在线电解修整磨削的电解磨削液研制

为了对金属结合剂砂轮电解修整 ,研究并配制了电解磨削液。根据电解磨削液的性能要求 ,分析确定了电解磨削液中具有电解、钝化、防锈和润滑等性能的各组元 ,并通过静态实验确认了各组元对电解磨削液性能的影响。确定最佳电解磨削液在实际系统中对金属结合剂砂轮进行电解修整得到了较为满意的修整结果。所研制的电解磨削液具有实用价值 ,可用于生产。     

Characterization of Polyvinyl Alcohol/ZnO Nanocomposite Hydrogels for Wound Dressings

Polymeric hydrogels, as novel soft biomaterials, have found various applications in the medical field; for instance, as wound dressings and wound care management. In this study, in order to achieve wound dressings with improved properties, nanocomposite hydrogels using incorporation of nano zinc oxide (ZnO) in polyvinyl alcohol (PVA), were prepared by a freezing-thawing method. The effect of ZnO loading on the mechanical, structural, physical and antibacterial properties of the samples was investigated and the morphology of the prepared nanocomposite hydrogels was determined by field emission scanning electron microscopy (FESEM). The results of mechanical tests of the nanocomposite hydrogels, using compressive and hardness tests, indicated that by adding increasingly amounts of the ZnO nanoparticles, the mechanical properties of the nanocomposite hydrogels were improved. Structure-related properties of the hydrogels, such as swelling and gel fraction measurements, showed that the increase in ZnO content lead to a decrease in the swelling rate and increase in the gel fraction of the nanocomposites. Antibacterial and biocompatibility analysis revealed that, with increasing nano ZnO content, the antibacterial properties of the nanocomposite significantly increased and the cells viability rose, leading to slightly reduced toxicity. The results of this work indicated that the presence and quantity of added ZnO in the PVA hydrogels were very influential factors to obtain the desirable characteristics of wound dressings, such as absorbing the wound fluids and exudates, being biocompatible, anti-bacterial and nontoxic, and having mechanical stability and flexibility.     

Drug‐Conjugation Induced Self‐Assembly of Feather Keratin‐Based Prodrug for Tumor Intracellular Reduction Triggered Drug Delivery

As a kind of natural protein, keratin is widely investigated in the biomedical field. Here, for the first time, a keratin‐based prodrug (PK‐SS‐D) is designed for tumor intracellular reduction triggered drug delivery, by conjugating doxorubicin (DOX) onto poly(ethylene glycol) modified keratin (PEGylated keratin, PK) with a bioreducible disulfide linkage. The protein‐drug conjugate prodrug, with a drug content of 20%, can self‐assemble into micelles with a mean hydrodynamic diameter of 175 nm and a narrow distribution. The in vitro controlled release profiles reveal the reduction triggered thiolated DOX (DOX‐SH) release behavior of the PK‐SS‐D micelles, with a cumulative drug release up to 52% within 10 d in the simulated tumor microenvironment in a sustained releasing mode, and a low drug leakage of 17% in the simulated normal physiological medium. The enhanced tumor growth inhibition of the proposed PK‐SS‐D prodrug micelles is revealed by the methyl tetrazolium (MTT) assays, although the released DOX‐SH prodrug possesses a lower tumor growth inhibition than DOX.     

Atom as a “dressed” nucleus

We show that the electrostatic potential of an atomic nucleus “seen” by a fast charged projectile at short distances is quantum mechanically smeared due to nucleus motion around the atomic center of inertia. For example, the size of the “positive charge cloud” in the Hydrogen ground state is much larger than the proper proton size. For target atoms in excited initial states, the effect is even larger. The elastic scattering at large angles is generally weaker than the Rutherford scattering since the effective potential at short distances is softer than the Colombian one due to a natural “cutoff”. In addition, the large-angle scattering leads to target atom excitations due to pushing the nucleus (⇒ inelastic processes). The Rutherford cross section is in fact inclusive rather than elastic. These results are analogous to those from QED. Non-relativistic atomic calculations are presented. The difference and the value of these calculations arise from nonperturbatively (exact) nucleus “dressing” that immediately leads to correct physical results and to significant technical simplifications. In these respects a nucleus bound in an atom is a simple but rather realistic model of a “dressed” charge in the QFT. This idea is briefly demonstrated on a real electron model (electronium) which is free from infinities.      

Dressing method in matter+radiation quantum models

We consider spectral problems related to Dicke and Jaynes-Cummings matter-radiation Hamiltonians and write the spectrum of a perturbed Dicke model (of a trapped ion interacting with the center-of-mass motion) in explicit form. We derive the dressing chain equations for non-Abelian elements and investigate them for two-state matter models. We discuss embedding of Jaynes-Tavis-Cummings models and nonrotating wave terms. __________ Translated from Teoreticheskaya i Matematicheskaya Fizika, Vol. 152, No. 1, pp. 118–132, July, 2007.     

Coherent control of dressed images of four-wave mixing

In two-level as well as V-type three-level atomic systems, we study probe transmission, four-wave mixing (FWM) and fluorescence signals with dressing effect experimentally and theoretically. We find both the hyperfine structure (at the same energy level) and the transition dipole moment (at different energy levels) can affect the dressing effect. We also experimentally investigate that angle-control dynamics in the nonlinear propagation of the images of the probe and generated FWM in two-level atomic systems, and find that the focusing and defocusing of probe beam and FWM signals can be greatly affected by the angles between dressing fields.     

In Vitro Assessment of Poly (Vinyl Alcohol) Film Incorporating Aloe Vera for Potential Application as a Wound Dressing

Since skin tissue acts as a vital protective barrier between the body and the external atmosphere, the repair or regeneration of skin injuries serves as a great challenge in regenerative medicine. Herein, hydrogel films composed of poly vinyl alcohol (PVA) and aloe vera (AV) extracted gel were prepared and characterized for wound dressing application. The physical and morphological properties, water absorption capacity, biodegradation behavior, and water transmission rate were characterized for several variations in the AV content (0–50%). The cytocompatibility of the films, as well as cell morphology in response to different films, was assessed using MTT assay and SEM, respectively. According to the results, AV incorporation improved the surface morphology, water absorption capacity, in vitro degradation rate, and water vapor permeability of the PVA films. However, these properties were affected by the AV content. The mechanical properties of the films were enhanced by introducing AV up to 30%, and then decreased significantly with further AV increase. Evaluation of fibroblast proliferation showed that AV can positively improve the bioactivity of the films without any cytotoxicity. In conclusion, the results demonstrated that PVA/AV optimized hydrogel film can be suggested as promising wound dressings for improving wound treatment.     

Integrable Structure Behind the WDVV Equations

An integrable structure behind the Witten–Dijkgraaf–Verlinde–Verlinde (WDVV) equations is identified with the reduction of the Riemann–Hilbert problem for the homogeneous loop group . The reduction requires the dressing matrices to be fixed points of an order-two loop group automorphism resulting in a subhierarchy of the hierarchy containing only odd-symmetry flows. The model has Virasoro symmetry; imposing Virasoro constraints ensures the homogeneity property of the Darboux–Egoroff structure. Dressing matrices of the reduced model provide solutions of the WDVV equations.     

Lipid organization and stratum corneum thickness determined in vivo in human skin analyzing lipid–keratin peak (2820–3030 cm−1) using confocal Raman microscopy

While the intercellular lipid structure of the stratum corneum (SC) plays an important role in the skin barrier function, the depth‐dependent profile of the intercellular lipids contributes decisively to deepen the understanding of the skin barrier function, drug penetration, development of skin diseases and their medication. The depth‐dependent profile of the lipids' chemico‐physical properties, such as the solid–fluid phase transition and the order–disorder transition, can exclusively be measured in human skin in vivo by means of confocal Raman microscopy. In the present paper, the lipid–keratin peak (2820–3030 cm⁻¹) was investigated. The lipid‐related Raman peaks centered at 2850 cm⁻¹ and 2880 cm⁻¹ were deconvoluted using Gaussian functions and investigated for their depth‐dependent shape and positional changes. Different fitting procedures show that even an additional Gaussian function cannot be used to fully characterize the lipid's polymethylene chains around 2880 cm⁻¹, which justifies the introduction of the sharpness of the peak centered near 2880 cm⁻¹. The results show that the 2880 cm⁻¹ peak sharpness might be used for determining the SC thickness. The concentration of the lipids with long‐chain carbon backbone (free fatty acids and ceramides) semi‐quantitatively decreases from 10 µm to 20 µm (SC thickness is 19.8 µm). The maximum position and broadness of the Gaussian peak centered at 2850 cm⁻¹ show that near the surface and in the deeper layers of the SC, the state of the lipids is more fluid and disordered compared to the medium layers of the SC. Copyright © 2016 John Wiley & Sons, Ltd.