Training equipment is configured for targeted muscle actuation. The training equipment contains a muscle-powered actuating element and a damping system having two components that can move in relation to one another. One of the components is operatively connected to the actuating element, such that a movement of the actuating element can be damped. A field-sensitive rheological medium and a field generation system are associated with the damping system, in order to generate and control the field strength. A damping characteristic can be influenced by the field generation system. A control system is suited and configured to control the field generation system in a targeted manner in accordance with a training parameter, such that the movement of the actuating element can be damped taking into account the training parameter.

A method for removing retroviruses from liquid samples and a nanofiber containing liquid filtration medium that simultaneously exhibits high liquid permeability and high microorganism retention is disclosed. Retroviruses are removed from a liquid by passing the liquid through a porous nanofiber containing filtration medium having a retrovirus LRV greater than about 6, and the nanofiber(s) has a diameter from about 10 nm to about 100 nm. The filtration medium can be in the form of a fibrous electrospun polymeric nanofiber liquid filtration medium mat.

Water vapor transport membranes for ERV and other water vapor transport applications are provided. The membranes include a substrate and an air impermeable selective layer coated on the substrate, the selective layer including a cellulose derivative and a sulfonated polyaryletherketone. In some embodiments the sulfonated polyaryletherketone is in a cation form and/or the selective layer includes sPEEK and CA in an sPEEK:CA (wt.:wt.) ratio in the range of about 7:3 to 2:3. Methods for making such membranes are provided. The methods include applying a coating solution/dispersion to a substrate and allowing the coating solution/dispersion to dry to form an air impermeable selective layer on the substrate, the coating solution/dispersion including a cellulose derivative and a sulfonated polyarylether ketone. In some embodiments the sulfonated polyaryletherketone is in a cation form and/or the coating solution/dispersion includes sPEEK and CA in an sPEEK:CA (wt.:wt.) ratio in the range of about 7:3 to 2:3.

A blood purification membrane capable of adsorbing creatinine which is a uremic toxin in the blood and purifying the blood, the blood purification membrane including fibers and particles adhered to the aforementioned fibers, wherein the aforementioned fibers are composed of a polymer insoluble in water, the aforementioned particles contain SiO.sub.2 and Al.sub.2O.sub.3, and pores capable of incorporating at least a portion of the aforementioned uremic toxin are provided in the aforementioned particles.

A composition having the structure of formula I:
[RAr(COOH).sub.2].sub.x[Ar(COOH).sub.3].sub.2-xM.sub.3.sup.2+(I) is provided where M is Mn, Cu, Co, Fe, Zn, Cd, Ni, or Pt; R is a bromine, nitro, a primary amine, C.sub.1-C.sub.4 alkyl secondary amine, C.sub.1-C.sub.4 alkyl oxy, Br(C.sub.1-C.sub.4 alkyl), NO.sub.2(C.sub.1-C.sub.4 alkyl), a mercaptan, and reaction products of any of the aforementioned with acyl chlorides of the formulas: CH.sub.3(CH.sub.2).sub.mC(O)Cl, or CH.sub.3(CH(C.sub.1-C.sub.4 alkyl)CH.sub.2).sub.mC(O)Cl, or CH.sub.3(CH.sub.2).sub.m-Ph-(CH.sub.2).sub.pC(O)Cl, where Ph is a C.sub.6 phenyl or C.sub.6 phenyl with one or more hydrogens replaced with F, C.sub.1-C.sub.4 fluoroalkyl, or C.sub.1-C.sub.4 perfluoroalkyl; m is independently in each occurrence an integer of 0 to 12 inclusive; p is an integer of 0 to 36 inclusive, to form an amide, a thioamide, or an ester; Ar is a 1,3,5-modified phenyl, and 1.4>?>0. A process of synthesis thereof and the use to chemically modify a gaseous reactant are also provided.

Espun material may function as a filtration medium or be put to other uses. The espun material may comprise espun poly(tetrafluoroethylene) (espun PTFE). One or more layers of the espun material may be included. The properties of the espun material can be tailored. For example, a gradient fabric may include espun PTFE. The gradient fabric may include two or more layers of espun PTFE.

This invention provides a new high flux reverse osmosis (RO) membrane comprising a nanoporous polyethersulfone (PES)/polyethylene oxide-polysilsesquioxane (PEO-Si) blend support membrane (PES/PEO-Si) comprising a polyethylene oxide-polysilsesquioxane (PEO-Si) polymer and a polyethersulfone (PES) polymer, a hydrophilic polymer inside the pores on the skin layer surface of the polyethersulfone/polyethylene oxide-polysilsesquioxane blend support membrane, and a thin, nanometer layer of cross-linked polyamide on the skin layer surface of said polyethersulfone/polyethylene oxide-polysilsesquioxane blend support membrane, and a method of making such a membrane. This invention also provides a method of using the new high flux reverse osmosis membrane comprising nanoporous PES/PEO-Si blend support membrane for water purification.

Described herein are filtration membranes and related, compositions, methods and systems and in particular filtration membranes with embedded polymeric micro/nanoparticles and related compositions, methods, and systems.

A method for manufacturing an ion exchange membrane is provided. The method for manufacturing an ion exchange membrane, according to one embodiment of the present invention, comprises the step of electrospinning a support fiber producing solution and an ion exchange fiber producing solution respectively to prepare a laminate in which a support fiber mat consisting of a support fiber and an ion exchange fiber mat consisting of an ion exchange fiber are alternatively laminated. According to the present invention, it is possible to simply control factors, such as the thickness, electroconductivity and mechanical strength of the membrane, and the diameter/ratio of a pore, etc. to be suitable for the use of ion exchange membrane during the manufacturing process, to simplify the manufacturing process. As such, the ion exchange membrane manufactured by the method can be utilized as a universal ion exchange membrane which has a large ion exchange capacity, a small electrical resistance, and a small diffusion coefficient as well as excellent mechanical strength and durability.

Provided herein are methods for forming nanofibers. The current disclosure provides ceramic nanofibers, morphology-controlled ceramic-polymer hybrid nanofibers, morphology-controlled ceramic nanofibers, core-sheath nanofibers and hollow core nanofibers using ceramic precursor materials and polymer materials which are combined and undergo electrospinning. The current disclosure provides for methods of forming these nanofibers at low temperatures such as room temperature and in the presence of oxygen and moisture wherein the ceramic precursor cures to a ceramic material during the electrospinning process. Also disclosed are the nanofibers prepared by the disclosed methods.