Применение аэрозоля нитазола в качестве антимикробного средства в клинике хирургической стоматологии

Клиническое испытание нитазола подтверждает его противомикробное действие по отношению к стафилококку, стрептококку, кишечной палочке, неклостридиальной аэробной микрофлоре в виде монокультур и микробных ассоциаций. Упаковка препарата — баллоны, образующие стойкую пену, весьма удобны. Безотказность в работе, простота применения позволяют применять препарат врачам как стационара, так и поликлиники, машин СП, а также при массовых поступлениях больных. Препарат Аэрозоль нитазола может применяться как эффективное антимикробное средство для первичной хирургической обработки и лечения гнойных ран; Клінічне випробування нитазола підтверджує його протимікробну дію по відношенню до стафілококу, стрептокока, кишкової палички, неклостридиальной аеробного мікрофлори у вигляді монокультур і мікробних асоціацій. Упаковка препарату - балони, що утворюють стійку піну, вельми зручні. Безвідмовність в роботі, простота застосування дозволяють застосовувати препарат лікарям як стаціонару, так і поліклініки, машин СП, а також при масових надходженнях хворих. Препарат Аерозоль нитазола може застосовуватися як ефективний антимікробний засіб для первинної хірургічної обробки і лікування гнійних ран; The clinical trial of nitazole confirms its antimicrobial effect against staphylococcus aureus, streptococcus, Escherichia coli, nonclostridial aerobic microflora in the form of monocultures and microbial associations. Packaging of the drug - cylinders that form a stable foam, are very convenient. Reliability in the work, ease of use allow the drug to be used by doctors in both the inpatient and outpatient clinics, the JV machines, as well as with mass income of patients. The drug Nitazol Aerosol can be used as an effective antimicrobial agent for primary surgical treatment and treatment of purulent wounds

Excitation cross sections for Li-like ions of beryllium and boron

We report on calculation of electron-impact excitation cross sections for Li-like ions of boron and beryllium. The data were produced with a number of modern methods in atomic collision theory, such as convergent close-coupling, K-matrix and Coulomb-Born-exchange. The results obtained are compared with other calculations and available expermental data, and the recommended cross sections for all transitions between atomic terms with principal quantum numbers n ≤ 4 are presented as tables of fitting parameters

Excitation Cross Sections for Li-like Ions of Beryllium and Boron

We report on calculation of electron-impact excitation cross sections for Li-like ions of boron and beryllium. The data were produced with a number of modern methods in atomic collision theory, such as convergent close-coupling, K-matrix and Coulomb–Born-exchange. The results obtained are compared with other calculations and available expermental data, and the recommended cross sections for all transitions between atomic terms with principal quantum numbers n 4 are presented as tables of fitting parameters. Due to the importance of beryllium and boron for fusion and astrophysics, the collisional data for ions of these elements have often been a subject of research, including calculations of excitation cross sections. The most recent compilation of the recommended data for electron-impact excitation of the Be qþ and B qþ ions [1] was principally based on the R-matrix (RM) and distorted-wave (DW) methods

Sea-Salt Aerosol Mass Concentration Oscillations after Rainfall, Derived from Long-Term Measurements in Lampedusa (Central Mediterranean)

Sea-salt aerosol (SSA) is the dominant contributor to cloud condensation nuclei over ocean areas, where wind speed is significant. Thereby, SSA could affect cloud formation and play an important role in the Earth weather and climate. Rainfall could produce large impact on SSA concentration due to wet removal processes. An analysis of changes in sea-salt aerosol concentration after rainfall is essential for a deeper understanding of the process of SSA loading in the boundary layer. The current experimental study focused on analyzing time variations of SSA mass concentration after rainfall, on the basis of long-term daily SSA measurements during the three-year period 2006–2008, at the tiny Mediterranean island of Lampedusa (Central Mediterranean). To study the effect of rainfall on SSA time variations, we used the superposed epoch method. We applied this approach to differing rainfall events related to different months and atmospheric/sea conditions. Integrated processing was applied to SSA concentration anomalies, in order to filter out random variability. Observational evidence of SSA mass concentration oscillations after rainfall with a maximum on the 2nd day and a minimum on the 4th day was obtained. The knowledge of SSA variations after rainfall is important for validating rainout parameterization in existing sea-salt aerosol and climate models