Климатические особенности и статистические оценки изменения элементов климата в районах вечной мерзлоты на территории севера Западной Сибири

Актуальность работы связана с необходимостью оценки изменений климата, влияющих на многолетнюю мерзлоту, в связи с возможным увеличением выбросов парниковых газов и увеличения аварийности на объектах промышленной, в том числе и нефтегазовой, инфраструктуры при таянии многолетнемерзлых пород. Цель работы: исследование современных изменений характеристик климата, непосредственно влияющих на термическое состояние почвогрунтов в районах распространения многолетней мерзлоты севера Западной Сибири. Методы исследования. Анализ многолетних изменений метеорологических данных включал в себя проверку нулевых гипотез о случайности и однородности рядов наблюдений и наличия тренда. Проверка на однородность осуществлялась с помощью теста Аббе, на случайность - критерием Питмена, на наличие тренда производилась с помощью критерия инверсий. Вывод о неслучайном изменении или нарушении однородности рядов соответствовал условию, когда расчетная статистика превышала соответствующее критическое значение при уровне значимости 0,05. Результаты. Рассмотрены особенности климата севера Западной Сибири и его изменчивость в последние годы. Исследованы изменения температуры воздуха и почвогрунтов на глубинах 160 и 320 см, продолжительность прямой солнечной радиации, суммы атмосферных осадков и высоты снежного покрова на основе инструментальных данных за последние 35 лет. В результате статистического анализа установлено сохранение темпов роста температуры воздуха в теплое время года, увеличение температуры почвогрунтов в течение всего года, выявлен зональный характер изменения суммы атмосферных осадков и снежного покрова. Микроклиматические изменения характеристик метеорологических величин могут искажать реальную картину изменения климата.The relevance of the research is related to the necessity to assess climate changes affecting the permafrost due to the possible growth of greenhouse gas emissions and increase of accident rate in industrial, oil and gas infrastructure at permafrost thawing. The aim of the research is to estimate the current changes in climate characteristics, which affect directly the thermal state of soils in permafrost areas in the north of Western Siberia. Methods. Analysis of long-term changes of meteorological data consisted of tests of null hypothesis of randomness and homogeneity of observation series and trend presence. The homogeneity test was carried out using the Abbe test, the test of randomness was carried out by Pitman criterion, the trend presence was checked using the criterion of inversions. The conclusion on nonrandom change or violation of the homogeneity of rows corresponded to the condition, when the modulus of the estimated statistics exceeded the corresponding critical value at significance level of 0,05. Results. The paper considers the climatic features in the north of Western Siberia and its variability in recent years. The analysis of temperature changes of air and soil at depths of 160 and 320 cm, the amount of precipitation and snow cover based on the instrumental data for the last 35 years has shown that air temperature continues rising in the warmer months, soil temperature increases throughout the year. The authors have revealed zonal character of changes in the amount of precipitation and snow cover. Microclimatic changes in characteristic of meteorological values can distort the real picture of climate change

Suspension-adapted Chinese hamster ovary-derived cells expressing green fluorescent protein as a screening tool for biomaterials

Synthetic biomaterials play an important role in regenerative medicine. To be effective they must support cell attachment and proliferation in addition to being non-toxic and non-immunogenic. We used a suspension-adapted Chinese hamster ovary-derived cell line expressing green fluorescent protein (GFP) to assess cell attachment and growth on synthetic biomaterials by direct measurement of GFP-specific fluorescence. To simplify operations, all cell cultivation steps were performed in orbitally-shaken, disposable containers. Comparative studies between this GFP assay and previously established cell quantification assays demonstrated that this novel approach is suitable for rapid screening of a large number of samples. Furthermore the utility of our assay system was confirmed by evaluation of cell growth on three polyvinylidene fluoride polymer scaffolds that differed in pore diameter and drawing conditions. The data presented here prove the general utility of GFP-expressing cell lines and orbital shaking technology for the screening of biomaterials for tissue engineering application

Spatial layering of cells in a novel poly(lactic acid-co-caprolactone)-collagen hybrid construct

INTRODUCTION: Advantages of synthetic polymers as a scaffolding material include the ability to produce them on a large scale and the ability to tailor their physical and mechanical properties to exact specification. A continuing difficulty is the uncertainty of cell seeding, largely due to a non-ideal surface chemistry. Natural biopolymers on the other hand, provide a substrate for cell-adhesion, are highly organized, and have the ability to induce tissue growth. A main disadvantage, however, is that they are less readily available and their mechanical and physical properties are difficult to control. The concept of combining these two biomaterials and their advantages is attractive. In this study we have fabricated a hybrid construct consisting of a synthetic polymer mesh coated with hyperhydrated collagen gels, which were plastic compressed

A collagen-poly(lactic acid-co-ɛ-caprolactone) hybrid scaffold for bladder tissue regeneration.

Scaffold materials should favor cell attachment and proliferation, and provide designable 3D structures with appropriate mechanical strength. Collagen matrices have proven to be beneficial scaffolds for tissue regeneration. However, apart from small intestinal submucosa, they offer a limited mechanical strength even if crosslinking can enhance their mechanical properties. A more cell-friendly way to increase material strength is to combine synthetic polymer meshes with plastic compressed collagen gels. This work describes the potential of plastic compressed collagen-poly(lactic acid-co-ɛ-caprolactone) (PLAC) hybrids as scaffolds for bladder tissue regeneration. Human bladder smooth muscle and urothelial cells were cultured on and inside collagen-PLAC hybrids in vitro. Scaffolds were analyzed by electron microscopy, histology, immunohistochemistry, and AlamarBlue assay. Both cell types proliferated in and on the hybrid, forming dense cell layers on top after two weeks. Furthermore, hybrids were implanted subcutaneously in the backs of nude mice. Host cell infiltration, scaffold degradation, and the presence of the seeded bladder cells were analyzed. Hybrids showed a lower inflammatory reaction in vivo than PLAC meshes alone, and first signs of polymer degradation were visible at six months. Collagen-PLAC hybrids have potential for bladder tissue regeneration, as they show efficient cell seeding, proliferation, and good mechanical properties