Abstract: The present disclosure provides compositions, methods, and kits comprising a nano-partition contained within a partition that allows for the separation and use of at least two enzymes in a partition-based assay of a biological sample, such as a single cell in a droplet. The compositions and methods are useful for carrying out partition-based assays of fixed biological samples.

Abstract: A mitochondria targeted gold nanoparticle (T-3-BP-AuNP) decorated with 3-bromopyruvate (3-BP) and delocalized lipophilic triphenylphosphonium (TPP) cations to target the mitochondrial membrane potential (??m) was developed for delivery of 3-BP to cancer cell mitochondria by taking advantage of higher ??m in cancer cell compared to normal cells. This construct showed remarkable anticancer activity in prostate cancer cells compared to non-targeted construct NT-3-BP-AuNP and free 3-BP. Anticancer activity of T-3-BP-AuNP was further enhanced upon laser irradiation by exciting the surface plasmon resonance band of AuNP and thereby utilizing a combination of 3-BP chemotherapeutic and AuNP photothermal effects. T-3-BP-AuNPs showed markedly enhanced ability to alter cancer cell metabolism by inhibiting glycolysis and demolishing mitochondrial oxidative phosphorylation in prostate cancer cells.

Abstract: Pt(IV) compounds include a mitochondria targeting moiety. One example of a Pt(IV) compound having a mitochondria targeting moiety is a Pt(IV) cisplatin-based compound. Upon reduction, the mitochondrial targeting moieties are released resulting in a Pt(II) therapeutic agent. Pt(IV) compounds including a mitochondria targeting moiety can be included in nanoparticles. The compounds or nanoparticles can be used to treat, for example, cancer.

Abstract: Nanoparticles include a core and one or more targeting moieties, as well as one or more contrast agents or one or more therapeutic agents. The contrast agents or therapeutic agents may be contained or embedded within the core. If the nanoparticle includes therapeutic agents, the agents are preferably released from the core at a desired rate. The core may be biodegradable and may release the agents as the core is degraded or eroded. The targeting moieties preferably extend outwardly from the core so that they are available for interaction with cellular components, which interactions will target the nanoparticles to the appropriate cells, such as apoptotic cells; organelles, such as mitochondria; or the like. The targeting moieties may be tethered to the core or components that interact with the core.

Abstract: Nanoparticles containing a mitochondrial that are capable of crossing the blood-brain barrier and that have a targeting moiety, an antioxidant and an anti-inflammatory agent may be useful for treatment of traumatic brain injury.

Abstract: Pt(IV) compounds include a mitochondria targeting moiety. One example of a Pt(IV) compound having a mitochondria targeting moiety is a Pt(IV) cisplatin-based compound. Upon reduction, the mitochondrial targeting moieties are released resulting in a Pt(II) therapeutic agent. Pt(IV) compounds including a mitochondria targeting moiety can be included in nanoparticles. The compounds or nanoparticles can be used to treat, for example, cancer.

Abstract: A mitochondria targeted gold nanoparticle (T-3-BP-AuNP) decorated with 3-bromopyruvate (3-BP) and delocalized lipophilic triphenylphosphonium (TPP) cations to target the mitochondrial membrane potential (??m) was developed for delivery of 3-BP to cancer cell mitochondria by taking advantage of higher ??m in cancer cell compared to normal cells. This construct showed remarkable anticancer activity in prostate cancer cells compared to non-targeted construct NT-3-BP-AuNP and free 3-BP. Anticancer activity of T-3-BP-AuNP was further enhanced upon laser irradiation by exciting the surface plasmon resonance band of AuNP and thereby utilizing a combination of 3-BP chemotherapeutic and AuNP photothermal effects. T-3-BP-AuNPs showed markedly enhanced ability to alter cancer cell metabolism by inhibiting glycolysis and demolishing mitochondrial oxidative phosphorylation in prostate cancer cells.

Abstract: Provides is a therapeutic technology that combines the phototoxic and immune-stimulating ability of photodynamic therapy with the widespread effectiveness of the immune system to reduce the viability of such as cancer cells and tumors. The nanoparticle compositions of the disclosure combine an immunostimulant with a photosensitizer using a nanoparticle delivery platform. For example, zinc pthalocyanine, which is a long-wavelength absorbing photosensitizer, integrated into a polymeric nanoparticle core made up of poly(D,L-lactic-co-glycolic acid)-b-poly(ethylene glycol) (PLGA-b-PEG). The outside surface of the core can be coated with metallic nanoparticles, which are then modified with CpG-ODN. Metastatic mouse breast carcinoma cells showed significant photocytotoxicity of the hybrid after irradiation with a 660 nm LASER light and this activity was remarkably better than either treatment alone.

Abstract: Nanoparticles containing a photosensitizer configured to generate a reactive oxygen species when exposed to an appropriate wavelength of light can be used to enhance immunogenicity of cancer cells, such as breast cancer cells. Such enhanced immunogenicity cancer cells, or supernatants thereof, can be used to activate dendritic cells or cause dendritic cells to produce INF-gamma. Nanoparticles having mitochondria-targeting moieties are more effective at enhancing the immunogenicity of the cancer cells, or causing the dendritic cells to produce IFN-gamma, than nanoparticle lacking mitochondria-targeting moieties or free photo sensitizer.

Abstract: Nanoparticles include a core and one or more targeting moieties, as well as one or more contrast agents or one or more therapeutic agents. The contrast agents or therapeutic agents may be contained or embedded within the core. If the nanoparticle includes therapeutic agents, the agents are preferably released from the core at a desired rate. The core may be biodegradable and may release the agents as the core is degraded or eroded. The targeting moieties preferably extend outwardly from the core so that they are available for interaction with cellular components, which interactions will target the nanoparticles to the appropriate cells, such as apoptotic cells; organelles, such as mitochondria; or the like. The targeting moieties may be tethered to the core or components that interact with the core.