The disclosure herein relates to systems, methods, and devices for medical image analysis, diagnosis, risk stratification, decision making and/or disease tracking. In some embodiments, the systems, devices, and methods described herein are configured to analyze non-invasive medical images of a subject to automatically and/or dynamically identify one or more features, such as plaque and vessels, and/or derive one or more quantified plaque parameters, such as radiodensity, radiodensity composition, volume, radiodensity heterogeneity, geometry, location, and/or the like. In some embodiments, the systems, devices, and methods described herein are further configured to generate one or more assessments of plaque-based diseases from raw medical images using one or more of the identified features and/or quantified parameters.

Disclosed herein are modified chromium-dpoed zinc gallate (ZGC) nanocubes, which are characterized in respectively having a concave surface that is modified with (3-aminopropyl)triethoxysilane (APTES). The modified ZGC nanocubes produce long lasting luminescence (LLL) that lasts for at least 1.5 hours under X-ray or UV excitation. Also disclosed herein are methods for the preparation of the modified ZGC nanocubes; and methods for imaging an area of interest (e.g., cancer) in a live subject using the modified ZGC nanocubes as an imaging agent.

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 embolizing vasculature including the neurovasculature within a patient, among many other uses.

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 embolizing vasculature including the neurovasculature within a patient, among many other uses.

Embodiments are directed to a method for monitoring pediatric colonic motility having the steps of administering an ingestible and dissolvable capsule to a pediatric patient, wherein the capsule contains a plurality of radiopaque markers; and performing a radiograph on the pediatric patient to identify the location of at least one of the plurality of radiopaque markers within the pediatric patient's colon.

The present disclosure pertains to iodinated polysaccharide compounds that comprise a polysaccharide backbone that comprises a plurality of carboxyl groups and a plurality of iodinated side groups. The present disclosure also pertains iodinated polysaccharide compounds in which at least a portion of carboxyl groups that are present in a carboxyl-containing polysaccharide chain are functionalized with a plurality of iodinated side groups. Other aspects of the present disclosure pertain to methods of forming iodinated polysaccharide compounds, medical compositions comprising iodinated polysaccharide compounds, medical procedures comprising introducing such medical compositions into or between tissue of a patient, and medical kits that comprise such medical compositions.

A radio-opaque composition is formulated to enable a clinician to apply custom markings to a surface, such as a patient's skin or a surgical drape on the patient. More specifically, the radio-opaque composition may be used to write on the surface. The markings may be well-defined and contrast with the surface to which they are applied. Such a composition may include a liquid radio-opaque component that includes one or more radio-opaque materials that have been dissolved in a solvent, as well as a solid radio-opaque component with particles of one or more radio-opaque materials dispersed throughout a carrier, such as the solvent of the liquid radio-opaque component. Marking apparatuses that may be used to write with the radio-opaque composition are also disclosed, as are methods for using the radio-opaque composition.

A radio-opaque composition is formulated to enable a clinician to apply custom markings to a surface, such as a patient's skin or a surgical drape on the patient. More specifically, the radio-opaque composition may be used to write on the surface. The markings may be well-defined and contrast with the surface to which they are applied. Such a composition may include a liquid radio-opaque component that includes one or more radio-opaque materials that have been dissolved in a solvent, as well as a solid radio-opaque component with particles of one or more radio-opaque materials dispersed throughout a carrier, such as the solvent of the liquid radio-opaque component. Marking apparatuses that may be used to write with the radio-opaque composition are also disclosed, as are methods for using the radio-opaque composition.

A platinum sulfide protein nanoparticle having near-infrared photothermal effect and multi-modal imaging function, a preparation method therefor and an application thereof. The platinum sulfide nanoparticle having near-infrared photothermal effect and multi-modal imaging function is prepared in aqueous phase by means of formulation screening and process limitation. The nanoparticle has an ultra-small particle size and good stability as well as tumor targeting and photothermal effects and integrates functions of near-infrared imaging, CT imaging, and thermal imaging, so as to achieve high sensitivity, high resolution, and precise positioning of tumors, and to produce high-efficiency photothermal effects under the excitation of near-infrared light to kill tumor cells by thermal ablation, thereby achieving the purpose of efficient, safe, visual, and accurate treatment of tumors. The nanoparticle has the potential for further development and clinical application.

A platinum sulfide protein nanoparticle having near-infrared photothermal effect and multi-modal imaging function, a preparation method therefor and an application thereof. The platinum sulfide nanoparticle having near-infrared photothermal effect and multi-modal imaging function is prepared in aqueous phase by means of formulation screening and process limitation. The nanoparticle has an ultra-small particle size and good stability as well as tumor targeting and photothermal effects and integrates functions of near-infrared imaging, CT imaging, and thermal imaging, so as to achieve high sensitivity, high resolution, and precise positioning of tumors, and to produce high-efficiency photothermal effects under the excitation of near-infrared light to kill tumor cells by thermal ablation, thereby achieving the purpose of efficient, safe, visual, and accurate treatment of tumors. The nanoparticle has the potential for further development and clinical application.