| Patent application number | Description | Published |
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| 20100046902 | BIOPOLYMER PHOTONIC CRYSTALS AND METHOD OF MANUFACTURING THE SAME - A method of manufacturing a biopolymer photonic crystal includes providing a biopolymer, processing the biopolymer to yield a biopolymer matrix solution, providing a substrate, casting the matrix solution on the substrate, and drying the biopolymer matrix solution to form a solidified biopolymer film. A surface of the film is formed with a nanopattern, or a nanopattern is machined on a surface of the film. In another embodiment, a plurality of biopolymer films is stacked together. A photonic crystal is also provided that is made of a biopolymer and has a nanopatterned surface. In another embodiment, the photonic crystal includes a plurality of nanopatterned films that are stacked together. | 02-25-2010 |
| 20100063404 | BIOPOLYMER OPTICAL WAVEGUIDE AND METHOD OF MANUFACTURING THE SAME - A method of manufacturing a biopolymer optical waveguide includes providing a biopolymer, unwinding the biopolymer progressively to extract individual biopolymer fibers, and putting the unwound fibers under tension. The tensioned fibers are then cast in a different polymer to form a biopolymer optical waveguide that guides light due to the difference in indices of refraction between the biopolymer and the different polymer. The optical fibers may be used in biomedical applications and can be inserted in the body as transmissive media. Printing techniques may be used to manufacture the biopolymer optical waveguides. | 03-11-2010 |
| 20100065784 | ELECTROACTIVE BIOPOLYMER OPTICAL AND ELECTRO-OPTICAL DEVICES AND METHOD OF MANUFACTURING THE SAME - A method of manufacturing a biopolymer optical device includes providing a polymer, providing a substrate, casting the polymer on the substrate, and enzymatically polymerizing an organic compound to generate a conducting polymer between the provided polymer and the substrate. The polymer may be a biopolymer such as silk and may be modified using organic compounds such as tyrosines to provide a molecular-level interface between the provided bulk biopolymer of the biopolymer optical device and a substrate or other conducting layer via a tyrosine-enzyme polymerization. The enzymatically polymerizing may include catalyzing the organic compound with peroxidase enzyme reactions. The result is a carbon-carbon conjugated backbone that provides polymeric “wires” for use in polymer and biopolymer optical devices. An all organic biopolymer electroactive material is thereby provided that provides optical functions and features. | 03-18-2010 |
| 20100068740 | MICROFLUIDIC DEVICE WITH A CYLINDRICAL MICROCHANNEL AND A METHOD FOR FABRICATING SAME - A method of manufacturing a microfluidic device having at least one cylindrical microchannel includes providing a substrate, casting an uncured polymer matrix solution onto the substrate, embedding an elongated rod in the uncured polymer matrix solution, curing the polymer matrix solution to form a solidified body, and extracting the elongated rod to form the cylindrical microchannel in the solidified body. In another embodiment, the method includes forming an optical feature on a surface of the microfluidic device. A microfluidic device is also provided, the device including a polymer body, and at least one cylindrical microchannel in the polymer body, the cylindrical microchannel having a diameter between approximately 40 ?m and 250 ?m, inclusive. An additional microfluidic device is provided that functions as an optofluidic spectrometer. The optofluidic spectrometer includes a polymer body, a diffraction grating integrated within the polymer body, and a cylindrical microchannel behind the diffraction grating on the polymer body. | 03-18-2010 |
| 20100070068 | BIOPOLYMER SENSOR AND METHOD OF MANUFACTURING THE SAME - A method of manufacturing a biopolymer sensor including providing a biopolymer, processing the biopolymer to yield a biopolymer matrix solution, adding a biological material in the biopolymer matrix, providing a substrate, casting the matrix solution on the substrate, and drying the biopolymer matrix solution to form a solidified biopolymer sensor on the substrate. A biopolymer sensor is also provided that includes a solidified biopolymer film with an embedded biological material. | 03-18-2010 |
| 20100096763 | BIOPOLYMER OPTOFLUIDIC DEVICE AND METHOD OF MANUFACTURING THE SAME - A method of manufacturing a biopolymer optofluidic device including providing a biopolymer, processing the biopolymer to yield a biopolymer matrix solution, providing a substrate, casting the biopolymer matrix solution on the substrate, embedding a channel mold in the biopolymer matrix solution, drying the biopolymer matrix solution to solidify biopolymer optofluidic device, and extracting the embedded channel mold to provide a fluidic channel in the solidified biopolymer optofluidic device. In accordance with another aspect, an optofluidic device is provided that is made of a biopolymer and that has a channel therein for conveying fluid. | 04-22-2010 |
| 20100120116 | NANOPATTERNED BIOPOLYMER OPTICAL DEVICE AND METHOD OF MANUFACTURING THE SAME - A method of manufacturing a nanopatterned biopolymer optical device includes providing a biopolymer, processing the biopolymer to yield a biopolymer matrix solution, providing a substrate with a nanopatterned surface, casting the biopolymer matrix solution on the nanopatterned surface of the substrate, and drying the biopolymer matrix solution to form a solidified biopolymer film on the substrate, where the solidified biopolymer film is formed with a surface having a nanopattern thereon. In another embodiment, the method also includes annealing the solidified biopolymer film. A nanopatterned biopolymer optical device includes a solidified biopolymer film with a surface having a nanopattern is also provided. | 05-13-2010 |
| 20100272651 | METHOD FOR ASSESSING POTENTIAL FOR TUMOR DEVELOPMENT AND METASTASIS - The present invention generally provides methods for assessing the potential of tumor formation and/or metastasis using a combination (e.g., a ratio) of the number of circulating tumor cells and the number of circulating cells exhibiting autofluorescence within a selected wavelength region (e.g., red autofluorescence). In one aspect, it is directed to a method for providing likelihood of occurrence of a primary and/or a metastatic cancerous tumor in an animal, which comprises inoculating the animal with a plurality of cancer cells, determining a ratio of a number of cancer cells relative to a number of circulating indicator cells (e.g., immature leukocytes) that exhibit autofluorescence in the inoculated animal's blood and correlating the ratio to a likelihood that the animal will develop at least one primary and/or metastatic cancerous tumor, e.g., by way of assigning a probability for tumor development and/or metastasis based on the measured ratio. The method can also be utilized in human studies using, e.g., contrast agents to identify the circulating tumor cells. | 10-28-2010 |
| 20100292543 | Analysis of Endogenous Fluorescence Images to Extract Morphological/Organization Information About Living Samples - Methods and computer program products for analyzing tissue are provided. The tissue is exposed to light at the appropriate wavelengths for inducing fluorescence. Images of the fluorescing tissue are taken at two or more depths within the tissue. The PSD function is determined for each image at a different depth within the tissue. A characteristic of each PSD function determined is compared, and it is determined whether or not the tissue exhibits a pre-cancerous characteristic. | 11-18-2010 |
| 20110109910 | NON-INVASIVE OPTICAL CHARACTERIZATION OF BIOMATERIAL MINERALIZATION - In one aspect, the present invention generally provides methods for characterizing mineralization of a material, e.g., a biomaterial, by illuminating the material with radiation and analyzing radiation scattered from the material in response to the illumination. For example, in some embodiments, a material can be illuminated with polarized radiation at a plurality of wavelengths and the elastically scattered radiation corresponding to two or more of those wavelengths can be collected at two polarizations: one parallel and the other perpendicular to the illumination polarization. A differential intensity of the scattered radiation at the two polarizations can be analyzed as a function of wavelength to obtain information regarding the morphology of mineral deposits in the sample. Further, the total scattered radiation can be analyzed to derive information regarding the level of mineralization. | 05-12-2011 |
