在全球生物市场利用特有技术积极开展事业
细胞批量培养技术 + 质量管理技术
兼具两种核心技术的企业
获得主导新药开发市场的
主要国家的专利
利用专利技术开拓国际市场
知识产权
我们通过建立知识产权保护核心技术
| 技术名称 | 申请国家 | 申请·注册号 | 申请·登记日期 |
|---|---|---|---|
| 用于检测细胞硫醇水平的 实时成像传感器 |
韩国 | 10-1862581 | 2018. 05. 24 |
| 美国 | 10.215.757B2 | 2019. 02. 26 | |
| 韩国 | 10-1983803 | 2019. 05. 23 | |
| 美国 | 10.620.215 | 2020. 04. 14 | |
| 细胞器内谷胱甘肽检测用 实时荧光成像传感器及其制造方法 |
韩国 | 10-2133794 | 2020. 07. 08 |
| 加拿大(申请) | 3.072.434 | 2020. 02. 07 | |
| 澳大利亚(申请) | 2018320601 | 2020. 02. 19 | |
| 美国(申请) | 16/640717 | 2020. 02. 20 | |
| 欧洲(申请) | 18848372.1 | 2020. 02. 21 | |
| 中国(申请) | 201880054675.0 | 2020. 02. 21 | |
| 印度(申请) | 202017007994 | 2020. 02. 25 | |
| 日本(申请) | 2020-511502 | 2020. 02. 19 | |
| 内质网内谷胱甘肽检测用 实时荧光成像传感器及其使用方法 |
韩国 | 10-2019-0178260 | 2019. 12. 30 |
Gene Biomarker
| 技术名称 | 申请国家 | 申请·注册号 | 申请·登记日期 |
|---|---|---|---|
| 基于 FreSHtracer 分离的细胞 基因配置文件的应用 |
PCT | PCT/KR 2018/008239 | 2018. 07. 20 |
Stem Cell Therapy
| 技术名称 | 申请国家 | 申请·注册号 | 申请·登记日期 |
|---|---|---|---|
| 用于治疗血小板减少症的组合物 | 韩国 | 10-2021-0063975 | 2021. 05. 18 |
| 用于评估干细胞特性的 基因标记及其用途 |
韩国 | 10-2020-0180455 | 2020. 12. 22 |
Cell Quality Control
| 技术名称 | 申请国家 | 申请·注册号 | 申请·登记日期 |
|---|---|---|---|
| 通过实时检测谷胱甘肽, 提高治疗用细胞质量的方法 |
韩国 | 10-2119714 | 2020. 06. 01 |
| 欧洲(申请) | 18883520.1 | 2020. 05. 27 | |
| 中国(申请) | 201880077266.2 | 2020. 05. 28 | |
| 日本(申请) | 2020-546264 | 2020. 05. 27 | |
| 美国(申请) | 16/767985 | 2020. 05. 28 | |
| 通过实时检测谷胱甘肽, 检测治疗用细胞质量的方法 |
韩国 | 10-2145929 | 2020. 08. 12 |
| 美国(申请) | 16/768014 | 2020. 05. 28 | |
| 欧洲(申请) | 18884812.1 | 2020. 05. 27 | |
| 中国(申请) | 201880077236.1 | 2020. 05. 28 | |
| 日本(申请) | 2020-546265 | 2020. 05. 27 |
发表
接连在知名学术期刊上发表了研究成果
Development Technology and senescent Cells : KB. Lee et al., Antioxidants reduce the heterogeneity of the intracellular glutathione level in senescent cell population of human dermal fibroblasts, J Dermatol Sci. (2020) 98(3),195-198
Accumulating evidence suggests that increased reactive
oxygen species (ROS) production has a role in inducing
senescence of human dermal
fibroblasts (HDFs) via the activation
of DNA damage and redox signaling pathways [1]. Unfortunately,
ROS-reducing antioxidant agents are only marginally effective in
delaying or preventing cellular senescence, even at a high
concentration [2,3]. We evaluated endogenous antioxidant
systems to better understand these
findings. Glutathione (GSH)
is the most abundant thiol-containing tripeptide that plays a
major role in eliminating H2O2 through a GSH peroxidase-
catalyzed reactions [4]. Moreover, GSH reduces oxidized proteins
through glutathionylation, thereby regulating the intensity and
duration of redox signaling. Thus, intracellular GSH level are
critical for maintaining redox homeostasis. Measuring GSH level
in live cells is challenging owing to the irreversible reaction of
fluorescent probes with GSH. We developed a new coumarin-
based GSH probe, FreSHtracer, which reversibly reacts with GSH
accompanied by spectral shifts in UV absorption (520 to 430 nm)
and
fluorescence emission (F580 to F510), allowing ratiometric
measurement of GSH in live cells [5]. Here, we monitored the
changes in GSH levels in HDFs during senescence and evaluated
the effect of antioxidants on GSH levels by measuring the F510/F580
ratio (FR).
oxygen species (ROS) production has a role in inducing
senescence of human dermal
fibroblasts (HDFs) via the activation
of DNA damage and redox signaling pathways [1]. Unfortunately,
ROS-reducing antioxidant agents are only marginally effective in
delaying or preventing cellular senescence, even at a high
concentration [2,3]. We evaluated endogenous antioxidant
systems to better understand these
findings. Glutathione (GSH)
is the most abundant thiol-containing tripeptide that plays a
major role in eliminating H2O2 through a GSH peroxidase-
catalyzed reactions [4]. Moreover, GSH reduces oxidized proteins
through glutathionylation, thereby regulating the intensity and
duration of redox signaling. Thus, intracellular GSH level are
critical for maintaining redox homeostasis. Measuring GSH level
in live cells is challenging owing to the irreversible reaction of
fluorescent probes with GSH. We developed a new coumarin-
based GSH probe, FreSHtracer, which reversibly reacts with GSH
accompanied by spectral shifts in UV absorption (520 to 430 nm)
and
fluorescence emission (F580 to F510), allowing ratiometric
measurement of GSH in live cells [5]. Here, we monitored the
changes in GSH levels in HDFs during senescence and evaluated
the effect of antioxidants on GSH levels by measuring the F510/F580
ratio (FR).