淀粉微载体的制备及对CHO-K1细胞培养的初步应用

以普通市售马铃薯淀粉为原材料,在常温下利用W/O乳化方法制备了交联淀粉微球,并以二乙胺基乙基修饰了微球的表面电荷。同时研究了制备淀粉微球的制备工艺和改性工艺,成功制备了适合细胞培养用的淀粉微载体。利用扫描电镜(SEM)、红外(FT-IR)、X射线衍射仪(XRD)对微球进行了表征。结果表明,最佳制备条件为:淀粉溶液浓度为7%,搅拌速度为500 rpm,交联剂用量为8%,水油相体积比1∶6;微球表面修饰最佳条件为:加入微球质量2倍体积的3.5 mol/L NaOH溶液和2.5 mol/L DEAE-HCl溶液,60℃密闭反应4 h。对比Cytodex-1微载体,培养CHO-K1细胞至144 h时,淀粉微载体表面细胞密度达到1.8×10~6cells/mL,且两者培养效果相似,表明了自制淀粉微载体是一种潜在的贴壁细胞培养用高分子材料。     

两种微载体培养鼠肝细胞对低温保存后的影响

为了研究细胞培养方式对低温保存后细胞功能的影响,将大鼠肝细胞接种至两种不同微载体(实体微载体Cytodex、多孔微载体Cytopore),微重力高密度培养后于–80°C冻存(冻存速率是1°C/min,5%DMSO+0.4 mol/L山梨糖醇)。2周后复温细胞与载体材料,用显微镜观察细胞生长形态,计算细胞活力情况,并通过细胞代谢功能指标葡萄糖、白蛋白、尿素等的测定,反映细胞在两种载体培养和低温保存后的生长和代谢情况。结果表明,在细胞培养期间,Cytopore的MTT值、代谢指标值是Cytodex的1~1.5倍,低温保存后,Cytopore的各项指标与低温保存前差异不显著,而Cytodex的代谢指标差异显著。因此,大鼠肝细胞在微载体Cytopore的高密度培养及低温保存比Cytodex更有利于细胞的生长和代谢。     

一种新型蛋白类药物口服载体的海藻酸钠/巯基化果糖-壳聚糖复合水凝胶

壳聚糖经果糖修饰以改善其水溶性,再经半胱氨酸修饰得到巯基化果糖-壳聚糖。海藻酸钠与巯基化果糖-壳聚糖混合溶液经氯化钙及硫酸钠双重交联制得复合水凝胶珠。溶胀试验结果表明:该凝胶珠在pH值6.8及7.4时的溶胀率分别是pH值1.2时的7倍和10倍左右。牛血清白蛋白(BSA)包载试验结果表明:BSA重量为凝胶珠质量的20%时,包载率可达94%以上,随着巯基化果糖-壳聚糖在凝胶珠中比例增加,BSA包载率上升。BSA释放试验表明:pH值1.2时BSA的释放率很低,只有6%～10%的BSA从凝胶珠中释放出来,随后累积释放量基本不变;pH值6.8和pH值7.4时BSA的释放率迅速提高,因此这种复合水凝胶珠可作为一种潜在的口服蛋白类药物载体。     

昆虫杆状病毒载体的细胞培养和重组蛋白生产

利用杆状病毒载体和昆虫细胞生产重组蛋白的研究日益增多,本文就杆状病毒的宿主细胞种类、培养条件、大规模培养方法和虫体表达以及昆虫细胞对表达产物的翻译后修饰加工的研究现况进行了概述。     

纤维素多孔微载体的制备及其用于动物细胞培养

将纤维素铜氨溶液喷洒至-40℃的硅油：正己烷=1：4的冷冻液中形成含冰晶的微球,用-30℃、40%的H₂SO₄再生纤维素,并用EDAE盐酸盐修饰其表面,制成适合动物细胞培养的纤维素多孔微载体。利用该微载体培养能分泌尿激酶原(Pro-UK)的重组CHO细胞,在100mL搅拌瓶中换液培养25d,细胞最高密度为6.3×10⁶/mL,尿激酶原最高活性为2325IU/mL,共获28.7mg产品。之后转入1000mL搅拌瓶中培养,可观察到细胞可从种子微载体中自动转移到新微载体中生长繁殖直至所有微载体中都长有细胞。在25d二级培养中,细胞最高密度为7.3×10⁶/mL,尿激酶原最高活性为3108IU/mL,共获含353mg尿激酶原的上清13.7L。在培养后期换用无血清培养基培养,细胞生长及蛋白表达水平正常。     

细胞培养微载体及其在生物医药领域的应用

细胞培养微载体能为贴壁依赖性细胞提供超大的附着生长表面,是动物细胞大规模培养过程中的一种重要生物功能材料。由于不同应用领域对细胞微载体的要求略有差异,因此产品设计开发已成为细胞微载体培养技术成功应用的关键。该文从细胞微载体的开发设计与应用水平上进行了综述,以探讨细胞微载体培养技术的发展方向。     

VERO细胞生物反应器放大培养初探

目的:研究用生物反应器放大进行Vero细胞微载体培养,实现生物反应器之间Veto细胞放大培养.方法:5L微载体生物反应器以10g/L微载体浓度培养Vero细胞,96h时经漂洗、消化、接种于30L微载体生物反应器,实现放大后的30L微载体生物反应器细胞怏速增殖,期间对不同时期的微载体细胞进行细胞计数、细胞代谢分析和形态观察.结果:5L生物反应器细胞经过96h灌注培养,平均细胞密度达到7.81×10~6cells/mL.5L微载体细胞放大到30L微载体生物反应器,平均细胞收获率为32.3%;放大到30L生物反应器后经过144h培养,细胞密度达到9.19×10~6cells/mL;放大后的细胞代谢途径依然以葡萄糖氧化代谢乳酸为主.结论:生物反应器由5L到30L进行Veto细胞放大培养是可行的.     

微载体浓度与细胞接种密度对ST细胞生长的影响

选择合适的微载体浓度、细胞接种密度以提高微载体利用率,优化微载体培养体系猪睾丸细胞(Swine testicle cells)的贴附生长与维持。使用DMEM补加10%血清、LSM(Low serum medium)两种培养基考察微载体浓度、细胞接种密度对细胞生长维持的影响,进而比较ST细胞在不同条件下对Cytodex1微载体的利用率。结果显示,使用LSM在T150方瓶中连续传代培养30d,平均比生长速率为0.626d~(0-1),是DMEM补加10%FBS培养基的1.15倍。选择10×10~5cells/mL细胞接种3g/LCytodex1搅拌瓶体系,最大细胞密度为38.3×10~5cells/mL,微载体利用率上升到58.8%。在灌注培养体系中培养ST细胞15d,最终细胞密度达到36.6×10~5cells/mL,扩增了13.6倍。微载体悬浮培养的使用一方面有利于ST细胞的贴附与生长,实现高密度生长,另一方面增加了微载体的使用成本,选择合适的微载体浓度、细胞接种密度,能够最大化利用微载体与培养基中的营养物质实现细胞的最优生长。     

用慢病毒转染RNAi技术沉默胆固醇7α羟化酶的基因表达，降低肝细胞中胆汁酸的分泌

为了降低生物人工肝(bioartificial liver system)中肝细胞胆汁酸的分泌,构建了胆固醇7α羟化酶慢病毒RNA干涉载体,并转染人肝脏细胞(L-02).根据绿色荧光蛋白的表达评估转染效率后进行流式分选,获得高表达慢病毒干涉载体的细胞,并以野生型L-02细胞和仅转染pSicoR空载体的L-02细胞作对照,观察肝细胞胆固醇7α羟化酶的表达以及培养上清中总胆汁酸含量.利用半定量PCR、实时荧光定量PCR及Western-blot等实验方法检测了转染细胞中基因的干涉效果,结果显示:与对照组相比,在mRNA水平,转染慢病毒siRNA载体的L-02细胞,其胆固醇7α羟化酶基因的表达量仅为野生型L-02细胞表达量的31.2%,为转染pSicoR空载体的L-02细胞的34.1%,干涉效率分别为68.8%和65.9%,均具有显著差异(P＜0.05);Western-blot结果显示胆固醇7α羟化酶在蛋白质水平表达也明显受到抑制,表明转染慢病毒siRNA下调了肝细胞中胆固醇7α羟化酶基因的表达,减少了胆汁酸的分泌.以上研究结果表明,利用RNAi技术可以获得低表达胆固醇7α羟化酶基因的肝细胞,并有效降低肝细胞中胆汁酸的分泌,为临床上生物人工肝的构建及应用奠定基础.     

流加微载体半连续培养分泌HBsAg的rCHO细胞过程研究

本文在固定浓度微载体半连续培养rCHO细胞动力学研究的基础上,通过逐步补加新的微载体以不断提高供细胞生长的表面,提高了细胞密度和产物的表达量。建立了流加微载体半连续培养rCHO肿细胞收获HBsAg的工艺,确定了此种培养方式的最大微载体浓度,为建立微载体连续培养rCH0细胞生产HBsAg技术,实现细胞高密度和产物高表达奠定了基础。     

Chitosan nanofiber scaffold enhances hepatocyte adhesion and function

To enhance cell attachment and promote liver functions of hepatocytes cultured in bioreactors, a chitosan nanofiber scaffold was designed and prepared via electrospinning. Effects of the scaffold on hepatocyte adhesion, viability and function were then investigated. Data showed that hepatocytes on chitosan nanofiber scaffold exhibited better viability and tighter cell-substrate contact than cells on regular chitosan film. In addition, urea synthesis, albumin secretion and cytochrome P450 activity of hepatocytes on chitosan nanofiber scaffold were all 1.5 to 2 folds higher than the controls. Glycogen synthesis was also increased as compared with the controls. These results suggested the potential application of this chitosan nanofiber scaffold as a suitable substratum for hepatocyte culturing in bioreactors.     

Optimization of hepatocyte attachment to microcarriers: Importance of oxygen

Many potential applications of primary hepatocytes cultured on microcarriers, such as an artificial liver or hepatocyte transplantation, would benefit from having a large number of hepatocytes attached to each microcarrier. In addition, the supply of primary hepatocytes is usually limited, so the efficient utilization of hepatocytes during attachment to microcarriers is necessary. Several physical parameters involved in the attachment process have been investigated, and the number of cells attached per microcarrier and the fraction of hepatocytes which attach have been quantitatively monitored. Variation of the partial pressure of gas phase oxygen in the incubation flask produced significant effects on the attachment of hepatocytes to microcarriers, with higher partial pressures of oxygen found to be necessary for attachment. In addition, variation of fluid depth and cell number, both of which influence the partial pressure of oxygen at the cell surface, affected hepatocyte attachment. The partial pressure of oxygen at the cell surface as a function of the physical parameters was analyzed using a simple one-dimensional theoretical model. Variations in the cell-to-microcarrier ratio used for incubation indicate that a compromise must be made in terms of maximizing the number of cells per microcarrier and the fraction of total hepatocytes which attach. The maximum number of hepatocytes per microcarrier obtained in this work was approximately 100. The best attachment fraction, defined as the ratio of the number of hepatocytes attached to the total number added to the incubation, was approximately 90%. (c) 1993 John Wiley & Sons, Inc.     

Chitosan/gelatin composite microcarrier for hepatocyte culture

Solid and porous chitosan/gelatin (CG) composite microcarriers were prepared by a water-in-oil emulsion process with additional freezing and lyophilization. Adult rat hepatocytes (10(6) cells ml(-1)) attached on CG microcarriers maintained at least 15 d of viability and differentiated functions. Over 15 d, unimmobilized hepatocytes released 1.34-fold less lactate dehydrogenase (LDH), and retained 1.63-, 1.51- and 1.28-fold higher albumin secretion, urea synthesis and 7-ethoxycoumarin deethylation activities, respectively, than those on collagen-coated microcarriers. The CG matrix is therefore a promising microcarrier for hepatocyte culture.     

Long-Term continuous culture of hepatocytes in a packed-bed reactor utilizing porous resin

As part of our attempt to develop a hybrid artificial liver support system using cultured hepatocytes, we investigated the long-term metabolic function of hepatocytes incubated in a packed-bed type reactor using reticulated polyvinyl formal (PVF) resin as a supporting material. Long-term (up to 1 week) perfusion culture experiments using the packed-bed reactor (20 mm i.d.) loaded with 500 PVF resin cubes (mean pore size 250 mum, 2 x 2 x 2 mm), together with conventional monolayer culture experiments as controls, were performed in serum-free or serum-containing medium. Ammonium metabolism and urea synthesis activities were evaluated quantitatively based on reaction kinetic analyses. Initial rates of ammonium metabolism and urea-N synthesis, as well as GPT enzyme activities, were adopted as indexes of the metabolic performance of the reactor and activities of the cultured hepatocytes.When serum-free medium was used in the perfusion cultures, ammonium metabolic and urea-N synthetic rates showed significant decay with elapse of the culture period, being less than 10% of those measured on day 1. This loss of activity was more prominent in the perfusion culture than in the monolayer cultures using this medium. In contrast, when serum-containing medium was used, approximately 50% of these activities obtained on day 1 were maintained even at the end of the cultures both in the perfusion and monolayer culture experiments.We concluded that the packed-bed reactor using PVF resin enabled high-density culture of hepatocytes, and showed a satisfactory ability to maintain the metabolic function of immobilized hepatocytes for relatively long periods of up to 1 week. This type of reactor is thus considered to represent a breakthrough in overcoming the difficulties involved in the development of a hybridtype artificial liver support system. (c) 1994 John Wiley & Sons, Inc.     

Combined effects of direct current stimulation and immobilized BMP‐2 for enhancement of osteogenesis

Direct current (DC) stimulation has been used to promote bone repair and osteogenesis, but problems associated with the implanted metal electrodes may limit its application and compromise the therapeutic results. The replacement of the metal electrodes with a biodegradable conductive polymer film can potentially overcome these problems. In our work, polypyrrole/chitosan films comprising polypyrrole nanoparticles dispersed in a chitosan matrix were prepared. The polypyrrole/chitosan film meets the requirements for DC delivery, as indicated by its electrical conductivity, biodegradability, and mechanical properties. The film supports osteoblast growth to the same degree as dentine discs (a bone‐like mineralized substrate), confirming that it is non‐cytotoxic. Our results showed that optimal DC stimulation was achieved with 200 µA for 4 h per day, and under this condition, osteoblast metabolic activity on Day 7 increased by 1.8‐fold over that without DC stimulation. To further improve osteogenesis on the polypyrrole/chitosan film, bone morphogenetic protein‐2 (BMP‐2) was covalently immobilized on the film surface. Osteoblasts cultured on the BMP‐2‐functionalized polypyrrole/chitosan film and subjected to the optimal DC stimulation exhibited a significant increase in cellular metabolic activity (2.3‐fold on Day 7), ALP activity (1.7‐fold on Day 21) and mineralization (twofold on Day 21) over those cultured on polypyrrole/chitosan film without DC stimulation. Osteogenic gene expression results showed that BMP‐2 and DC stimulation by itself enhanced osteoblast differentiation, and a combination of these two factors resulted in synergistic effects on osteoblast differentiation and maturation. Biotechnol. Bioeng. 2013; 110: 1466–1475. © 2012 Wiley Periodicals, Inc.     

Microcalorimetric investigation of metabolism in rat hepatocytes cultured on microplates and in cell suspensions

In the present work, heat production rate in rat hepatocytes has been measured by use of thermopile heat conduction calorimeters. Both hepatocytes cultured in monolayers on microplates and hepatocytes in suspensions were used for microcalorimetric measurements. The highest heat production rate was found in newly cultured cells; thereafter, a gradual decrease was noted. After 1 day of culture, metabolic activity had reached a steady state that lasted about 4 days. A cell-density dependence of heat production was found, both in cell suspensions and in cultured hepatocytes on microplates. Higher cell concentration in the calorimeter ampoule was accompanied by decreasing heat production per cell. The heat output recorded for hepatocytes cultured on microplates (25 X 10(3) cells) was found to be 0.327 +/- 0.13 nW per cell after 24-48 h. Addition of sodium azide and sodium fluoride to tissue culture medium reduced heat production rate in cultured hepatocytes by 60 and 20%, respectively. Recording of heat production with the present calorimetric technique is relatively simple and fast, and offers the possibility to perform measurements in small samples of cultured hepatocytes on microplates, thus allowing long-term as well as repeated measurements on the same cell population.     

原代地鼠肾细胞及狂犬病毒不同培养方式的研究

目的通过比较原代地鼠肾细胞在转瓶、微载体、细胞工厂的3种培养方式的培养效果,为原代地鼠肾细胞选择一种易扩大规模、培养高质量细胞的培养方式,进而提高狂犬病毒的产量。方法消化取得的细胞悬液分别在转瓶、微载体、细胞工厂中培养,通过显微镜观察细胞形态、计数等结果比对培养的差别。结果细胞工厂可以很好地培养原代地鼠肾细胞和狂犬病毒;而细胞在微载体上贴附性差,生长不好。结论实验结果表明细胞工厂可以取代转瓶,用于大规模培养原代地鼠肾细胞扩大狂犬病毒的产量。     

Cultivation of immortalized human hepatocytes HepZ on macroporous CultiSpher G microcarriers

Cultivation of the new immortalized hepatocyte cell line HepZ was performed with a 1:1 mixture of DMEM and Ham's F12 media containing 5% FCS. The cells were grown in their 40th passage in 100 mL and 1 L volumes in spinner flasks and in a bioreactor, respectively. For the production of adherently growing HepZ cells macroporous CultiSpher G gelatin microcarriers were used in various concentrations from 1 to 3 g/L. The cells were seeded in a density of 2 x 10(5) cells/mL when using a microcarrier concentration of 1 g/L and 5 x 10(5) cells/mL at a microcarrier concentration of 3 g/L. After 7 days of cultivation a maximum cell concentration of 4.5 x 10(6) cells/mL was obtained in the spinner culture using a microcarrier concentration of 1 g/L. With bubble-free aeration and daily medium exchange from day 7, 7.1 x 10(6) cells/mL were achieved in the bioreactor using a microcarrier concentration of 3 g/L. The cells exhibited a maximum specific growth rate of 0.84 per day in the spinner system and 1.0 per day in the bioreactor, respectively. During the growth phase the lactate dehydrogenase (LDH) activity rose slightly up to values of 200 U/L. At the end of cultivation the macroporous carriers were completely filled with cells exhibiting a spherical morphology whereas the hepatocytes on the outer surface were flat-shaped. Concerning their metabolic activity the cells predominantly consumed glutamine and glucose. During the growth phase lactate was produced up to 19.3 mM in the spinner culture and up to 9.1 mM in the bioreactor. Maximal oxygen consumption was 1950 nmol/(10(6) cells. day). HepZ cells resisted a 4-day long chilling period at 9.5 degrees C. The cytochrome P450 system was challenged with a pulse of 7 microgram/mL lidocaine at a cell density of 4.5 x 10(6) cells/mL. Five ng/mL monoethylglycinexylidide (MEGX) was generated within 1 day without phenobarbital induction compared to 26 ng/mL after a preceded three day induction period with 50 microgram/mL of phenobarbital indicating hepatic potency. Thus, the new immortalized HepZ cell line, exhibiting primary metabolic functions and appropriate for a mass cell cultivation, suggests its application for a bioartificial liver support system.     

Derivation,characterization and expansion of fetal chondrocytes on different microcarriers

Fetal chondrocytes (FCs) have recently been identified as an alternative cell source for cartilage tissue engineering applications because of their partially chondrogenically differentiated phenotype and developmental plasticity. In this study, chondrocytes derived from fetal bovine cartilage were characterized and then cultured on commercially available Cytodex-1 and Biosilon microcarriers and thermosensitive poly(hydroxyethylmethacrylate)-poly(N-isopropylacrylamide) (PHEMA-PNIPAAm) beads produced by us. Growth kinetics of FCs were estimated by means of specific growth rate and metabolic activity assay. Cell detachment from thermosensitive microcarriers was induced by cold treatment at 4 °C for 20 min or enzymatic treatment was applied for the detachment of cells from Cytodex-1 and Biosilon. Although attachment efficiency and proliferation of FCs on PHEMA-PNIPAAm beads were lower than that of commercial Cytodex-1 and Biosilon microcarriers, these beads also supported growth of FCs. Detached cells from thermosensitive beads by cold induction exhibited a normal proliferative activity. Our results indicated that Cytodex-1 microcarrier was the most suitable material for the production of FCs in high capacity, however, ‘thermosensitive microcarrier model’ could be considered as an attractive solution to the process scale up for cartilage tissue engineering by improving surface characteristics of PHEMA-PNIPAAm beads.