Provided are systems and methods for treating a biological fluid, e.g., to inactivate pathogens.

The invention describes a method and a walk through apparatus to treat surfaces with hydroxyl ions to reduce the viability and/or kill pathogens.

Provided are systems and methods for treating a biological fluid, e.g., to inactivate pathogens.

A method of lamellar corneal graft implantation is disclosed herein. In one or more embodiments, the method includes the steps of: (i) modifying a genetic component of a lamellar cornea or other tissue of an animal so that the lamellar cornea or other tissue of the animal can be used for human transplantation; (ii) decellularizing the lamellar cornea or other tissue ex vivo using chemical means; (iii) modifying a shape of the lamellar cornea or other tissue before or after transplantation; and (iv) applying a photosensitizer and ultraviolet radiation to the lamellar cornea or other tissue so as to crosslink collagen and intercellular proteins of the lamellar cornea or other tissue, kill the cells exposed to the photosensitizer, and eliminate an immune response by a host to the implanted lamellar cornea or the tissue.

Methods and compositions for the prevention or reduction of platelet transfusion associated complications are provided. The subject methods include modifying donor whole blood or platelets prior to transfusion to prevent or reduce alloimmune platelet refractoriness.

A photosensitizer formulation can be disposed on or in a mesh; net; netting; screen; curtain of strands, fibers, or monofilaments; substrate, personal protective gear, mask, or any other suitable object. The photosensitizer formulation, when in contact with molecular oxygen and activated by light or ultrasound, produces microbicidal singlet oxygen. A variety of different arrangements and applications are described. For example, an air flow device may also be included to generate a flow of air through or over the photosensitizer formulation. A fluorescent formulation may be included to monitor photobleaching. The photosensitizer formulation may be disposed in a concentration gradient to generate antigenic particles by damaging or destroying microbes.

A photosensitizer formulation can be disposed on or in a container. The photosensitizer formulation, when in contact with molecular oxygen and activated by light or ultrasound, produces microbicidal singlet oxygen. A variety of different arrangements and applications are described. For example, an air flow device may also be included to generate a flow of air through or over the photosensitizer formulation.

An object of the invention is to provide a means for accomplishing inactivation of a pathogen in a blood sample containing red blood cells and platelets together, as well as sufficiently reducing the hemolysis rate of the red blood cell product finally obtained.

The means is to irradiate ultraviolet ray to a blood sample containing red blood cells and platelets in the presence of a hemolysis inhibitor and a surfactant having an HLB value of 13 or greater and having the number of oxyethylene groups of a hydrophilic portion in the molecular structure of 20 or greater when producing a blood product containing red blood cells and platelets.

Antimicrobial films for generating singlet oxygen and their use is described. The antimicrobial films are generally thin films having two surfaces or faces. The first surface of the film is adhesive. Various adhesives, including, electrostatic charges, are possible. The second surface faces in a direction opposite from the first surface. The second surface of the film emits singlet oxygen when activated by light or ultrasound. Various photosensitizers can be incorporated onto the second surface of the films for generating the singlet oxygen. The singlet oxygen and other radical species generated from the antimicrobial films diffuses out from and in proximity to the films to form a layer or cloud of singlet oxygen at a concentration sufficient to inactivate microbial particles, e.g., viruses and other pathogens, that come within the singlet oxygen layer to provide a protective zone against microbial particles.

A method of inactivating harmful microorganisms of a filtration medium including pathogenic bacteria and viruses is disclosed which includes placing a predetermined quantity of a hybridized fluorescent silk on to a filtration medium, applying light for a predetermined amount of time to the placed quantity of the hybridized fluorescent silk, and passing a fluid through the medium, wherein the fluid is one of substantially air or substantially water,

wherein the hybridized fluorescent silk is one of KillerRed, SuperNova, KillerOrange, Dronpa, TurboGFP, mCherry, or any combination thereof.