微囊化K562细胞生长周期及代谢特性的研究

以K562细胞为模型,分别进行微囊化和游离培养,运用流式细胞术考察两种培养体系下细胞周期和生长代谢变化;建立数学模型,模拟了两种培养体系下细胞的生长活性和代谢特性。实验发现：微囊化培养过程中的K562细胞处于DNA合成期（S期）的百分含量显著高于游离培养,并且细胞保持较高的增殖活性。模型计算表明,所建模型动力学参数能够很好地描述微囊化和游离两种培养体系下细胞的代谢情况;对细胞活性的理论计算表明,微囊化的细胞具有较高的增殖和代谢活性,同时细胞能够较长时间保持此活性;模型参数表明,两种培养体系下,葡萄糖对细胞生长的影响无显著差别 (k^Free_L≈k^APA_L),乳酸对游离培养细胞的生长具有明显抑制作用,但对微囊化培养细胞抑制作用较小(kFreeL>≈kAPAL)。     

体外培养和冷冻保存对微囊化细胞生长和内皮抑素表达的影响

微囊化基因工程细胞移植治疗肿瘤是一种新兴的肿瘤治疗方法,如果将此技术应用到临床研究,就需要制备大量的细胞活性良好、重组蛋白表达量高的生物微胶囊。体外培养和冷冻保存是生物微胶囊制备过程中两个重要的环节,因此需要考察体外培养和冷冻保存对微囊化重组基因细胞生长和蛋白表达的影响。以重组CHO细胞为模型,考察了体外培养时间和冷冻保存对微囊化细胞在动物体内生长和内皮抑素表达的影响及体外培养时间对微囊化细胞冷冻保存的影响。结果表明:体外培养时间对微囊化细胞在动物体内生长、内皮抑素表达和微囊稳定性具有较大的影响,体外不培养和培养4d的微囊化细胞在小鼠腹腔内生长良好、内皮抑素表达量高,并且微囊稳定性好,而体外培养8d的微囊化细胞在移植后的第26天破裂。体外培养时间对微囊化细胞冷冻保存也具有较大的影响,体外培养4d和8d的微囊化细胞在液氮中冷冻保存40d,复苏后细胞生长良好、内皮抑素表达量高,而冻存前未经过体外培养的微囊化细胞,复苏后细胞几乎全部死亡。综上所述,生物微胶囊在体外比较适宜的培养时间为4d。并且冷冻保存对微囊化细胞在动物体内生长、内皮抑素表达和微囊稳定性没有显著的影响。     

微囊化重组CHO细胞制备和培养条件的优化

微囊化重组基因细胞移植治疗肿瘤是一种新兴的肿瘤基因治疗方法,然而由于目前微囊化细胞规模化制备和培养技术还不成熟,阻碍了其在临床治疗中的推广与应用。以重组CHO细胞为模型,考察了不同的微囊制备和培养条件对微囊化细胞生长和内皮抑素表达的影响。实验表明,种子细胞所处的生长阶段和细胞接种密度对微囊化细胞生长和内皮抑素表达的影响较大,对数生长期的细胞进行包囊并且细胞接种密度为1×106~2×106cells/mL微囊时微囊内细胞生长良好、内皮抑素表达量高。微囊制备时间对细胞活性和内皮抑素表达也有较大的影响,制备时间延长对细胞的损伤增大,因此制备时间应控制在5h以内。生物微胶囊在制备过程中会造成细胞损伤,而体外培养是恢复细胞活性的良好方法,在培养过程中微囊接种量为5%时对细胞生长和内皮抑素表达有利。     

微囊化胰岛B细胞系体外生长和分泌功能的研究

目的：研究海藻酸钠－多聚赖氨酸－海澡酸钠（APA）微囊化胰岛B细胞系BTC6－F7的生长和分泌规律,探索其作为生物人工胰岛的可能性。方法：以微囊静电液滴发生器制作APA微囊化BTC6－F7细胞,体外培养并定期测定微囊化细胞的生长和胰岛素分泌。结果：在实验观察的90d内,BTC6－F7细胞可在微囊内以细胞团的形式生长、存活。囊内细胞总数随培养时间的延长而增加,但细胞活率呈下降趋势,胰岛素分泌与囊内活细胞数的变化规律一致,最初呈上升趋势,然后较长时间维持在相对恒定的水平。结论：本研究所制备的APA微囊化胰岛B细胞可在较长时间内保持生长、存活和分泌功能,为进一步发展生物型人工胰岛奠定了基础,并可用于糖尿病的发病机理和治疗研究。     

谷氨酰胺对微囊化重组CHO细胞生长代谢及内皮抑素表达的影响

微囊化技术是一种有发展潜力的生物技术,在细胞移植和药物控释等方面具有广泛的应用。然而由于目前微囊化细胞规模化培养技术还不成熟,阻碍了其在临床治疗中的推广与应用。为了了解微囊化重组CHO细胞的生长代谢特性为今后规模化培养优化提供技术参考,考察了主要氮源物质谷氨酰胺对微囊化重组CHO细胞生长代谢及内皮抑素表达的影响。结果显示:当谷氨酰胺起始浓度从2.69mmolL增加到9.05mmolL时最大活细胞密度并没有增高,细胞增殖没有显著差异。当谷氨酰胺起始浓度较低(2.69mmolL)时,葡萄糖的比消耗速率较大;当谷氨酰胺起始浓度增高时(7.91mmolL～9.05mmolL)葡萄糖和谷氨酰胺的比消耗速率增大,但细胞对葡萄糖和谷氨酰胺的利用率降低。谷氨酰胺对产物表达有显著影响,起始浓度为4.97mmolL时的内皮抑素累积浓度最高,达546.36ngmL,过低和过高谷氨酰胺起始浓度下内皮抑素的累积浓度均较低。     

表达内皮抑素的rCHO细胞的微囊化培养

微囊化重组基因细胞移植治疗肿瘤是一种新兴的肿瘤基因治疗方法,如果将此技术应用到临床研究,就需要制备大量的细胞活性良好、重组蛋白表达量高的生物微胶囊。种子细胞是生物微胶囊治疗作用的执行者, 是构建微囊微反应器的基本元素。如何获得大量高活性的种子细胞已经成为规模化制备生物微胶囊所面临的最关键的限制因素。本实验考察了搅拌式生物反应器内扩增的重组CHO细胞进行包囊及微囊化细胞在生物反应器内规模化培养的可行性。实验结果显示:重组CHO细胞在生物反应器内可以快速生长,并且对数期细胞包囊,微囊化细胞活性良好。制备的微囊化细胞可以在生物反应器内培养,与培养板培养比较细胞生长较快、内皮抑素表达量较高。应用生物反应器培养技术能够在体外快速、大量扩增重组CHO细胞,满足微囊化细胞制备对种子细胞量与质的要求,微囊化细胞可以在生物反应器内培养。     

HPLC监测微囊化细胞培养中乳酸和丙酮酸的变化

ＨＰＬＣ监测微囊化细胞培养中乳酸和丙酮酸的变化朱冬发,李士云,吉鑫松,袁中一（中国科学院上海生物化学研究所,２０００３１）关键词丙酮酸;乳酸;ＨＰＬＣ;细胞培养;微囊化动物细胞随着基因工程和细胞培养技术的发展,人们越来越重视利用生物反应器大规模培养基...     

无载体固定化培养模式下HEK293细胞的生长和代谢特征

利用HEK293细胞在悬浮培养体系中下具有聚集成团的体外培养特性,在250ml的spinner flask搅拌式细胞培养瓶中以悬浮细胞团的形式实施HEK293细胞的无载体固定化培养,以细胞密度、细胞活力、细胞团粒径分布和葡萄糖比消耗率 (qglc)、乳酸比产率 (qlac)、乳酸转化率 (Ylac/glc)、氨基酸消耗为观察指标,同时设置静止培养体系作为参照,考察无载体固定化培养模式下的HEK293细胞生长和代谢特征。观察结果表明,HEK293细胞在搅拌式细胞培养瓶中无载体固定化培养和在组织培养瓶中静止贴壁培养表现为基本相同的细胞生长和代谢特征,平均粒径小于300μm的细胞团中的物质传递能够满足HEK293细胞维持正常生长和代谢的基本需要。HEK293细胞的无载体固定化培养便于实施灌注操作、提高生物反应器单位体积的生产效率。     

微囊化干细胞及其应用研究进展

干细胞极强的自我更新能力和多向分化潜能使其可以成为绝佳的种子细胞来源,用于各种疑难疾病的治疗。微胶囊不仅可以为细胞提供三维生长微环境,而且具有良好的免疫隔离性能和生物相容性。微囊化干细胞技术为干细胞大规模、高活性体外培养及长期保存提供了新的技术支持,为细胞移植疗法开辟了新途径。以下首先简述了微囊化技术的发展情况,然后介绍了目前用于微囊化干细胞的材料、制备方法及其免疫隔离作用,重点阐述了近年来微囊化各种不同类型干细胞的研究和应用进展。最后,提出目前微胶囊化干细胞的问题所在并对此技术进行展望。     

三维支架材料中软骨细胞生长过程的数值模拟

组织工程是临床上用于修复以及重建受损软骨的一项有广泛应用前景的方法。但是在支架材料内部物质传递仅仅依赖于扩散,这是支架材料中细胞生长的主要限制因素。利用氧扩散-反应基本原理建立了软骨细胞生长过程的数学模型,同时考虑了由于细胞生长引起的扩散系数下降以及空间抑制因素对细胞生长的影响。模拟结果与实验数据吻合良好,表明该模型对材料内部的细胞生长的分析具有较高的可靠性,可用于组织工程生物反应器以及三维多孔支架材料的优化设计。     

Cell cycle modelling

Models able to describe the events of cellular growth and division and the dynamics of cell populations are useful for the understanding of functional control mechanisms and for the theoretical support for automated analysis of flow cytometric data and of cell volume distributions. This paper reports on models that we have developed with this aim for different kinds of cells. The models are composed by two subsystems: one describes the growth dynamics of RNA and protein, and the second accounts for DNA replication and cell division, and describe in a rather unitary frame the cell cycle of eukaryotic cells, like mammalian cells and yeast, and of prokaryotic cells. The model is also used to study the effects of various sources of variability on the statistical properties of cell populations, and we find that in microbial cells the main source of variability appears to be an inaccuracy of the molecular mechanism that monitors cell size. In normal mammalian cells another source of variability, that depends upon the interaction with growth factors which give competence, is apparent. An extended version of the model, which comprises also this additional variability, is presented and used to describe the properties of mammalian cell growth.     

Cell growth and hemoglobin synthesis in murine erythroleukemic cells propagated in high density microcapsule culture

Summary A new microencapsulation technology, developed for the encapsulation of living cells, has been demonstrated to be useful for the study of growth and differential gene expression using Friend erythroleukemic cells cultured at high cell densities. Using this technology, cultures of FL Clone 745 cells were encapsulated within semipermeable membranes composed of cross-linked alginic acid and poly-l-lysine. Cell growth studies measuring total cell number demonstrated an average generation time of 8.5 h in 5% (vol/vol) microcapsule cultures vs. 8.0 h in suspension cultures. Similar microcapsule cultures were serially propagated for more than 90 cell generations (13 sequential passages) with no significant change in this growth rate. In addition, final culture densities of greater than 1.0×10⁸ cells/ml of intracapsular volume were attained using a 3% (vol/vol) microcapsule culture in conjunction with a standard refeeding schedule. Comparison of the level of dimethyl sulfoxide-induced hemoglobin production in suspension and microcapsule cultures demonstrated that the total amount of hemoglobin produced on a per cell basis was comparable in both systems. Due to the retention characteristics of the semipermeable membrane, the concentration of detergent-released hemoglobin, relative to other released protein, was approximately twofold higher in microcapsule cultures than in control suspension cultures.     

Cell cycle progression

In this paper we consider cell cycle models for which the transition operator for the evolution of birth mass density is a simple, linear dynamical system with a stochastic perturbation. The convolution model for a birth mass distribution is presented. Density functions of birth mass and tail probabilities in n-th generation are calculated by a saddle-point approximation method. With these probabilities, representing the probability of exceeding an acceptable mass value, we have more control over pathological growth. A computer simulation is presented for cell proliferation in the age-dependent cell cycle model. The simulation takes into account the fact that the age-dependent model with a linear growth is a simple linear dynamical system with an additive stochastic perturbation. The simulated data as well as the experimental data (generation times for mouse L) are fitted by the proposed convolution model.     

A Mass Conserved Reaction–Diffusion System Captures Properties of Cell Polarity

Cell polarity is a general cellular process that can be seen in various cell types such as migrating neutrophils and Dictyostelium cells. The Rho small GTP(guanosine 5′-tri phosphate)ases have been shown to regulate cell polarity; however, its mechanism of emergence has yet to be clarified. We first developed a reaction–diffusion model of the Rho GTPases, which exhibits switch-like reversible response to a gradient of extracellular signals, exclusive accumulation of Cdc42 and Rac, or RhoA at the maximal or minimal intensity of the signal, respectively, and tracking of changes of a signal gradient by the polarized peak. The previous cell polarity models proposed by Subramanian and Narang show similar behaviors to our Rho GTPase model, despite the difference in molecular networks. This led us to compare these models, and we found that these models commonly share instability and a mass conservation of components. Based on these common properties, we developed conceptual models of a mass conserved reaction–diffusion system with diffusion–driven instability. These conceptual models retained similar behaviors of cell polarity in the Rho GTPase model. Using these models, we numerically and analytically found that multiple polarized peaks are unstable, resulting in a single stable peak (uniqueness of axis), and that sensitivity toward changes of a signal gradient is specifically restricted at the polarized peak (localized sensitivity). Although molecular networks may differ from one cell type to another, the behaviors of cell polarity in migrating cells seem similar, suggesting that there should be a fundamental principle. Thus, we propose that a mass conserved reaction–diffusion system with diffusion-driven instability is one of such principles of cell polarity.     

Cell growth and alpha-amylase production characteristics of Bacillus amyloliquefaciens

Growth and alpha-amylase production characteristics of Bacillus amyloliquefaciens strain F (ATCC 23350) in batch cultures are examined using glucose or maltose as the carbon source. While the cell growth is rapid when glucose is used as the carbon source, higher cell mass, higher total and specific enzyme activities, and higher enzyme production rates are obtained when maltose is used as the carbon source. The overall specific enzyme activity decreases with an increase in the initial concentration of carbon source. The oxygen requirement and carbon dioxide generation vary linearly with the maximum amount of cell mass produced. For experiments conducted using glucose as the carbon source, the kinetics of cell growth and glucose consumption are described using a special form of the Vavilin equation. For a given amount of initial carbon source, the enzyme synthesis capability is retained by the microorganism, although at a substantially reduced level, under severe oxygen limitation.     

Changes in Cell Size and Shape Associated with Changes in the Replication Time of the Chromosome of Escherichia coli

Average cell mass is shown to be inversely related to the concentration of thymine in the growth medium of a thy⁻ strain of Escherichia coli. The kinetics of the transition from one steady-state average cell mass to another was followed in an attempt to determine the relationship between the chromosome replication time and the time between completion of a round of chromosome replication and the subsequent cell division. Differences in average cell mass are shown to be associated with similar differences in average cell volume. Changes in volume associated with changes in thymine concentration are shown to be due primarily to differences in the width of cells. It is proposed that extension in length of the cell envelope occurs at a linear rate which is proportional to the growth rate and which doubles at the time of termination of rounds of replication. Changes in volume not associated with a change in growth rate are therefore accommodated by a change in cell width. Conditions are described under which average cell mass can continue to increase in successive generations and no steady-state average cell mass is achieved.     

Influence of microenvironmental conditions on hybridoma cell growth inside the alginate-poly-l-lysine microcapsule

A mathematical model was formulated to describe hybridoma cell growth within the alginate-poly-l-lysine (alginate-PLL) microcapsules during air-lift bioreactor cultivation. Model development was based on experimentally obtained data concerning the hybridoma cell counts, monoclonal antibody (mAb) production and the distribution of hybridoma cell growth within the microcapsules. The cell growth was modeled using a mean field approach expressed as Langevin class of equations for two different regions of alginate-PLL microcapsules, the alginate microcapsule core and the annular region between microcapsule core and membrane. In this paper we propose an influence of microenvironmental conditions on cell growth. The osmotic pressure changes in the Na-alginate liquefied annular region, as well as, the resistance effects of Ca-alginate hydrogel in the core region during the cell growth were incorporated into the model. Good agreement between the experimental data and model prediction values was obtained. The proposed model successfully predicted the impact of various microenvironmental restriction effects on the dynamics of cell growth and appears useful for further optimization of microcapsule design in order to achieve higher intra-capsule cell concentrations resulting in higher amounts of mAb produced.     

Age-dependent cell cycle models.

This paper presents age-dependent cell cycle models i.e., models where cell generation time is a random variable given by some distribution function, and the probability of cell division per unit time is a function only of cell age (not, for example, of cell mass). It is shown that there does not exist a stable mass distribution if the cells grow exponentially. In the case of linear growth, conditions for stability of the mass distribution are derived. To show these, the methods different from those considered up till now in the literature, are used. It is also shown that one can consider the cell mass growth as a linear dynamical system with a stochastic perturbation. The sister cell model as an improvement of the Transition Probability Model is derived. Statistical data are obtained for that model, and comparisons are made with some experimental data. As a verification tool, alpha and beta curves, are used.