The purpose of this invention is to prepare lanthanum (La) supported tin oxide-titania (SnO.sub.2—TiO.sub.2) nanoparticles in the presence of three different solvents (Ethyl acetate, Benzyl alcohol, Ethylene glycol) as directing medium, through sol-gel followed by hydrothermal method for nanofiltration system.

A method for separating microplastics from an animal feces, the method including: 1) freeze-drying an animal fecal sample; 2) transferring the animal fecal sample dried in 1) into a beaker, adding a Fenton's reagent; stirring a mixture of the animal fecal sample and the Fenton's reagent until no bubbles were produced; constantly adding the Fenton's reagent to the mixture; filtering the mixture through a plurality of cellulose nitrate-cellulose acetate (CN-CA) membranes, and transferring the plurality of CN-CA membranes into a plurality of 500 mL beakers; adding 100 mL of 65% HNO.sub.3 to each beaker, placing the each beaker in a water bath firstly at 50° C. for 30 min and then at 70° C. for 15 min; cooling the each beaker in an ice bath, and filtering a solution in the each beaker through a first polytetrafluoroethylene (PTFE) membrane; and 3) transferring the first PTFE membrane into a 500 mL beaker.

A method for separating microplastics from an animal feces, the method including: 1) freeze-drying an animal fecal sample; 2) transferring the animal fecal sample dried in 1) into a beaker, adding a Fenton's reagent; stirring a mixture of the animal fecal sample and the Fenton's reagent until no bubbles were produced; constantly adding the Fenton's reagent to the mixture; filtering the mixture through a plurality of cellulose nitrate-cellulose acetate (CN-CA) membranes, and transferring the plurality of CN-CA membranes into a plurality of 500 mL beakers; adding 100 mL of 65% HNO.sub.3 to each beaker, placing the each beaker in a water bath firstly at 50° C. for 30 min and then at 70° C. for 15 min; cooling the each beaker in an ice bath, and filtering a solution in the each beaker through a first polytetrafluoroethylene (PTFE) membrane; and 3) transferring the first PTFE membrane into a 500 mL beaker.

The present invention provides an improved method of quantitative and/or qualitative analysis of a target molecule using nitrocellulose membrane (NCM). In particular, the present invention provides a porous nitrocellulose membrane that includes a surface and an organic nanostructured molecule that is non-covalently attached to the surface of NCM. The organic nanostructured molecule has a branched region that includes a plurality of terminal region (e.g., terminal end) moieties that are non-covalently attached or bound to a surface of the porous NCM. The organic nanostructured molecule also comprises a linear region that includes a covalently attached capture molecule that is adapted to selectively bind to a target molecule. The NCM of the invention provides an improved reproducibility, reliability, and selectivity compared an NCM in the absence of the organic nanostructured molecule.

The present invention provides an improved method of quantitative and/or qualitative analysis of a target molecule using nitrocellulose membrane (NCM). In particular, the present invention provides a porous nitrocellulose membrane that includes a surface and an organic nanostructured molecule that is non-covalently attached to the surface of NCM. The organic nanostructured molecule has a branched region that includes a plurality of terminal region (e.g., terminal end) moieties that are non-covalently attached or bound to a surface of the porous NCM. The organic nanostructured molecule also comprises a linear region that includes a covalently attached capture molecule that is adapted to selectively bind to a target molecule. The NCM of the invention provides an improved reproducibility, reliability, and selectivity compared an NCM in the absence of the organic nanostructured molecule.

The present invention relates to cellulose based papers coated with nitrocellulose as well as to methods for producing such coated papers and methods for using them, especially in lateral flow applications.

The present invention relates to cellulose based papers coated with nitrocellulose as well as to methods for producing such coated papers and methods for using them, especially in lateral flow applications.

A composite membrane is disclosed that comprises a porous polyvinylidene fluoride (PVDF), polytetrafluoroethylene (PTFE) or nitrocellulose membrane body. The membrane also comprises graphene oxide disposed on a surface of the membrane body. An array comprising two or more such composite membranes is also disclosed. A method of preparing the composite membrane is also disclosed. Further, a method of removing natural organic matter (NOM) from NOM-contaminated water, or water suspected of being contaminated with NOM, is disclosed.

A composite membrane is disclosed that comprises a porous polyvinylidene fluoride (PVDF), polytetrafluoroethylene (PTFE) or nitrocellulose membrane body. The membrane also comprises graphene oxide disposed on a surface of the membrane body. An array comprising two or more such composite membranes is also disclosed. A method of preparing the composite membrane is also disclosed. Further, a method of removing natural organic matter (NOM) from NOM-contaminated water, or water suspected of being contaminated with NOM, is disclosed.

An apparatus is provided for the production of biomass or a bioproduct, the apparatus comprising: at least one elongate bioreactor, the bioreactor comprised of at least one outer membrane layer that defines a substantially tubular compartment that is capable of being filled with a liquid or gel, wherein the membrane layer is comprised of a material that is permeable to gas transfer across the membrane layer. A chamber is provided comprising walls that define and enclose a gaseous atmosphere within. At least a part of the bioreactor is located inside the chamber. A control system controls the composition of the atmosphere within the chamber and gas transfer occurs across the membrane layer of the bioreactor between the tubular compartment and the atmosphere comprised within the chamber. Methods of using the apparatus in order to manufacture biomass are also provided.