). Then, pAdeasy-HA117 was transfected into 293 cells. After two weeks, the transfected 293 cells became to be float from adherence observed by the GFP fluorescence intensity (Figure

2). At this time, the completed recombined adenovirus Ad5-HA117 was harvested. Figure 1 Gel screening of Adeasy-HA117 after digested by Pac I. After digeted with Pac I, Adeasy-HA117 produced 4.5 kb DNA strap, which proved that the homologous recombination was successful. M: DNA Marker; 1,2: Adeasy-HA117 Figure 2 The generation of recombinated adenovirus pAdeasy-HA117. Expression of fluorescence and most suitable adenovirus amount of infetected K562 cells The K562 cells had green fluorescent expression at 24 hours after infected

(Figure 3). It was found that the infection rate of adenovirus to K562 cells increased with the adenovirus amout increased. Both cells’ survival rate (exceeded 80%) and infection rate (reached 39.72%) were fairly well when MOI was 100. And the weak and dead cells increased selleck products obviously when MOI exceeded 100. So MOI 100 was chosen as the most suitable amount for

the further investigation (Table 1 and Figure 4). Figure 3 Fluorescent expression of K562 cells after transfected 24 hours. A:K562 cells; B: K562/Ad-HA117 cells expressed green fluorescence. Figure 4 The infection rates of K562 cells during different MOI detected by FCM. The infection rates were about 39.72%~64.3%. Immune system A: MOI = 100; B: MOI = 1000. Table 1 The rates of infection and survival of cell during different MOI   MOI   1 10 50 100 500 1000 Infection rates 0.47 ± 0.04 5.83 ± 0.07 10.65 ± 0.11 16.19 ± 0.31 20.27 ± 0.52 30.42 ± 2.31 Survivil rates 90.33 ± 1.21 85.27 ± 1.37 82.11 ± 1.63 81 ± 1.42 62.23 ± 2.15 40.25 ± 2.13 RT-PCR results for HA117 gene expression in k562 cells Both uninfected K562 cells and K562/Ad-null cells had no HA117 gene expression, and HA117 expressed only in the K562/Ad-HA117 cells, which indicated that K562 cells could express exogenous HA117 gene when infected by Ad-HA117 (figure 5). Figure 5 The expression of HA117 gene mRNA in K562 cells. M: DNA marker; 1:K562 cells; 2: K562/Ad-null cells had no HA117 gene expression; 3:K562/Ad-HA117 cells had HA117 gene expression. The DNA strap having 397 bp was β-actin. The MTT assays results for K562 cells’ drug sensitivity The survival rates of K562/HA117 cells increased than that of K562 cells and K562/Ad-null cells. The RFs of K562/Ad-HA117 cells to VCR, ADM, Vp-16, DNR, MMC and CTX were 4.

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