| 序号 | 专利名 | 申请号 | 申请日 | 公开(公告)号 | 公开(公告)日 | 发明人 |
|---|---|---|---|---|---|---|
| 1 | BIOPHOTONIC MATERIALS AND USES THEREOF | EP14765490.9 | 2014-03-14 | EP2968561A1 | 2016-01-20 | LOUPIS, Nikolaos; PIERGALLINI, Remigio; DESROSIERS, Éric |
| The present disclosure provides biophotonic materials and methods useful in phototherapy. In particular, the biophotonic materials of the present disclosure include a cohesive matrix, and at least one chromophore, wherein the at least one chromophore can absorb and emit light from within the biophotonic material. The biophotonic materials and the methods of the present disclosure are useful for promoting wound healing and skin rejuvenation, as well as treating acne and various skin disorders. | ||||||
| 2 | PHOTODYNAMIC THERAPY USING IN SITU NONLINEAR PHOTON UPCONVERSION OF NIR LIGHT BY BIOLOGICAL MEDIUM | PCT/US2015/027928 | 2015-04-28 | WO2015168080A1 | 2015-11-05 | PRASAD, Paras, N.; PLISS, Artem; KACHYNSKI, Aliaksandr; OHULCHANSKYY, Tymish, Y.; KUZMIN, Andrey, N. |
Photodynamic therapy methods using near infrared light and visible-light-absorbing photosensitizers and methods of generating visible light in an individual. The methods use upconverted incident near infrared light, for example, to excite the photosensitizer or facilitate drug delivery. The methods can be carried out on humans and non-human animals. |
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| 3 | DEVICE, APPARATUS AND SYSTEM FOR USE IN PHOTONICS, NANOTECHNOLOGY, MICROSCOPY AND BIOLOGY | PCT/EP2014/076616 | 2014-12-04 | WO2015082635A1 | 2015-06-11 | TORRE, Vincent; MAZZOLINI, Monica; LAZZARINO, Marco; ANDOLFI, Laura |
The present invention relates to devices, equipment and systems useful in the investigation in several fields where highly confined light beams are useful and/or necessary, in particular the present invention relates to the far-field imaging applications. The apparatus according to the present invention is useful in photonics, nanotechnology, microscopy and biology, in particular in optogenetics investigation characterized in that it comprises at least one apertureless optical fibre (TOF). Preferably, said TOF is partially coated or completely coated by a metal film. According to the present invention, said apertureless optical fibre shows a light profile intermediate between a 0 order Bessel function J0 and a top hat function. This light profile has a light profile sharper than that emitted from a cleaved optical fibre and the light intensity is confined entirely in the inner region and no photons are present in the outer region, thus reducing to zero the background signal. |
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| 4 | 이방성 고분자 쉘을 가진 리간드 유도 이중 금속 코어-새틀라이트 나노구조체, 이의 제조 방법 및 이의 바이오광학적 응용 | KR20170100357 | 2017-08-08 | KR20180018376A | 2018-02-21 | |
| 본발명은코어-새틀라이트구조의이중금속나노입자구획과고분자구획으로이루어진야누스나노구조체, 이의제조방법및 이를이용한표면-증강라만산란(SERS) 기반표적물질검출용금속나노프로브, SERS 기반의표적물질검출방법에관한것이다. 본발명에따른이중금속 Au 코어-Ag 새틀라이트나노입자구획및 고분자구획을포함하는야누스나노구조체는전하를띠는고분자또는리간드로개질된이중금속나노입자구획을포함함에따라 SERS 강도가현저히향상된표면-증강라만산란(SERS) 기반표적물질검출용금속나노프로브로이용할수 있다. | ||||||
| 5 | PHOTODYNAMIC THERAPY USING IN SITU NONLINEAR PHOTON UPCONVERSION OF NIR LIGHT BY BIOLOGICAL MEDIUM | US15307548 | 2015-04-28 | US20170050045A1 | 2017-02-23 | Paras N. PRASAD; Artem PLISS; Aliaksandr KACHYNSKI; Tymish OHULCHANSKYY; Andrey N. KUZMIN |
| Photodynamic therapy methods using near infrared light and visible-light-absorbing photosensitizers and methods of generating visible light in an individual. The methods use upconverted incident near infrared light, for example, to excite the photosensitizer or facilitate drug delivery. The methods can be carried out on humans and non-human animals. | ||||||
| 6 | Molecular imaging and nanophotonics imaging and detection principles and systems, and contrast agents, media makers and biomarkers, and mechanisms for such contrast agents | US11912560 | 2006-05-12 | US07823215B2 | 2010-10-26 | George C. Giakos |
| The present invention relates to near-field scanning optical microscopy (NSOM) and near-field/far-field scanning microscopy methods, systems and devices that permit the imaging of biological samples, including biological samples or structures that are smaller than the wavelength of light. In one embodiment, the present invention permits the production of multi-spectral, polarimetric, near-field microscopy systems that can achieve a spatial resolution of less than 100 nanometers. In another embodiment, the present invention permits the production of a multifunctional, multi-spectral, polarimetric, near-field/far-field microscopy that can achieve enhanced sub-surface and in-depth imaging of biological samples. In still another embodiment, the present invention relates to the use of polar molecules as new optical contrast agents for imaging applications (e.g., cancer detection). | ||||||
| 7 | Molecular imaging and nanophotonics imaging and detection principles and systems, and contrast agents, media makers and biomarkers, and mechanisms for such contrast agents | US11912560 | 2006-05-12 | US20090119808A1 | 2009-05-07 | George C. Giakos |
| The present invention relates to near-field scanning optical microscopy (NSOM) and near-field/far-field scanning microscopy methods, systems and devices that permit the imaging of biological samples, including biological samples or structures that are smaller than the wavelength of light. In one embodiment, the present invention permits the production of multi-spectral, polarimetric, near-field microscopy systems that can achieve a spatial resolution of less than 100 nanometers. In another embodiment, the present invention permits the production of a multifunctional, multi-spectral, polarimetric, near-field/far-field microscopy that can achieve enhanced sub-surface and in-depth imaging of biological samples. In still another embodiment, the present invention relates to the use of polar molecules as new optical contrast agents for imaging applications (e.g., cancer detection). | ||||||
| 8 | 一种衬底-有源层复合纳米光子学结构碱金属化合物光电阴极 | CN202010342767.8 | 2020-04-27 | CN111477524A | 2020-07-31 | 彭新村; 邹继军; 汤彬; 邓文娟; 朱志甫; 刘双飞 |
| 一种衬底-有源层复合纳米光子学结构碱金属化合物光电阴极,由下至上依次包括衬底、纳米阵列和碱金属化合物有源层,利用纳米阵列与入射光作用产生的光学共振效应,能够降低光反射率并提升光电子的产生与输运效率,从而有效提升光电阴极的性能。本发明制备的复合纳米光子学结构碱金属化合物光电阴极,其有源层直接沉积制备于纳米阵列的上表面以避免对光电发射面的刻蚀,纳米阵列采用纳米压印或自组装纳米球等较成熟的工艺直接刻蚀衬底进行制备,制备工艺简单、稳定性好,可应用于微弱信号探测与成像、生物医疗、加速器电子源、先进光源等领域。 | ||||||
| 9 | 表达组合式荧光蛋白片段的载体及其应用 | CN202110144958.8 | 2021-02-02 | CN114836470A | 2022-08-02 | 姚雪彪; 窦震; 刘行; 桂萍 |
| 本发明属于生物技术领域,具体涉及一组表达四个荧光蛋白片段的载体,可以用于实现荧光蛋白的互补和荧光共振能量转移,可以在活细胞水平监控4个蛋白质的相互作用。本发明实施例选取了CENP‑T/W/S/X复合物融合蛋白以及CENPT、CENPW、SPC24、SPC25融合蛋白对该系统进行了验证。该系统将成为功能蛋白组学时代生物光子学领域的前沿技术,其应用前景十分可观。 | ||||||
| 10 | 一种提高多光子成像信号强度的方法及系统 | CN201510572194.7 | 2015-09-09 | CN105158224B | 2017-10-20 | 王科; 邱娉; 梁闰富 |
| 本发明适用于生物光子学领域,提供了一种提高多光子成像信号强度的方法,包括:获取多光子成像的信号强度;在物镜中,通过改变物镜填充因子来增强所述多光子成像的信号强度。本发明还提供了一种提高多光子成像信号强度的系统。本发明能提高深层生物组织高阶多光子显微成像中最大化的信号强度,从而获得更大成像深度。 | ||||||
| 11 | 一种提高多光子成像信号强度的方法及系统 | CN201510572194.7 | 2015-09-09 | CN105158224A | 2015-12-16 | 王科; 邱娉; 梁闰富 |
| 本发明适用于生物光子学领域,提供了一种提高多光子成像信号强度的方法,包括:获取多光子成像的信号强度;在物镜中,通过改变物镜填充因子来增强所述多光子成像的信号强度。本发明还提供了一种提高多光子成像信号强度的系统。本发明能提高深层生物组织高阶多光子显微成像中最大化的信号强度,从而获得更大成像深度。 | ||||||
| 12 | 一种基于超表面的全视场平面三维显示装置 | CN202310697550.2 | 2023-06-13 | CN116794852A | 2023-09-22 | 陈瑞; 马云贵; 胡欢; 周毅 |
| 本发明公开了一种基于超表面的全视场平面三维显示装置。本发明包括超表面、平面镜以及支撑结构;所述超表面由各向异性亚波长微纳结构组成,其可对正交偏振态实现独立的透射以及反射振幅和相位的调制;所述的平面反射镜由金属薄膜构成,其上面可增加透明材料进行保护;所述的支撑结构对制作材料没有限制,其主要负责固定反射镜以及设计超表面。本发明通过超表面对光波不同偏振态的自由调制能力,将被观测物体的三维信息投影到装置外,充分发挥了超表面平面化、轻薄化以及偏振可控的优势,为生物光子学中活体实时三维观测提供新的实现方案,为超表面在生物光子学中的应用开辟新的思路。 | ||||||
| 13 | 一种介入式光学神经刺激装置 | CN202311647333.9 | 2023-12-04 | CN117563149A | 2024-02-20 | 段峰; 李乐洋; 刘淦; 李思宁; 王文智; 汝志豪; 谭莹; 段雅涵; 杜颖 |
| 本发明属于生物光子学的生物交叉科研领域,涉及一种介入式光学神经刺激装置。该装置包括光源产生模块、传输引导模块和光学刺激终端模块;所述光源产生模块用于根据实际需求产生特定波长、功率、脉冲周期和脉冲宽度的光源,耦合进入传输引导模块;所述传输引导模块作为媒介联通光源产生模块和光学刺激终端模块,用于接受光源产生模块产生的激光,将其引导作用于目标生物指定脑区;所述光学刺激终端模块用于将传输引导模块传输的激光固定在预先指定的目标生物脑区。 | ||||||
| 14 | 一种基于回音壁模式的单细胞内物质检测方法 | CN201810558923.7 | 2018-06-01 | CN108760704A | 2018-11-06 | 王秀红; 王亚平 |
| 一种基于回音壁模式的单细胞内物质检测方法属于激光技术与生物光子学领域。方法包括以下几点:(1)回音壁模式微腔的选取(2)微腔与细胞的处理(3)待测生物物质探测的具体实施方法(4)此探测方法的探测范围涉及到核酸、蛋白质、细胞、生物分子等众多特定生物物质。本发明检测灵敏度高,可在细胞内实现检测。回音壁模式会使荧光在腔内形成谐振,产生激光,信号大大增强并延长了跟踪检测的时间。 | ||||||
| 15 | 基于倏逝波技术的特种光纤生化传感器 | CN201510779036.9 | 2015-11-13 | CN105445242A | 2016-03-30 | 王秀红; 张炤; 冯宪 |
| 基于倏逝波技术的特种光纤生化传感器,属于生物医学光子学中的生物光纤传感领域。以纤芯直径只有1±0.2微米的特种多孔微结构光纤,作为探测探针,纤芯材料是Schott N-BK7系列玻璃;支撑纤芯的薄膜将光纤的空腔分为独立的两部分,其中支撑纤芯的薄膜的两端分别与光纤连接在一起;材质属于D263T系列玻璃,玻璃薄膜相当于光纤两孔之间的分界;激光通过空间光耦合进这种光纤的纤芯中,光纤的芯径接近光波长尺寸,且光纤纤芯的外部是空气,与纤芯的折射率相差较大,这样就会在纤芯的外部会产生极强的倏逝波,这种倏逝波为生物化学传感提供了极大的便利。 | ||||||
| 16 | 基于倏逝波技术的特种光纤生化传感器 | CN201510779036.9 | 2015-11-13 | CN105445242B | 2018-07-31 | 王秀红; 张炤; 冯宪 |
| 基于倏逝波技术的特种光纤生化传感器,属于生物医学光子学中的生物光纤传感领域。以纤芯直径只有1±0.2微米的特种多孔微结构光纤,作为探测探针,纤芯材料是Schott N‑BK7系列玻璃;支撑纤芯的薄膜将光纤的空腔分为独立的两部分,其中支撑纤芯的薄膜的两端分别与光纤连接在一起;材质属于D263T系列玻璃,玻璃薄膜相当于光纤两孔之间的分界;激光通过空间光耦合进这种光纤的纤芯中,光纤的芯径接近光波长尺寸,且光纤纤芯的外部是空气,与纤芯的折射率相差较大,这样就会在纤芯的外部会产生极强的倏逝波,这种倏逝波为生物化学传感提供了极大的便利。 | ||||||
| 17 | 一种上转换荧光纳米材料的表面包覆方法 | CN201210060849.9 | 2012-03-09 | CN102618257B | 2014-01-29 | 王丹; 钱骏; 詹求强; 何赛灵 |
| 本发明属于光子学及材料学交叉技术领域,基于研究简单高效、生物兼容性好的上转换荧光纳米材料包覆方法的思路,采用牛血清蛋白作为表面活性剂,在超声分散的四氢呋喃和水混合液中,利用反溶剂法对上转换荧光纳米材料表面进行牛血清蛋白包覆,随后加入戊二醛将纳米材料表面的牛血清蛋白分子进行联接,提高表面包覆层的稳定性。其中用到的表面包覆剂是生物体中提取的蛋白分子,具有极高的生物兼容性,对于利用上转换荧光纳米材料进行活体成像研究的开展创造了便利。 | ||||||
| 18 | 一种上转换荧光纳米材料的表面包覆方法 | CN201210060849.9 | 2012-03-09 | CN102618257A | 2012-08-01 | 王丹; 钱骏; 詹求强; 何赛灵 |
| 本发明属于光子学及材料学交叉技术领域,基于研究简单高效、生物兼容性好的上转换荧光纳米材料包覆方法的思路,采用牛血清蛋白作为表面活性剂,在超声分散的四氢呋喃和水混合液中,利用反溶剂法对上转换荧光纳米材料表面进行牛血清蛋白包覆,随后加入戊二醛将纳米材料表面的牛血清蛋白分子进行联接,提高表面包覆层的稳定性。其中用到的表面包覆剂是生物体中提取的蛋白分子,具有极高的生物兼容性,对于利用上转换荧光纳米材料进行活体成像研究的开展创造了便利。 | ||||||
| 19 | 基于空芯反谐振光纤的生化传感器 | CN201910391587.6 | 2019-05-10 | CN110174380A | 2019-08-27 | 王秀红; 尹晓燕; 乔鹏飞 |
| 基于空芯反谐振光纤的生化传感器,属于生物医学光子学中的生物光纤传感领域。空芯反谐振光纤的优越的光学特征,即极大的光谱带宽、低折射率溶剂匹配性和低损耗,可以使光与物质的相互作用达到最大化。利用这一特点,通过物理吸附、离子吸附或化学吸附的方法将所需材料修饰在光纤内壁,结合某些纳米材料的优异的荧光淬灭性能,以及适体识别单元的高度特异性,可以在光纤内部实现高灵敏,无标记检测。由于整个传感界面是基于光纤内部,提高了抗外界参数干扰的能力,保证了光纤传感平台的稳定性,提高了定量检测灵敏度。 | ||||||
| 20 | 一种基于空芯光子晶体光纤载体的活细胞生物激光器 | CN201310633590.7 | 2013-12-02 | CN103682966B | 2016-11-02 | 王秀红; 杨铁山; 王璞 |
| 本发明公开了一种基于空芯光子晶体光纤载体的活细胞生物激光器,属于激光技术与生物光子学领域。该激光器包括泵浦源、光学准直系统、活细胞激光增益介质、空芯光子晶体光纤以及光学元件;泵浦光进入光学准直系统准直,聚焦到增益介质上,增益介质为表达荧光蛋白的活细胞,将充填活细胞的光子晶体光纤两端加上高反射平面反射镜,使光纤在两个镜面之间形成光学谐振腔。本发明应用新型的光子晶体光纤光学谐振腔使活细胞产生激光,同时利用光子晶体光纤,谐振腔内可以容纳多个细胞,产生的荧光强度大大增强,发出的激光很容易探测记录。 | ||||||
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