Polymeric particles are provided for use in therapeutic and/or diagnostic procedures. The particles include poly[bis(trifluoroethoxy)phosphazene and/or a derivative thereof which may be present throughout the particles or within an outer coating of the particles. The particles may also include a core having a hydrogel formed from an acrylic-based polymer. Such particles may be provided to a user in specific selected sizes to allow for selective embolization of certain sized blood vessels or localized treatment with an active component agent in specific clinical uses. Particles of the present invention may further be provided as color-coded microspheres or nanospheres to allow ready identification of the sized particles in use. Such color-coded microspheres or nanospheres may further be provided in like color-coded delivery or containment devices to enhance user identification and provide visual confirmation of the use of a specifically desired size of microspheres or nanospheres.

The present disclosure pertains to crosslinkable compositions and systems as well as methods for forming crosslinked compositions in situ, including the use of the same for controlling the movement of bodily fluid within a patient, among many other uses.

The present disclosure provides compositions including self-degrading alginate particles comprising alginate, alginate lyase, and divalent metal ions. The present disclosure also provides methods of making compositions including self-degrading alginate particles comprising alginate, alginate lyase, and divalent metal ions. The present disclosure also provides methods of inducing an embolism in a subject in thereof, and syringes containing the compositions of the present disclosure for use in the methods thereof.

An object is to provide a preparation for forming emboli highly safe in a living body and capable of retaining and controlled-releasing an anticancer agent, occluding a blood vessel when injected into the blood vessel, unlikely to be washed out and having a controlled decomposition time (i.e., occludes a blood vessel for a while and quickly decomposes to prevent the necrosis of the entire tissues when the function is completed). The preparation for forming emboli according to the present invention comprises a solution comprising a phenolic hydroxyl group-modified polymer represented by the following formula (1): wherein P is a biocompatible polymer, A is a single bond or an —OCO—C.sub.2-C.sub.4-alkenylene group, a —CONH—C.sub.1-C.sub.4-alkylene group or an —HNCO—C.sub.1-C.sub.4-alkylene group, and X is hydrogen or a C.sub.1-C.sub.3-alkoxy group, a solution comprising at least one selected from a peroxidase, a laccase, a tyrosinase, a catalase and an iron porphyrin complex and a solution comprising hydrogen peroxide.

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In some aspects, the disclosure pertains to injectable particles that contain at least one pH-altering agent that is configured to be released from the injectable particles in vivo, upon embolization of an intratumoral artery of a tumor with the injectable particles. In certain instances, the pH-altering agent may be a basic agent having a pH value of 7.5, a buffering agent having a pKa value of 7.6 or more, or both. Other aspects of the disclosure pertain to preloaded containers containing such injectable particles and methods of using such injectable particles.

The present invention relates to a medical Au—Pt—Pd alloy including Au, Pt, Pd, and inevitable impurities. The alloy has an alloy composition inside a polygon (A1-A2-A3-A4-A5-A6) surrounded by straight lines connected at point A1 (Au: 37.9 atom %, Pt: 0.1 atom %, and Pd: 62 atom %), point A2 (Au: 79.9 atom %, Pt: 0.1 atom %, and Pd: 20 atom %), point A3 (Au: 79.9 atom %, Pt: 20 atom %, and Pd: 0.1 atom %), point A4 (Au: 69.9 atom %, Pt: 30 atom %, and Pd: 0.1 atom %), point A5 (Au: 49 atom %, Pt: 30 atom %, and Pd: 21 atom %), and point A6 (Au: 39 atom %, Pt: 40 atom %, and Pd: 21 atom %) in a Au—Pt—Pd ternary state diagram. The metal structure of the alloy is optimized, and the metal structure is close to a single-phase structure, and has little precipitation of a Au-rich phase and a Pt-rich phase different in composition from a mother phase.

Shape memory materials (SMM) are formed as coil-shaped vascular occlusion devices upon deployment. Shape memory polymer (SMP) materials are tailored through formulation for specific mechanical behavior of the coils. Concurrent coil diameter changes enhance the relative change in stiffness along the length of the coil. Interconnecting structures (104a/b) are formed on ends of elongated members (102a) in the pre-deployment shape for multiple coil insertion capability within an introducer. Channels (206) are formed in pre-deployment shape, elongate members (202) that allow access for injection of imaging contrast agent or concurrent placement of instruments. A single SMM occlusive device (300) transforms into multiple, smaller diameter coils (302b) in the deployed state to generate a complex occlusive structure. A SMM occlusive device (400) has a collapsed fabric (404) component attached to and extending along a sidewall during storage and insertion, and then deploys as a coil (402b) to form a single- or multiple-layer occlusive fabric surface within a center of the coil (402b).

This disclosure relates to dermal treatment compositions, such as dermal fillers and tissue glues, and injectable compositions that incorporate one or more cationic steroidal antimicrobials (CSAs). The CSAs are incorporated into the dermal treatment compositions to provide effective antimicrobial, anti-inflammatory, analgesic, anti-swelling and/or tissue-healing properties. A treatment composition includes a component formed from a biologically compatible material suitable for injection into and/or application onto tissue at a treatment site. One or more CSA compounds are mixed with the biologically compatible material so that the one or more CSA compounds are incorporated within the composition, forming a reservoir of CSA compounds within the resulting bolus of the treatment composition after injection and/or application.

Biodegradable, cross-linked polymer particle embolics and methods of making the same are described. The particle embolics can be used as embolization agents.

Methods for the diagnosis and treatment of nonstenotic carotid plaques and symptomatic nonstenotic carotid disease (SyNC) are described. In particular, methods of evaluating the presence of unstable plaque/thrombus and methods of treatment that include deploying plaque stabilizers (PSs) into the cerebral vasculature are described. The invention further describes plaque stabilizers, uses of plaque stabilizers and plaque stabilizer kits.