Abstract: A method of treating bone deficiencies includes applying a biocompatible structure to an implant surgical site. The biocompatible structure includes multiple polymer layers stacked to have a predetermined shape, multiple bone particle layers disposed between each of two neighboring polymer layers of the multiple polymer layers, and a coating surrounding the polymer layers and bone particle layers. Each of the polymer layers is formed with a polymer and first tissue forming nanoparticles. The predetermined shape is configured to conform to the implant surgical site.

Abstract: A method of making a nanocomposite includes forming at least one gold nanorod; coating a silver layer on an outer surface of the gold nanorod; assembling a Raman reporter molecule layer on the coated silver layer; coating a pegylated layer on the assembled Raman reporter molecule layer; and conjugating the coated pegylated layer with an active layer, the active layer comprising at least one of a targeting molecule configured to bind to the target of interest and a functional molecule configured to interact with the target of interest.

Abstract: A method of making at least one nanocomposite for surface enhanced Raman spectroscopy (SERS) detection of a target of interest includes forming at least one gold nanorod; coating a silver layer on an outer surface of the gold nanorod; assembling a Raman reporter molecule layer on the coated silver layer, wherein the Raman reporter molecule layer comprises Raman reporter molecules that are detectable by the SERS; coating a thiolated polyethylene glycol (PEG) layer on the assembled Raman reporter molecule layer; and conjugating the coated thiolated PEG layer with molecules of an antibody to make the at least one nanocomposite.

Abstract: A nanoagent includes at least one nanocomposite. The nanocomposite includes at least one gold nanorod, a silver layer coated on an outer surface of the gold nanorod, a Raman reporter molecule layer coated on the silver layer, a pegylated layer coated on the Raman reporter molecule layer, an active layer conjugated to the pegylated layer. the active layer includes at least one of a targeting molecule configured to bind to a target of interest, and a functional molecule configured to interact with the target of interest. The silver layer has silver nanoparticles. The Raman reporter molecule layer has Raman reporter molecules that are detectable by surface enhanced Raman spectroscopy (SERS). The pegylated layer has at least one of thiolated polyethylene glycol (HS-PEG), thiolated polyethylene glycol acid (HS-PEG-COOH) and HS-PEG-NHx.

Abstract: A two dimensional (2D) active plasmonic scaffold includes a polymer film and one or more nanoparticle layers disposed on the polymer film. The nanoparticles has functional groups attached thereon. A three dimensional (3D) structure fabricated using the 2D scaffold.

Abstract: A nanoagent for surface enhanced Raman spectroscopy (SERS) detection of a target of interest, includes one or more nanocomposites. The target of interest may include at least one tumor cell or at least one pathogen. Each nanocomposite includes at least one gold nanorod, a silver layer coated on a surface of the gold nanorod and having silver nanoparticles, a Raman reporter molecule layer assembled on the silver layer and having Raman reporter molecules, a pegylated layer coated on the Raman reporter molecule layer, and an antibody layer conjugated to the pegylated layer. The different nanocomposites of the nanoagent can be represented by different colors when SERS images are collected upon the nanoagent.

Abstract: A biocompatible structure includes one or more base structures for regeneration of different tissues. Each base structure includes alternately stacked polymer layers and spacer layers. The polymer layer includes a polymer and tissue forming nanoparticles. The polymer includes polyurethane. The tissue forming nanoparticles includes hydroxypatites (HAP) nanoparticles, polymeric nanoparticles, or nanofibers. The spacer layer includes bone particles, polymeric nanoparticles, or nanofibers. The weight percentage of tissue forming nanoparticles to the polymer in the polymer layer in one base structure is different from that in the other base structures. A method of producing the biocompatible structure includes forming multiple base structures stacked together, coating the stacked multiple base structures, and plasma treating the coated structure.

Abstract: A biocompatible structure includes one or more base structures for regeneration of different tissues. Each base structure includes alternately stacked polymer layers and spacer layers. The polymer layer includes a polymer and tissue forming nanoparticles. The polymer includes polyurethane. The tissue forming nanoparticles includes hydroxypatites (HAP) nanoparticles, polymeric nanoparticles, or nanofibers. The spacer layer includes bone particles, polymeric nanoparticles, or nanofibers. The weight percentage of tissue forming nanoparticles to the polymer in the polymer layer in one base structure is different from that in the other base structures. A method of producing the biocompatible structure includes forming multiple base structures stacked together, coating the stacked multiple base structures, and plasma treating the coated structure.

Abstract: A nanocomposite for detection and treatment of a target of interest including tumor cells or pathogens includes at least one nanostructure, each nanostructure having a core and a shell surrounding the core; a reporter assembled on the shell of each nanostructure; and a layer of a treating agent and a targeting agent conjugated to the reporter. In use, the nanocomposite targets to the target of interest according to the targeting agent and releases the treating agent and the nanostructure therein for therapeutic treatment of the target of interest, and the target of interest transmits at least one signature responsive to the reporter for detection of the target of interest.

Abstract: A method for treatment of malignant cells includes administering to the malignant cells nanoparticles and etoposide. The nanoparticles are selected from the group consisting of single wall carbon nanotubes, silver nanoparticles, gold nanoparticles and combinations thereof.

Abstract: A method for regulating properties of a plant, includes: providing a nanoagent having at least one nanocomposite; and delivering the nanoagent to the plant. The nanocomposite has at least one gold nanorod, a silver layer coated on an outer surface of the gold nanorod, a pegylated layer coated on the silver layer, and an active layer conjugated to the pegylated layer. The silver layer includes silver nanoparticles. The pegylated layer includes at least one of thiolated polyethylene glycol (HS-PEG), thiolated polyethylene glycol acid (HS-PEG-COOH) and HS-PEG-NHx. The active layer includes at least one bio-active agent configured to interact with the plant. The bio-active agent can be 2,4-dichlorophenoxyacetic acid (2,4-D).

Abstract: In one aspect of the invention, a method for growth of carbon nanotubes includes providing a graphitic composite, decorating the graphitic composite with metal nanostructures to form graphene-contained powders, and heating the graphene-contained powders at a target temperature to form the carbon nanotubes in an argon/hydrogen environment that is devoid of a hydrocarbon source. In one embodiment, the target temperature can be as low as about 150° C. (±5° C.).

Abstract: A method of treating bone deficiencies includes applying a biocompatible structure to an implant surgical site. The biocompatible structure includes multiple polymer layers stacked to have a predetermined shape, multiple bone particle layers disposed between each of two neighboring polymer layers of the multiple polymer layers, and a coating surrounding the polymer layers and bone particle layers. Each of the polymer layers is formed with a polymer and first tissue forming nanoparticles. The predetermined shape is configured to conform to the implant surgical site.

Abstract: A structure of, and a method of producing, a biocompatible structure for bone and tissue regeneration are disclosed. The method includes dissolving a polyurethane polymer in methanol, adding hydroxyapatite (HAP) nanoparticles to form a uniformly distributed mixture, applying the mixture to a polytetrafluoroethylene (PTFE) surface to form a polymer film, cutting the polymer film into strips, stacking the strips with layers of bone particles disposed therebetween, coating the stacked strips and layers by the mixture and allowing it to dry, adding bone particles to the coating, and plasma treating the structure to form the biocompatible structure. A weight percentage of the HAP nanoparticles to the polymer is about 5-50% such that a resorption rate of the biocompatible structure substantially matches a rate of tissue generation in the biocompatible structure.

Abstract: The present invention encompasses a composition capable of delivering and expressing a nucleic acid encoding UDP-Glucuronosyltransferases, p53 or a combination thereof into a cell, and methods for treating tumors.

Abstract: A method for producing a biocompatible structure includes: obtaining a load graph and a stress graph representing a relationship between a weight percentage of tissue forming nanoparticles and a maximum load or maximum stress of a polymer film, respectively; determining a first and second weight percentage corresponding to a peak of the load graph and the stress graph respectively; determining an optimal weight percentage based on the first and second weight percentages; preparing a polymer film having the optimal weight percentage of the first tissue forming nanoparticles to the polymer; dividing the polymer film to multiple strips; constructing a scaffold by stacking the strips to form polymer layers and adding bone or composite particles between the polymer layers; applying a solution to the scaffold to form a coated scaffold; and adding second tissue forming particles to the coated scaffold to form the biocompatible structure.

Abstract: A method of increasing the probability and rate of seed germination, increasing vegetative biomass, and increasing water uptake in seeds, in which a seed is introduced to an effective concentration of carbon nanomaterial. The effective concentration of carbon nanomaterial is 10-200 ?g/mL.

Abstract: A nanoagent for surface enhanced Raman spectroscopy (SERS) detection of a target of interest, includes one or more nanocomposites. The target of interest may include at least one tumor cell or at least one pathogen. Each nanocomposite includes at least one gold nanorod, a silver layer coated on a surface of the gold nanorod and having silver nanoparticles, a Raman reporter molecule layer assembled on the silver layer and having Raman reporter molecules, a pegylated layer coated on the Raman reporter molecule layer, and an antibody layer conjugated to the pegylated layer. The different nanocomposites of the nanoagent can be represented by different colors when SERS images are collected upon the nanoagent.

Abstract: A nanoagent includes at least one nanocomposite. The nanocomposite includes at least one gold nanorod, a silver layer coated on an outer surface of the gold nanorod, a Raman reporter molecule layer coated on the silver layer, a pegylated layer coated on the Raman reporter molecule layer, an active layer conjugated to the pegylated layer. the active layer includes at least one of a targeting molecule configured to bind to a target of interest, and a functional molecule configured to interact with the target of interest. The silver layer has silver nanoparticles. The Raman reporter molecule layer has Raman reporter molecules that are detectable by surface enhanced Raman spectroscopy (SERS). The pegylated layer has at least one of thiolated polyethylene glycol (HS-PEG), thiolated polyethylene glycol acid (HS-PEG-COOH) and HS-PEG-NHx.

Abstract: Compositions comprising nanoparticles, such as silver or gold nanoparticles or carbon nanotubes (CNTs), and apoptotic agents are described. The nanoparticles can significantly enhance the cancer chemotherapeutic effects of the apoptotic agents. In particular, a highly increased anti-tumor activity has been demonstrated for the combination of etoposide and CNTs against HeLa cells compared to the administration of either etoposide alone or nanoparticles alone. Data provided by flow cytometry, Caspase 3 and other methods, suggest a strong interaction between the nanoparticles and the cellular structure, which can result in the improved effectiveness of chemotherapeutic agents. These findings provide potential new cancer therapies by carefully selecting the right combination of cytostatic drugs and nanostructural materials which synergistically provide significantly greater curative rates.