immunotools重组人巨噬细胞集落刺激因子

 

immunotools重组人巨噬细胞集落刺激因子标准品系指用于生物检定、抗生素或生物药品中含量或效价测定的标准物质,以效价单位(U)表示。包括:化学计量标准品、药检标准品,中药标准品,Sigma标准品,usp标准品,化学标准品,进口标准品。对照品系指用于鉴别、检查、含量测定和校正检定仪器性能的标准物质.


immunotools重组人巨噬细胞集落刺激因子 血清,指血液凝固后,在血浆中除去纤维蛋白原分离出的淡黄色透明液体或指纤维蛋白原已被除去的血浆。其主要作用是提供基本营养物质、提供激素和各种生长因子、提供结合蛋白、提供促接触和伸展因子使细胞贴壁免受机械损伤、对培养中的细胞的起到某些保护作用。类别有胎牛血清immunotools重组人巨噬细胞集落刺激因子(现货)、透析型胎牛血清、天然低IGG胎牛血清 、干细胞培养胎牛血清 、特殊用途胎牛血清、活性炭/葡萄糖处理胎牛血清、胎牛血清替代物、小牛血清 、新生牛血清 、供体马血清 、兔血清 、鸡血清 、猪血清 、马血清 、其他动物血清 、合成血清替代品。


immunotools重组人巨噬细胞集落刺激因子实验仪器,是自然科学具体实验时用到的仪器,主要是物理学、化学、生物学使用仪器较多,是用以检出、测量、观察、计算各物理量、物质成分、物性参数等的器具或设备。仪器用途多种多样,在科学研究的实验室里、在医学研究和实践中仪器是非常重要的科研工具和装置.


                                                                                             

货号 品名 规格 品牌
11343384 rh MCP-1 20μg immunotools
21330701 anti-human cd70 100 μg in 100 μl immunotools
11343015 rh TNF-alpha 50μg immunotools
11340013 rh IL-1beta 10μg immunotools
12343016 rm TNF-alpha 100μg immunotools
11344170 Recombinant Human Eotaxin-2 (CCL24) 5ug immunotools
11343415 Recombinant Human Hepatocyte Growth Factor (rh HGF) 50µg immunotools
11343013 Recombinant Human Tumor Necrosis Factor-alpha 10ug immunotools


重组人肿瘤坏死因子α

(rh TNFα)

同义词:肿瘤坏死因子配体超家族成员2、恶病质、DIF、TNFSF2、坏死素、细胞毒素。

简介:肿瘤坏死因子是一种参与全身炎症的细胞因子,是一组刺激急性期反应的细胞因子之一。TNFalpha主要由巨噬细胞分泌。

TNFalpha导致凋亡细胞死亡、细胞增殖、分化、炎症、肿瘤发生和病毒复制,并参与脂质代谢和凝血。TNF的主要作用是调节免疫细胞。TNFalpha的失调,尤其是生产过剩,与多种人类疾病有关——自身免疫性疾病、胰岛素抵抗和癌症。

说明:在大肠杆菌中产生的重组人TNF-α是一条单一的非糖基化多肽链,包含158个氨基酸,分子量为17483.77道尔顿。rh-TNF-α通过标准色谱技术纯化。

来源:大肠杆菌

外观:无菌过滤白色冻干(冻干)粉末。

配方:从0.2µm过滤溶液中加入含有200mM NACl的25mM乙酸钠(pH 6.5)进行冻干。

1µg的等份含有5%(w/vol)的海藻糖,以便更好地回收。

溶解度:建议在不小于100µg/ml的无菌H2O中重新配制冻干rh TNFα,然后再将其稀释到其他水溶液中。

稳定性:冻干的rh-TNF-α虽然在室温下稳定3周,但应在-18°C以下干燥保存。重组后,rh-TNF-α应在2-7天之间在4°C下保存,以备将来在-18°C以下使用。对于长期保存,建议添加载体蛋白(0.1%HSA或BSA)。

请防止冻融循环。

纯度:SDS-PAGE测定大于98.0%。

氨基酸序列:测定前五个N端氨基酸的序列,发现其符合Val-Arg-Ser-Ser。

内毒素:LAL法测定的内毒素水平小于1 EU/µg

生物活性:放线菌素存在下小鼠L929细胞的细胞裂解测定的ED50<0.05 ng/ml,对应于

比活度为2 x 107 IU/mg。

本材料仅供研究使用。不用于人体。仅供体外使用。ImmunoTools将不对

i负责

 

使用我们的产品时可能发生的侵权或其他违规行为。


small 10 µg Cat.N° 11343013

medium 50 µg Cat.N° 11343015

large 250 µg Cat.N° 11343017

x- large 1000 µg Cat.N° 11343018


 

nkmaxbio VIS0702说明书

nkmaxbio VIS0702说明书

 

重组小鼠PBEF / Visfatin蛋白

猫号
VIS0702

尺寸

数量

价格表

20微克

  

105美元

100微克

  

320美元

500微克

  

960美元

 

产品类别
重组蛋白
表达系统
大肠杆菌
1-491aa
UniProt号
Q99KQ4
NCBI登记号
NP_067499
替代名称
B细胞集落前增强因子1,B细胞集落前增强因子1,Visfatin,visfatin小鼠,小鼠visfatin,烟酰胺磷酸核糖基转移酶[Mus musculus],B细胞前集落增强因子1
  • 产品信息
  • 产品规格书
  • 数据

产品规格书

分子量
MALDI-TOF确认57.6 kDa(511aa)
浓度
1mg / ml(通过Bradford测定法测定)
公式
液体中磷酸盐缓冲盐水(pH 7.4)
纯度
> 90%通过SDS-PAGE
内毒素
每1ug蛋白质<1 EU(通过LAL方法测定)
标签
他的标签
应用领域
SDS页面
存储
可以在+ 2C至+ 8C的温度下保存1周。对于长期存储,请分装并存储在-20C至-80C之间。避免重复冷冻和解冻循环。
  • 产品信息
  • 产品规格书
  • 数据

数据

SDS页面

在还原条件下通过SDS-PAGE 3ug,并通过考马斯亮蓝染色显现。

注意:仅供研究使用。该产品不适用于或用于人类,诊断或兽医用途。

 

PrimeSurface 低吸附细胞培养板 PrimeSurface 35mm dish

PrimeSurface 低吸附细胞培养板
PrimeSurface 35mm dish

  • 产品特性
  • 相关资料
  • Q&A
  • 参考文献

PrimeSurface 低吸附细胞培养板                              PrimeSurface 35mm dish低吸附相关试剂

PrimeSurface 低吸附细胞培养板



PrimeSurface® 是采用 sumiron 公司的低吸附蛋白质处理产品(Proteosave® SS)的技术制成的低吸附细胞处理产品。使用该容器培养细胞更容易形成细胞球集落。

◆特长


● 能够简单地形成细胞集落

      将细胞播种在96、384多孔板中,静置培养就能简单地得到细胞集落。 

● 细胞集落大小均一 

      抑制细胞吸附在培养面,集落的形成率得到了提高,能够在细胞形态平整、均一的状态下培养。

● 适用于细胞分化的研究 

      能够将ES细胞变成胚叶体(EB体)后直接添加分化诱导试剂 。

● 适合用于使用细胞球进行抗癌剂的筛选 

      进行3D培养,与常规的单层培养相比培养环境更加接近生物体。


PrimeSurface 低吸附细胞培养板                              PrimeSurface 35mm dish



◆用途


用于再生医疗和药物研发中

 


◆细胞培养

 

●    ES细胞·IPS细胞·骨髓间充质干细胞的分化诱导

●    使用细胞的3D模型进行药物研发筛选

 


◆产品概要

产品编号

产品名称

规格

培养面积

容量

包装

MS-9035XZ

PrimeSurface® 培养皿35mm

外寸35Φ×14(H)mm

9 cm2

5包·50/case

MS-9060XZ

PrimeSurface® 培养皿60mm

外寸60Φ×15(H)mm

21 cm2

10包·100/case

MS-9090XZ

PrimeSurface® 培养皿90mm

外寸90Φ×20(H)mm

57 cm2

10包·50/case

MS-9024XZ

 Sumiron Celltight 板24F

24孔·平底

1.8 cm2 

3.4 mL/well

1包·10/case


注:已进行放射线灭菌  保存温度:室温 有效期:制造后两年

 


产品编号

产品名称

孔数

孔底形状

容量

包装

MS-9384UZ

PrimeSurface® 384U多孔板

384

U底

0.1 mL

1/包・20/case

MS-9384WZ

PrimeSurface® 384U白色多孔板

384

U底

0.1 mL

1/包・20/case

MS-9096VZ

PrimeSurface® 96V多孔板

96

V底

0.3 mL

1/包・20/case

MS-9096MZ

PrimeSurface® 96M多孔板

96

纺锤底

0.2 mL

1/包・20/case

MS-9096UZ

PrimeSurface® 96U多孔板

96

U底

0.3 mL

1/包・20/case

MS-9096WZ

PrimeSurface® 96U白色多孔板

96

U底

0.3 mL

1/包・20/case


注:已进行放射线灭菌  保存温度:室温  有效期:制造后两年


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◆实验例子


在用球体制作工程构建三维结构体时使用了 Cyfuse 的生物3D打印机 Regenova®

Regenova® 是先进的机器人系统之一,它通过将球体固定在剑山,再按照3D设计制作出三维结构体。下面为大家介绍使用了该系统的神经三维结构体和使用了间充质干细胞的三维结构体的实验例子。


神经三维结构体


使用细胞:人iPSC来源神经前驱细胞

播种数:4×104 cells/well

培养基:神经细胞用培养基

培养板培养天数:2天

制作出的三维结构体的形状、尺寸:3×3×2

用于三维结构体的细胞块个数:18个

积层后的培养天数:9天后拔出剑山


PrimeSurface 低吸附细胞培养板                              PrimeSurface 35mm dish

PrimeSurface 低吸附细胞培养板                              PrimeSurface 35mm dish

PrimeSurface 低吸附细胞培养板                              PrimeSurface 35mm dish

细胞块

3D打印后

拔出剑山后的三维结构体

使用间充质干细胞的三维结构体


使用细胞:人脂肪组织来源间充质干细胞

播种数:5×103 cells/well

培养基:间充质干细胞用培养基

培养板培养天数:2天

制作出的三维结构体的形状、尺寸:用48个细胞块组成环状×10层

用于三维结构体的细胞块个数:480个

积层后的培养天数:6天后拔出剑山


PrimeSurface 低吸附细胞培养板                              PrimeSurface 35mm dish

PrimeSurface 低吸附细胞培养板                              PrimeSurface 35mm dish

PrimeSurface 低吸附细胞培养板                              PrimeSurface 35mm dish

PrimeSurface 低吸附细胞培养板                              PrimeSurface 35mm dish

细胞块

3D打印后(上面)

3D打印后(侧面)

拔出剑山后

 


使用 PrimeSurface® 96U 多孔板的培养例子


小鼠ES细胞培养

 

播种数:750 cells/well
培养基:DMEM+4.5 mg/mL Glc.
添加物:15%灭活 FCS
              2 mM L-谷氨酰胺
              1%非必须氨基酸
              110 μM 2-巯基乙醇  
培养日数:3日

PrimeSurface 低吸附细胞培养板                              PrimeSurface 35mm dish

没有细胞吸附在 PrimeSurface® 96U 多孔板上,也没有凌乱的细胞集落,已经形成均一。

PrimeSurface 低吸附细胞培养板                              PrimeSurface 35mm dish

一般市面上贩卖的漂浮培养用多孔板,细胞紧密粘附或者死亡。

使用PrimeSurface® 96U多孔板的细胞分化诱导实验例子


使用PrimeSurface® MS-9096V将人ES细胞集落导入自身组织化神经网膜组织

 

培养器:PrimeSurface® MS-9096V

使用细胞:人ES(KhES-1株)

播种密度:9000 cells/well

使用培养基:GMEM+KSR+NEAA+2ME+ 20uM Y-27632

培养条件:5% CO2,37℃


PrimeSurface 低吸附细胞培养板                              PrimeSurface 35mm dish


【数据提供】

・照片a)~c) 

 理化学研究所 发生与再生科学综合研究中心 干细胞研究支援开发室

 

【参考文献】

・Self-Formation of Optic Cups and Storable Stratified Neural Retina from Human ESCs

 NakanoT, Ando S, Takata N, Kawada M, Muguruma K, Sekiguchi K, Saito K, Yonemura S, Eiraku M, Sasai Y

 Cell Stem Cell, 10 (6), 771-785 (2012)

 


使用PrimeSurface® 进行抗癌药药效测试实验


细胞:MCF-7(人乳腺癌细胞)

试剂:5-Fluorouracil(5-FU)


PrimeSurface 低吸附细胞培养板                              PrimeSurface 35mm dish


【数据提供】

・近畿大学医学部 基因组生物学教室 西尾研究室



在小鼠 ES 细胞形成球体引起心肌细胞分化的过程中使用 DS Pharma Biomedical 的心肌分化毒性(发生毒性)评价试剂盒。


POCA® Hand1-EST


POCA® Hand1-EST 是一种使用 PrimeSurface,在待测物存在下的培养中将检测小鼠ES细胞的心肌分化是否正常作为标记基因活性的指标的方法。

 

使用细胞:小鼠ES细胞(Hand1-ES细胞)

播种数:750 cells/well

培养基:心肌分化培养基

培养板培养天数:5天


PrimeSurface 低吸附细胞培养板                              PrimeSurface 35mm dish

研究领域

使用型号

参考文献

视网膜

研究

MS-9096V

KUWAHARA, Atsushi, et al. Generation of a ciliary margin-like stem cell niche from self-organizing human retinal tissue. Nature communications, 2015, 6.: 1-15

MS-9096V

TANAKA, T., et al. Generation of retinal ganglion cells with functional axons from human induced pluripotent stem cells. Sci Rep, 2015, 5. 8344.

MS-9096U

EIRAKU, Mototsugu and SASAI, Yoshiki Mouse embryonic stem cell culture for generation of three-dimensional retinal and cortical tissues. Nature protocols,

2012, 7. 1: 69-79. 

MS-9096V

NAKANO, Tokushige, et al. Self-Formation of Optic Cups and Storable Stratified Neural Retina from Human ESCs. Cell Stem Cell, 2012, 10. 6: 771-785.

 MS-9096V

GAO, Lixiong, et al. Intermittent high oxygen influences the formation of neural retinal tissue from human embryonic stem cells.Scientific Reports, 2016, 6.

神经科学

研究

MS-9096V

MUGURUMA, Keiko, et al. Self-Organization of Polarized Cerebellar Tissue in 3D Culture of Human Pluripotent Stem Cells. Cell Reports, 2015, 10:537-550

MS-9096V

BAMBA, Y., et al. Differentiation, polarization, and migration of human induced pluripotent stem cell-derived neural progenitor cells co-cultured with a human glial cell   line with radial glial-like characteristics. Biochem Biophys Res Commun,   2014, 447. 4: 683-688. 

MS-9096 U, M or V

MINAMINO, Yuki, et al. Isolation and Propagation of Neural Crest Stem Cells from Mouse Embryonic Stem Cells via Cranial Neurospheres. Stem cells and development, 2014, 24.2:   172-181

MS-9096V

KADOSHIMA, T., et al. Self-organization of axial polarity, inside-out layer pattern, and species-specific progenitor dynamics in human ES cell-derived neocortex. Proceedings of the National Academy of Sciences of the United States of   America, 2013, 110. 50: 20284-20289. 

MS-9096 U, M or V

OGAWA, Yasuhiro, et al. Impaired neural differentiation of induced pluripotent stem cells generated from a mouse model of Sandhoff disease. PLoS ONE, 2013, 8. 1: e55856.

MS-9035X

GOMI, Masanori, et al. Functional recovery of the murine brain ischemia model using human induced pluripotent stem cell-derived telencephalic progenitors. Brain research, 2012, 1459. 52-60. 

MS-9096 U, M or V

NASU, Makoto, et al. Robust formation and maintenance of continuous stratified cortical   neuroepithelium by laminin-containing matrix in mouse ES cell culture. PLoS ONE, 2012, 7. 12: e53024.

MS-9096 U

DANJO, T., et al. Subregional specification of embryonic stem cell-derived ventral telencephalic tissues by timed and combinatory treatment with extrinsic signals. The Journal of neuroscience : the official journal of the Society   for Neuroscience, 2011, 31. 5: 1919-1933.

MS-9096 U

KANEMURA, Yonehiro Development of cell-processing systems for human stem cells (neural stem cells, mesenchymal stem cells, and iPS cells) for regenerative medicine. The   Keio journal of medicine, 2010, 59. 2: 35-45.

MS-9096 U, M or V

MS-9035X, MS-9060X

or

MS-9090X

FUKUSUMI, Hayato, et al. (2016). Establishment of human neural progenitor cells from human induced pluripotent stem cells with diverse tissue. Stem cells international: 1-10.

 MS-9096 U, M or V

RAASCH, Martin, et al. (2016). An integrative microfluidically supported in vitro model of an endothelial barrier combined with cortical spheroids simulates effects of neuroinflammation in neocortex development. Biomicrofluidics. 10: 044102.

MS-9096 M

ISODA, Miho, et al. (2016). Robust production of human neural cells by establishing neuroepithelial-like stem cells from peripheral blood mononuclear cell-derived feeder-free iPSCs under xeno-free conditions. Neuroscienc   Research.

MS-9035X, MS-9060X

or

MS-9090X

BAMBA, Yohei, et al. (2016). In vitro characterization of neurite extension using induced pluripotent stem cells derived from lissencephaly patients with TUBA1A missense mutations. Molecular brain.

MS-9096V

SAKAGUCHI, Hideya, et al. (2015). Generation of functional hippocampal neurons from self-organizing human embryonic stem cell-derived dorsomedial telencephalic tissue. Nature communications. 6: 1-11.

MS-9096V

MUGURUMA, Keiko, et al. Self-Organization of Polarized Cerebellar Tissue in 3D Culture of Human Pluripotent Stem Cells. Cell Reports, 2015, 10:537-550

KAMIYA, Daisuke, et al. Intrinsic transition of embryonic stem-cell differentiation into neural progenitors. Nature, 2011, 470. 7335: 503-509.

心肌细胞

研究和心脏研究

MS-9096V

TAKASHIMA, Yasuhiro, et al. Resetting transcription factor control circuitry toward ground-state pluripotency in human. Cell, 2014, 158. 6: 1254-1269.

MS-9035X

OTSUJI, Tomomi G, et al. Dynamic link between histone H3 acetylation and an increase in the functional characteristics of human ESC/iPSC-derived cardiomyocytes. PLoS ONE, 2012, 7. 9: e45010.

MS-9096U

SATOSHI, Yasuda, et al. AW551984: a novel regulator of cardiomyogenesis in pluripotent embryonic cells. Biochemical Journal, 2011, 437. 2: 345-355.

MS-9096U

YASUDA, S., et al. A novel regulator of cardiomyogenesis in pluripotent embryonic cells. The Biochemical journal, 2011, 437. 2: 345-355.

MS-9096U

OTSUJI, Tomomi G, et al. Progressive maturation in contracting cardiomyocytes derived from human embryonic stem cells: Qualitative effects on electrophysiological responses to drugs. Stem cell research, 2010, 4. 3: 201-213.

MS-9035X, MS-9060X or MS-9090X

YAMAUCHI, Kaori, et al. Cardiomyocytes develop from anterior primitive streak cells induced by β‐catenin activation and the blockage of BMP signaling in hESCs. Genes to Cells, 2010, 15. 12: 1216-1227.

MS-9096V

GUO, Ge, et al. (2016). Naive pluripotent stem cells derived directly from isolated cells of the human innercell mass. Stem Cell Reports. 6: 437-446.

MS-9096 U

 MS-9035X, MS-9060X

or

MS-9090X

NOGUCHI, Ryo, et al. (2016). Development of a three-dimensional pre-vascularized scaffold-freecontractile cardiac patch for treating heart disease. The Journal of Heart and Lung Transplantation. 35: 137-145.

 MS-9096

NOGUCHI, Ryo, et al. Development of a Three-Dimensional Prevascularized Scaffold-Free Contractile Cardiac Patch for Treating Heart Disease. The Journal of Heart and Lung Transplantation, 2015,

肝细胞

研究

MS-9096 U, M or V

ISHII, Takamichi (2012).   Differentiation of Human Embryonic Stem Cells into Functional Hepatocyte-Like Cells (Method). Stem Cells and Cancer Stem Cells, Volume 2, Springer:   43-49. 

MS-9096 U, M or V

ISHII, Takamichi et al. (2012). Hepatic Maturation of hES Cells by Using a Murine Mesenchymal Cell Line Derived from Fetal Livers.Human Embryonic and Induced Pluripotent Stem Cells, Springer: 397-403.

MS-9096U

ISHII, Takamichi, et al. In vitro hepatic maturation of human embryonic stem cells by using a mesenchymal cell line derived from murine fetal livers. Cell and tissue research, 2010, 339. 3: 505-512. 

MS-9096U

YANAGIDA, Ayaka, et al. Liver maturation deficiency in p57 Kip2-/-mice occurs in a hepatocytic p57 Kip2 expression-independent manner. Developmental biology, 2015,

牙科

研究

MS-9035X, MS-9060X or MS-9090X

OZEKI, Nobuaki, et al. Differentiation of Human Skeletal Muscle Stem Cells into Odontoblasts Is Dependent on Induction of α1 Integrin Expression.Journal of Biological Chemistry, 2014, 289. 20: 14380-14391.

MS-9096 U, M or V

YAMAMOTO, Mioko, et al. Three-dimensional spheroid culture promotes odonto/osteoblastic differentiation of dental pulp cells.Archives of oral biology, 2014, 59. 3: 310-317.

生精小管

研究

MS-9096V

YOKONISHI, T., et al. In Vitro Reconstruction of Mouse Seminiferous Tubules Supporting Germ Cell Differentiation. Biol Reprod, 2013, 89. (1):15: 1–6.

iPS细胞

生成

MS-9035X

OHNISHI, Hiroe, et al. A comparative study of induced pluripotent stem cells generated from frozen, stocked bone marrow‐and adipose tissue‐derived mesenchymal stem cells. Journal of tissue engineering and regenerative medicine, 2012, 6. 4: 261-271. 1. 

MS-9035X

AOKI, T., et al. Generation of induced pluripotent stem cells from human adipose-derived stem cells without c-MYC. Tissue engineering. Part A, 2010, 16. 7: 2197-2206.

MS-9035X, MS-9060X or MS-9090X

ODA, Y., et al. Induction of pluripotent stem cells from human third molar mesenchymal stromal cells. J Biol Chem, 2010, 285. 38: 29270-29278.

OHNISHI, Hiroe, et al. Generation of Xeroderma Pigmentosum-A Patient-Derived Induced Pluripotent Stem Cell Line for Use As Future Disease Model. Cellular Reprogramming (Formerly" Cloning and Stem Cells"), 2015, 17. 4: 268-274.

EST(胚胎干细胞试验)

MS-9096W

SUZUKI, N., et al. Evaluation of novel high-throughput embryonic stem cell tests with new molecular markers for screening embryotoxic chemicals in vitro. Toxicological sciences : an official journal of the Society of Toxicology, 2011, 124. 2: 460-471.

MS-9096U

NAGAHORI, H., et al. (2016). Prediction of in vivo developmental toxicity by combination of Hand1-Luc embryonic stem cell test and metabolic stability test with clarification of metabolically inapplicable candidates. Toxicol Lett. 259: 44-51.

 MS-9096U

YU, Ruoxing, et al. (2015). A Modified Murine Embryonic Stem Cell Test for Evaluating the Teratogenic Effects of Drugs on Early Embryogenesis. PLoS ONE. 10: e0145286.

MS-9096W

COZ, Florian Le, et al. (2015). Hand1-Luc Embryonic Stem Cell Test (Hand1-Luc EST): A novel rapid and highly reproducible in vitro test for embryotoxicity by measuring cytotoxicity and differentiation toxicity using engineered mouse ES cells. The Journal of Toxicological Sciences. 40: 251-261.

骨和软骨研究

MS-9096 U

HINO, Kyosuke, et al. (2015). Neofunction of ACVR1 in fibrodysplasia ossificans progressiva. Proceedings ofthe National Academy of Sciences. 112: 15438-15443.

MS-9096 U, M or V

MURATA, Daiki, et al. A preliminary study of osteochondral regeneration using a  scaffold-free threedimensional construct of porcine adipose tissue-derived mesenchymal stem cells. Journal of orthopaedic surgery and research, 2015, 10. 1: 1-12.

 MS-9096 U, M or V

FUJIMOTO, Mai, et al. Establishment of a novel model of chondrogenesis using murine embryonic stem cells carrying fibrodysplasia ossificans progressiva-associated mutant ALK2. Biochemical and Biophysical Research Communications,

2014, 455. 3: 347-352. 1.

MS-9096 U

ISHIHARA, Kohei, et al. Simultaneous regeneration of full-thickness cartilage and subchondral bone defects in vivo using a three-dimensional scaffold-free autologous construct derived from high-density bone marrow-derived mesenchymal stem cells. J Orthop Surg Res, 2014, 9. 1: 98. 1.

血管

研究

 MS-9096 U

MS-9035X, MS-9060X

or

MS-9090X

KAGEYAMA, Tatsuto, et al. (2016). In situ crosslinkable gelatin-CMC hydrogels designed for rapid engineering of perfusable vasculatures. ACS Biomaterials Science & Engineering.

MS-9096U

ITOH, M., et al. Scaffold-Free Tubular Tissues Created by a Bio-3D Printer Undergo Remodeling and Endothelialization when Implanted in Rat Aortae.PLoS ONE,

2015, 10. 9: e0136681.

胰岛细胞移植

MS-9096 U

NAKAMURA, Kentaro, et al. (2016). Introduction to a new cell transplantation platform via recombinant peptide petaloid pieces and its application to islet transplantation with mesenchymal stem cells. Transplant International. 29: 1039-1050.

骨髓

研究

 MS-9096 U

SAYO, Kanae, et al. (2016). Fabrication of bone marrow-like tissue in vitro from dispersed-state bone marrow cells. Regenerative Therapy. 3: 32-37.

其它

MS-9035X, MS-9060X

or

MS-9090X

ITO, Yoshitaka, et al. (2015). Establishment of Tsc2deficient rat embryonic stem cells. International journal of oncology. 46: 1944-1952.

 MS-9096 U, M or V

OGAWA, Yasuhiro, et al. (2015). Induced Pluripotent Stem Cells Generated from P0-Cre; Z/EG Transgenic Mice. PLoS ONE. 10: e0138620.

MS-9096U

IMAI, Hiroyuki, et al. Tetraploid Embryonic Stem Cells Maintain Pluripotency and Differentiation Potency into Three Germ Layers. PLoS ONE, 2015, 10. 6: e0130585.

MS-9096U, MS-9096M

or

MS-9096V

MITSUI, Kaoru, et al. Conditionally replicating adenovirus prevents pluripotent stem cell–derived teratoma by specifically eliminating undifferentiated cells. Molecular Therapy. Methods & Clinical Development, 2015, 2. 15026.

MS-9096U

ZHOU, Yuanshu, et al. Metabolic suppression during mesodermal differentiation of embryonic stem cells identified by single-cell comprehensive gene expression analysis. Molecular BioSystems, 2015, 11. 9: 2560-2567.

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Tissue Penetration in 3D Cell Culture Models of Ovarian Cancer Residual Disease. Molecular pharmaceutics. 12: 3973-3985.

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PrimSurface® 其他领域参考文献

1.

TAKASHIMA,   Yasuhiro, et al. Resetting transcription factor control circuitry toward   ground-state pluripotency in human. Cell, 2014, 158. 6: 1254-1269.   [MS-9096V]

2.

KIMURA,   Kenichi, et al. The Role of CCL5 in the Ability of Adipose Tissue-Derived   Mesenchymal Stem Cells to Support Repair of Ischemic Regions. Stem cells and development, 2013, 23. 5: 488-501. [MS-9096U]

3.

SHIMOTO,   Takeshi, et al. (2013). Bio Rapid Prototyping Project: Development of   Spheroid Formation System for Regenerative Medicine. Information Technology Convergence,   Springer: 855-862. [MS-9096 U, M or V]

4.

KOIDE,   Naoshi, et al. Establishment and optimal culture conditions of   microRNA-induced pluripotent stem cells generated from HEK293 cells via   transfection of microRNA-302s expression vector. Nagoya journal of medical science,   2012, 74. 1-2: 157-165. [MS-9096 U, M or V]

5.

MARKS, H., et al. The transcriptional and epigenomic foundations of ground state   pluripotency. Cell, 2012, 149. 3: 590-604. [MS-9096U]

6.

OHNISHI,   Hiroe, et al. (2012). Human Mesenchymal Stem Cells and iPS Cells (Preparation   Methods). Human Embryonic   and Induced Pluripotent Stem Cells, Springer:   173-190. [MS-9035X, MS-9060X or MS-9090X]

7.

SAKAI,   Yusuke, et al. Embryoid body culture of mouse embryonic stem cells using   microwell and micropatterned chips. Journal of bioscience and bioengineering, 2011, 111. 1: 85-91. [MS-9096U]

8.

TAKAYAMA,   Yuzo, et al. Toward the Precise Control of Cell Differentiation Processes by   Using Micro and Soft Lithography. 2011, [MS-9096 U, M or V]

9.

TAKAYAMA,   Yuzo, et al. Simultaneous induction of calcium transients in embryoid bodies   using microfabricated electrode substrates. Journal of bioscience and bioengineering, 2011, 112. 6: 624-629. [MS-9096U]

10.  

TANASIJEVIC,   Borko and RASMUSSEN, Theodore P X chromosome inactivation and differentiation   occur readily in ES cells doubly-deficient for macroH2A1 and macroH2A2. PLoS ONE, 2011, 6. 6: e21512. [MS-9096U]

11.

KATAOKA,   Ken, et al. Internalization of REIC/Dkk-3 protein by induced pluripotent stem   cell-derived embryoid bodies and extra-embryonic tissues. Int J Mol Med, 2010, 26. 6: 853-859.   [MS-9096U]

12.

TAKAYAMA,   Yuzo, et al. (2009). Ensemble   stimulation of embryoid bodies using microfabricated ITO substrates. Engineering in Medicine and Biology Society, 2009. EMBC 2009.   Annual International Conference of the IEEE, IEEE. [MS-9096U]

13.

TAKAYAMA,   Yuzo, et al. Ensemble Stimulation of Embryoid Bodies using Substrate‐Embedded   Electrodes. IEEJ   Transactions on Electrical and Electronic Engineering, 2009, 4. 6: 734-735. [MS-9096U]

14.

ICHIOKA, Masayuki, et al. Dienogest, a synthetic progestin, down-regulates expression of CYP19A1 and inflammatory and neuroangiogenesis factors through progesterone receptor isoforms A and B in endometriotic cells. The Journal of steroid biochemistry and molecular biology, 2015, 147. 103-110.

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MORI, Taisuke, et al. Dienogest reduces HSD17β1 expression and activity in endometriosis. Journal of Endocrinology, 2015, 225. 2: 69-76. PARSONS, Matthew W, et al. Dectin-2 Regulates the Effector Phase of House Dust Mite–Elicited Pulmonary Inflammation Independently from Its Role in Sensitization. The Journal of Immunology, 2014, 192. 4: 13611371.

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BRESLIN, Susan and O’DRISCOLL, Lorraine Three-dimensional cell culture: the missing link in drug discovery. Drug Discovery Today, 2013, 18. 5: 240-249.

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BARRETT, Nora A, et al. Cysteinyl leukotriene 2 receptor on dendritic cells negatively regulates liganddependent allergic pulmonary inflammation. The Journal of Immunology, 2012, 189. 9: 4556-4565.

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MASUDA, Taisuke, et al. A microfabricated platform to form three-dimensional toroidal multicellular aggregate. Biomedical microdevices, 2012, 14. 6: 1085-1093.

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SOMA, Tsutomu, et al. Hair-inducing ability of human dermal papilla cells cultured under Wnt/β-catenin signalling activation. Experimental dermatology, 2012, 21. 4: 307-309.

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YAMANAKA, Kaoruko, et al. Dienogest inhibits aromatase and cyclooxygenase-2 expression and prostaglandin E2 production in human endometriotic stromal cells in spheroid culture. Fertil Steril, 2012, 97. 2: 477-482.

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BRENNAN, Patrick J, et al. Invariant natural killer T cells recognize lipid self antigen induced by microbial danger signals. Nature immunology, 2011, 12. 12: 1202-1211.

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YOSHIIKE, Yuka and KITAOKA, Takuya Tailoring hybrid glyco-nanolayers composed of chitohexaose and cellohexaose for cell culture applications. Journal of Materials Chemistry, 2011, 21. 30: 11150-11158.

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MAEKAWA, Akiko, et al. GPR17 regulates immune pulmonary inflammation induced by house dust mites. The Journal of Immunology, 2010, 185. 3: 1846-1854.

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TAMADA, Atsushi, et al. Autonomous right-screw rotation of growth cone filopodia drives neurite turning. The Journal of Cell Biology, 2010, 188. 3: 429-441.

25.

IJIMA, Hiroyuki, et al. Composition of culture medium is more important than co-culture with hepatic nonparenchymal cells in albumin production activity of primary rat hepatocytes, and the effect was enhanced by hepatocytes spheroid culture in collagen gel. BIOCHEMICAL ENGINEERING JOURNAL, 2009, 45. 3: 226231.

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ITO, Michiko and TAGUCHI, Tetsushi Enhanced insulin secretion of physically crosslinked pancreatic β-cells by using a poly (ethylene glycol) derivative with oleyl groups. Acta Biomater, 2009, 5. 8: 2945-2952. KATAOKA, M, et al. Detection of biomarker for periodontal disease using a microchip.2008, 

2018年的参考文献 (46)

1.

K. Tsuji-Tamura, et al, Dual inhibition of mTORC1 and mTORC2 perturbs cytoskeletal organization andimpairs endothelial cell elongation. Biochemical and Biophysical Research Communications, 2018, 497.1.:326-331  [MS-9096U]

2.

R. Akizukia, et al, Decrease in paracellular permeability and chemosensitivity to doxorubicin by claudin-1 in spheroid culture models of human lung adenocarcinoma A549 cells. Biochimica et Biophysica Acta (BBA) -Molecular Cell Research, 2018, 1865.5.:769-780 [MS-9096U]

3.

E. C. Costa, et al, Spheroids Formation on Non‐Adhesive Surfaces by Liquid Overlay Technique: Considerations and Practical Approaches. Biotechnology Journal (Special Issue: Biotech Methods and Advances), 2018, 13.1 [MS-9096U

4.

Y Fukuda-Takami, et el, Layer-by-layer cell coating technique using extracellular matrix facilitates rapid fabrication and function of pancreatic β-cell spheroids. Biomaterials. 2018, 160.:82-91 [MS-9096U]

5.

R. Maruhashia, et el, Elevation of sensitivity to anticancer agents of human lung adenocarcinoma A549 cells by knockdown of claudin-2 expression in monolayer and spheroid culture models. Biochimica et Biophysica Acta (BBA) – Molecular Cell Research, 2018, 1865.3.:470-479 [MS-9096U]

6.

J. Terashima, The regulation mechanism of AhR activated by benzo[a]pyrene for CYP expression are different between 2D and 3D culture of human lung cancer cells. Drug Metabolism and Pharmacokinetics, 2018 [MS-9096V]

7.

H. Yamamoto, et el, Characterization of genetically engineered mouse hepatoma cells with inducible liver functions by overexpression of liver-enriched transcription factors. Journal of Bioscience and Bioengineering, 2018, 125.1.:131-139  [ MS-9096 U, M or V ]

8.

S. Sai, et el, Effects of carbon ion beam alone or in combination with cisplatin on malignant mesotheliomacells in vitro. Oncotarget, 2018, 9.19.:14849-1486 [MS-9096U]

9.

E. Takada, et el, Reproduction of Characteristics of Extracellular Matrices in Specific Longitudinal Depth ZoneCartilage within Spherical Organoids in Response to Changes in Osmotic Pressure. International Journal ofMedical Sciences, 2018, 19.5.:1507 [MS-9096U]

10.

D. Murata, Osteochondral Regeneration with a Scaffold-Free Three-Dimensional Construct of AdiposeTissue-Derived Mesenchymal Stromal Cells in Pigs. Tissue Engineering and Regenerative Medicine, 2018,15.1.:101-113 [MS-9096U]

11.

F, Chisa Yoshimuraa, et el, Spontaneous hair follicle germ (HFG) formation in vitro, enabling the large-scale production of HFGs for regenerative medicine. Biomaterials, 2018, 154.: 291-30

12.

Daisuke Taniguchi, et el, Scaffold-free trachea regeneration by tissue engineering with bio-3D printing. Interactive CardioVascular and Thoracic Surgery, 2018, 26.5.:745-752 [MS-9096U]

13.

Michael Dunne, et el, Hyperthermia-mediated drug delivery induces biological effects at the tumor and molecular levels that improve cisplatin efficacy in triple negative breast cancer. Journal of Controlled Release, 2018, 282.28.: 35-45 [MS-9096]

14.

Wenjie Wang, et el, Impaired pentose phosphate pathway in the development of 3D MCF-7 cells mediated intracellular redox disturbance and multi-cellular resistance without drug induction. Redox Biology, 2018, 15.:253-265 [ MS-9096 U, M or V ]

15.

Xiu-Ying Zhang, et el, Regeneration of diaphragm with bio-3D cellular patch. Biomaterials, 2018.167.:1-14 [MS-9096U]

16.

Kaori Yamauchi, et el, Isolation and characterization of ventricular-like cells derived from NKX2-5eGFP/w and MLC2vmCherry/w double knock-in human pluripotent stem cells. Biochemical and Biophysical Research Communications, 2018, 495.1.:1278-1284 [MS-9096U]

17.

Yoko Sawada, et el, Ajuga decumbens stimulates mesenchymal stem cell differentiation and regenerates cartilage in a rabbit osteoarthritis model. Experimental and TherapeuticMedicine, 2018. 15.5

18.

Kazuhiko Iikubo, et el, Discovery of N-{2-Methoxy-4-[4-(4-methylpiperazin-1-yl)piperidin-1-yl]phenyl}- N′-[2-(propane-2-sulfonyl)phenyl]-1,3,5-triazine-2,4-diamine (ASP3026), a Potent and Selective Anaplastic Lymphoma Kinase (ALK) Inhibitor. Chemical and Pharmaceutical Bulletin, 2018.66.3.:251-262

19.

Toshiyuki Sumi, et el, Survivin knockdown induces senescence in TTF1-expressing, KRAS-mutant lung adenocarcinomas. International Journal of Oncology, 2018. 53.1 [MS-9096U]

20.

Yu Nakano, et el, Evaluation of hollow fiber culture for large-scale production of mouse embryonic stem cell-derived hematopoietic stem cells. Cytotechnology, 2018, 70.3.:975-982

21.

Takahashi, Yoshinobu, et el, Self-Condensation Culture Enables Vascularization of Tissue Fragments for Efficient Therapeutic Transplantation. Cell Reports, 208, 23.6.:1620-1629 [MS-9096U]

22.

Luqi Wang, et el, Effects of a checkpoint kinase inhibitor, AZD7762, on tumor suppression and bone remodeling. International Journal of Oncology, 2018, 52.5 [MS-9096U]

23.

Akira Igarashi, et el, Mast cells derived from human induced pluripotent stem cells are useful for allergen tests. Allergology International, 2018. 67.:234-242 [MS-9024X]

24.

Lauren M. Watson, et el, A Simplified Method for Generating Purkinje Cells from Human-Induced Pluripotent Stem Cells. The Cerebellum, 2018, 17.4.:419-427 [MS-9096V]

25.

Tokuhiro Chano, et el, Prominent role of RAB39A-RXRB axis in cancer development and stemness. Oncotarget, 2018, 9.11.:9852-9866

26.

Daisuke Watanabe, et el, The Generation of Human γδ T Cell‐Derived Induced Pluripotent Stem Cells from Whole Peripheral Blood Mononuclear Cell Culture. Pluripotent Stem Cells, 2018, 7.1.34-44 [MS-9096M]

27.

Wataru Kobayashi, et el, Culture Systems of Dissociated Mouse and Human Pluripotent Stem Cell–Derived Retinal Ganglion Cells Purified by Two-Step Immunopanning. Investigative Opthamology & Visual Science, 2018, 59.2.:776-787 [MS-9096U & MS-9090XZ]

28.

Shin-Ichi Mae, et el, Generation of branching ureteric bud tissues from human pluripotent stem cells. Biochemical and Biophysical Research Communications, 2018, 495.1.:954-961 [ MS-9096 U, M or V ]

29.

JunTerashima, et el, CYP1A1 and CYP1A2 expression levels are differentially regulated in three-dimensional spheroids of liver cancer cells compared to two-dimensional monolayer cultures. Drug Metabolism and Pharmacokinetics, 2018, 30.6.:434-440 [MS-9096U]

30.

Toshiki Kato, et el, Elevated Expression of Dkk-1 by Glucocorticoid Treatment Impairs Bone Regenerative Capacity of Adipose Tissue-Derived Mesenchymal Stem Cells. Stem Cells and Development, 2018, 27.2

31.

Sina Eetezadi, et el, Ratio-Dependent Synergism of a Doxorubicin and Olaparib Combination in 2D and Spheroid Models of Ovarian Cancer. American Chemical Society, 2018, 15.2.:472-485

32.

Chul Jang Kim, et el, Anti-oncogenic activities of cyclin D1b siRNA on human bladder cancer cells via induction of apoptosis and suppression of cancer cell stemness and invasiveness. International Journal of Oncology, 2018, 52.1.:231-240

33.

Emi Sano, et el, Engineering of vascularized 3D cell constructs to model cellular interactions through a vascular network. Biomicrofluidics, 2018, 12.4

34.

Hiroto Fujii, et el, Compact Seahorse‐Shaped T Cell–Activating Antibody for Cancer Therapy. Advanced Therapeutics, 2018, 1.3

35.

Kenichiro Ishii, et el, Additive naftopidil treatment synergizes docetaxel-induced apoptosis in human prostate cancer cells. Journal of Cancer Research and Clinical Oncology, 2018, 1.3

36.

Anju Dang, et el, Brightfield and Fluorescence Imaging using 3D PrimeSurface® Ultra-Low Attachment Microplates. The Journal of Immunology, 2018, 200.1

37.

Yulius Hermanto, et el, Transplantation of feeder‐free human induced pluripotent stem cell–derived cortical neuron progenitors in adult male Wistar rats with focal brain ischemia. Journal of Nueroscience Research, 2018, 96.5.:863-874

38.

Reiko Iwazawa, et el, The Therapeutic Effects of Adipose-Derived Stem Cells and Recombinant Peptide Pieces on Mouse Model of DSS Colitis, 2018 [MS-9096U]

39.

Yukimasa Makita, et el, Antitumor activity of kinetochore-associated protein 2 siRNA against lung cancer patient-derived tumor xenografts. Oncology Letters, 2018 [MS-9096U]

40.

T. Sakabe, et el, Transcription factor scleraxis vitally contributes to progenitor lineage direction in woundhealing of adult tendon in mice. Journal of Biological Chemistry, 2018, 293.16.:5766-5780

41.

K. Ogawa, et el, Vasopressin-secreting neurons derived from human embryonic stem cells through specificinduction of dorsal hypothalamic progenitors. Scientific Reports, 2018, 8.3615 [MS-9096V] [MS-9096M]

42.

村田大紀 , et el, 脂肪組織由来間葉系幹細胞の三次元構造体による骨軟再生. Clinical Orthopedic Surgery,  2018, 53. 1

43.

K. Iikubo, et el, Discovery of N-{2-Methoxy-4-[4-(4-methylpiperazin-1-yl) piperidin-1-yl] phenyl}-N′-[2-(propane-2-sulfonyl) phenyl]-1, 3, 5-triazine-2, 4-diamine (ASP3026), a Potent and Selective AnaplasticLymphoma Kinase (ALK) Inhibitor. Chemical and Pharmaceutical Bulletin, 2018, 66.3.:251-262

44.

A. D. Silva, et el, Surface modification using the biomimetic method in alumina‐zirconia porous ceramicsobtained by the replica method. Journal of Biomedical Materials Research, 2018

45.

Y. Fukuda, et el, Layer by layer cell coating technique using extracellular matrix facilitates rapid fabricationand function of pancreatic β-cell spheroids. Biomaterials, 2018, 160.:82-91 [MS-9096U]

46.

M. G. Murrali, et el, 13 C APSY-NMR for sequential assignment of intrinsically disordered proteins. Journalof Biomolecular NMR, 2018, 70.3.:167-175

2017年的参考文献 (50)


1.

W. Wang, et al. Impaired pentose phosphate pathway in the development of 3D MCF-7 cells mediated intracellular redox disturbance and multi-cellular resistance without drug induction. Redox Biology, 2017,15.: 253-265 [MS-9096U]

2.

M. Tamura, et al. Morphology-based optical separation of subpopulations from a heterogeneous murine breast cancer cell line. PLOS|One, 2017 [MS-9096V]

3.

T. Suzuki, et al. Quantitative visualization of synchronized insulin secretion from 3D-cultured cells.Biochemical and Biophysical Research Communications, 2017, 485.4:253-265 [MS-9096U]

4.

A. G. Smith, et al. Epigenetic resetting of human pluripotency. Development, 2017, 144.15: 2748–2763 [MS-9096V]

5.

M. Sato-Nakai, et al, Metabolites of alectinib in human: their identification and pharmacological activity.Heliyon, 2017, 3.7 [MS-9096U]

6.

 N. Sano, et al, Enhanced axonal extension of subcortical projection neurons isolated from murine embryonic cortex using neuropilin-1. Frontiers in Cellular Neuroscience, 2017, 11.123 [MS-9096U]

7.

M. Sano, et al, Induction of cell death in pancreatic ductal adenocarcinoma by indirubin 3′-oxime and 5-methoxyindirubin 3′-oxime in vitro and in vivo. Cancer Letters, 2017, 11.123 [MS-9096U]

8.

S. Quader, et al, cRGD peptide-installed epirubicin-loaded polymeric micelles for effective targeted therapy against brain tumors. Journal of Controlled Release, 2017, 258: 56-66 [MS-9096U]

9.

Y. Ogawa, et al, Abnormal differentiation of Sandhoff disease model mouse-derived multipotent stem cells toward a neural lineage. PLOS|One, 2017 [MS-9096U]

10.

K. Miyano, et al, cRGD peptide installation on cisplatin-loaded nanomedicines enhances efficacy against locally advanced head and neck squamous cell carcinoma bearing cancer stem-like cells. Journal of Controlled Release, 2017, 261: 275-286 [ MS-9096 U, M or V ]

11.

M. Kucinska, et al, Beyond mouse cancer models: Three-dimensional human-relevant in vitro and non-mammalian in vivo models for photodynamic therapy. Mutation Research/Reviews in Mutation Research,2017, 772: 242-262 [ MS-9096 U, M or V ]

12.

S. Kessel, et al, High-Throughput 3D tumor spheroid screening method for cancer drug discovery using Celigo image cytometry. Micro- and Nanotechnologies for Quantitative Biology and Medicine, 2017, 22.4.:454-465 [MS-9096U and MS-9384U]

13.

S.-i. Ito, et al, Chemically-induced photoreceptor degeneration and protection in mouse iPSC-derived three-dimensional retinal organoids. Stem Cell Research, 2017, 24.: 94-101 [MS-9090X]

14.

R. Ishida, et al, The Tissue-Reconstructing Ability of Colon CSCs Is Enhanced by FK506 and Suppressed by GSK3 Inhibition. Molecular Cancer Research, 2017, 15.10 [MS-9024X]

15.

A. Igarashi, et al, Mast cells derived from human induced pluripotent stem cells are useful for allergen tests. Allergology International, 2017, 67.2.: 234-242 [MS-9024X]

16.

Y. Fujita, et al, KH-type splicing regulatory protein is involved in esophageal squamous cell carcinoma progression. Oncotarget, 2017, 8.60 [MS-9096U]

17.

D. Diekjürgen, et al, Polysaccharide matrices used in 3D in vitro cell culture systems. Biomaterials, 2017,141.:96-115 [ MS-9096 U, M or V ]

18.

E. C. Costa, et al, Spheroids formation on non‐adhesive surfaces by Liquid Overlay Technique:considerations and practical approaches. Biotechnology Journal: Special Issue: Biotech Methods andAdvances, 2017, 13.1 [ MS-9096 U, M or V ]

19.

Y. Bamba, et al, Visualization of migration of human cortical neurons generated from induced pluripotent stem cells. Journal of Neuroscience Methods, 2017, 289.: 57-63 [MS-9096V]

20.

H. Ogawa, et al, Interleukin-6 blockade attenuates lung cancer tissue construction integrated by cancer stemcells. Scientific Reports, 2017, 7.12317 [MS-9024X]

21.

T. Hiragi, et al, Differentiation of Human Induced Pluripotent Stem Cell (hiPSC)-Derived Neurons in Mouse Hippocampal Slice Cultures. frontiers in Cellular Neuroscience, 2017,11.143 [MS-9035X, MS-9060X, or MS-9090X]

22.

H. Jung, et al, Development of flexible nanocarriers for siRNA delivery into tumor tissue. International Journal of Pharmaceutics, 2017, 516.1-2.:258-265

23.

M. Ikeda, et al, Dormant pluripotent cells emerge during neural differentiation of embryonic stem cells in a FoxO3-dependent manner. Molecular and Cellular Biology, 2017, 37.5 [ MS-9096 U, M or V ]

24.

K. Sawada, et al, Vitamin D receptor agonist VS-105 directly modulates parathyroid hormone expression inhuman parathyroid cells and in 5/6 nephrectomized rats. The Journal of Steroid Biochemistry and MolecularBiology, 2017, 167.:48-54 [MS-9096U and MS-9024X]

25.

H. Katayama, et al, Generation of non-viral, transgene-free hepatocyte like cells with piggyBac transposon.Scientific Reports, 2017, 7 [ MS-9096 U, M or V ]

26.

J. Kawada, et al, Generation of a Motor Nerve Organoid with Human Stem Cell-Derived Neurons. Stem CellReports, 2017 [MS-9096V]

27.

M. Fukuhara, et al, A G-quadruplex structure at the 5′ end of the H19 coding region regulates H19 transcription. Scientific Reports, 2017, 7 [ MS-9096 U, M or V ]

28.

D. Yahia, et al, Cytotoxic activity of fumonisin B 1 in Vero cells: comparison between 2D and 3D structural microplates. Comparative Clinical Pathology, 2017, 26.3.: 561-568 [ MS-9096 U, M or V ]

29.

S. Tsubota, et al, PRC2-mediated transcriptomic alterations at the embryonic stage govern tumorigenesis and clinical outcome in MYCN-driven neuroblastoma. Cancer Research, 2017, 77.19 [ MS-9096 U, M or V ]

30.

 Y. Takechi-Haraya, et al, Control of Liposomal Penetration into Three-Dimensional Multicellular. Molecular Pharmaceutics, 2017, 14.6.: 2158-2165 [ MS-9096 U, M or V

31.

K. Muguruma, 3D Culture for Self-Formation of the Cerebellum from Human Pluripotent Stem Cells Through Induction of the Isthmic Organizer. Organ Regeneration, 2017, 31-41 [ MS-9096 U, M or V

32.

L. Li, et al, 3D High-Content Screening of Organoids for Drug Discovery, 2017

33.

G. Lazzari, et al, Multicellular tumor spheroids: a relevant 3D model for the in vitro preclinical investigation of polymer nanomedicines. Polymer Chemistry, 2017, 34 [ MS-9096 U, M or V ]

34.

T. Kobayashi, et al, Principles of early human development and germ cell program from conserved model systems. Nature, 2017, 546.: 416-420 [ MS-9096 U, M or V ]

35.

 U. Elling, et al, A reversible haploid mouse embryonic stem cell biobank resource for functional genomics.Nature, 2017 [ MS-9096 U, M or V ]

36.

P. Dvořáková, et al, Inhibitor-Decorated Polymer Conjugates Targeting Fibroblast Activation Protein. Journalof Medicinal Chemistry, 2017, 60.20.: 8385-8393 [ MS-9096 U, M or V ]

37. 

Z. Chen, et al, Tuning chemistry and topography of nanoengineered surfaces to manipulate immuneresponse for bone regeneration applications. ACS Nano, 2017, 11.5.:4494-4506 [ MS-9096 U, M or V ]

38.

Y. Yoshikawa, et al, Ras inhibitors display an anti-metastatic effect by downregulation of lysyl oxidase through inhibition of the Ras-PI3K-Akt-HIF-1α pathway. Cancer Letters, 2017 [ MS-9096 U, M or V ]

39.

F. Clément, Regulating human mammary epithelial stem cells transformation: an interplay between extrinsicand intrinsic signals. 2017 [ MS-9096 U, M or V ]

40.

F. Perche, et al, Improved brain expression of anti-amyloid β scfv by complexation of mRNA including asecretion sequence with PEG-based block catiomer. Current Alzheimer Research, 2017, 14.3.:295-302 [ MS-9096 U, M or V ]

41.

J.-I Furukawa, et al, Impact of the Niemann–Pick c1 Gene Mutation on the Total Cellular Glycomics of CHOCells. Journal of Proteome Research, 2017, 16.8.1802-2810 [ MS-9096 U, M or V ]

42.

K. Arai, et al, Fabrication of 3D‐culture platform with sandwich architecture for preserving liver‐specificfunctions of hepatocytes using 3D bioprinter. Journal of Biomedical Materials Research, 2017, 105.6.:1583-1592 [ MS-9096 U, M or V ]

43.

A. Taguchi, et al, Higher-Order Kidney Organogenesis from Pluripotent Stem Cells. Cell Stem Cell, 2017, 21.6.:730-746 [ MS-9096 U, M or V ]

44.

H. Tamada, et al, Three‐dimensional analysis of somatic mitochondrial dynamics in fission‐deficientinjured motor neurons using FIB/SEM. The Journal of Comparative Neurology, 2017, 525.11.: 2535-2548[ MS-9096 U, M or V ]

45.

Y. Nashimoto, et al, Integrating perfusable vascular networks with a three-dimensional tissue in amicrofluidic device. Integrative Biology, 6 [ MS-9096 U, M or V ]

46.

Y. Nashimoto, et al, Engineering a three-dimensional tissue model with a perfusable vasculature in amicrofluidic device. 2017

47.

L. Moldovan N. Senda, et al, Spheroid imaging of phase-diversity homodyne OCT. 2017

48.

L. Moldovan, et al, iPSC‐Derived Vascular Cell Spheroids as Building Blocks for Scaffold‐Free Biofabrication. Biotechnology Journal: Special Issue: AFOB Special Issue on Stem Cells in Tissue Engineering and Regenerative Medicine, 2017, 12.12

49.

H. Kobayashi, et al, Identification of the determinants of 2-deoxyglucose sensitivity in cancer cells by shRNA library screening. Biochemical and biophysical research communications, 2015, 467:121-127

50.

H. Yurie, et al, The efficacy of a scaffold-free Bio 3D conduit developed from human fibroblasts on peripheral nerve regeneration in a rat sciatic nerve model. PloS one, 2017, 12,2

产品列表
产品编号 产品名称 产品规格 产品等级 备注
MS-9035XZ PrimeSurface 35mm dish
 PrimeSurface 35mm 
 培养皿
50个
MS-9060XZ PrimeSurface® 
培养皿60mm
100个
MS-9090XZ PrimeSurface® 
培养皿90mm
50个
MS-9024XZ Sumiron Celltight    板24F 10个
MS-9384UZ PrimeSurface®  
384U多孔板
​0.1 mL
MS-9384WZ PrimeSurface®     
 384U白色多孔板
0.1 mL
MS-9096VZ PrimeSurface® 
 96V多孔板
0.3 mL
MS-9096MZ PrimeSurface® 
 96M多孔板
0.2 mL
MS-9096UZ PrimeSurface® 
96U多孔板
0.3 mL
MS-9096WZ PrimeSurface® 
96U白色多孔板
0.3 mL