Silk-Elastinlike Protein Polymer Liquid Chemoembolic for Localized Release of Doxorubicin and Sorafenib.

Locoregional therapies for cancer are minimally invasive procedures in which the treatment is administered directly into cancerous tissue. Transarterial chemoembolization (TACE) is used to treat intermediate stage hepatocellular carcinoma (HCC). TACE uses an embolic material to block blood flow while coadministering a chemotherapeutic to the neoplastic tissue. Liquid embolics capable of drug loading are at the forefront of development as they allow for deeper permeation of tumor vasculature, increase neoplasm exposure to therapeutics, and resist revascularization by occupying both large and small diameter vessels. In this work, two chemotherapeutics used in the treatment of HCC, doxorubicin and sorafenib, were incorporated into the in situ gelling liquid embolic composed of a silk-elastinlike protein polymer (SELP-815 K). The base forms of the drugs had no significant effect on the viscosity, the gelation kinetics, and the gel stiffness of the SELP: all properties essential for the successful performance of an injectable liquid embolic. In vitro release studies indicated that the SELP liquid embolic delivered doxorubicin and sorafenib, either alone or in combination, at therapeutically relevant concentrations for a minimum of 14 and 30 days, respectively.

Development and use of an attenuated total reflectance/fourier transform infrared (ATR/FT-IR) spectral database to identify foreign matter in cotton.

The presence of foreign matter in cotton seriously affects the cotton grade and thus the price per bale paid by the spinner to the grower, the efficiency of the spinning and ginning operations, and the quality of the final woven product. Rapid identification of the nature of the extraneous matter in cotton at each stage of cleaning and processing is necessary to permit actions to eliminate or reduce its presence and improve efficiency and quality. Although several instruments are being successfully employed for the measurement of contamination in cotton fibers based on particle size/weight, no commercial instrument is capable of accurate qualitative identification of contaminants. To this end, ATR/FT-IR spectra of retrieved foreign matter were collected and subsequently rapidly matched to an authentic spectrum in a spectral database. The database includes contaminants typically classified as "trash", cotton plant parts (hull, shale, seed-coat fragments, bract, cacyx, leaf, bark, sticks, and stems) and grass plant parts (leaf and stem); "foreign objects and materials", synthetic materials (plastic bags, film, rubber, bale wrapping and strapping); organic materials (other fibers, yarns, paper, feathers, and leather); plus entomological and physiological sugars and inorganic materials (sand and rust). The spectral matching resulted in consistently high-score identification of the foreign matter based on chemical composition, irrespective of its particle size. The method is envisioned to be employed with stand-alone rugged infrared instrumentation to provide specific identification of extraneous materials in cotton as opposed to only general classification of the type by particle size or shape.