The present invention relates to a process for sterilizing implantable biomaterials. In particular, the invention relates to a process for sterilizing collagen-containing implantable biomaterials and storage thereafter.

The present invention relates to a process for sterilizing implantable biomaterials. In particular, the invention relates to a process for sterilizing collagen-containing implantable biomaterials and storage thereafter.

The invention provides compositions containing hemoglobin, particularly PEGylated hemoglobin. The PEGylated hemoglobin molecule is capable of transferring oxygen or carbon monoxide bound thereto to a tissue with which it is in proximity. Exemplary PEGylated hemoglobin formulations of the invention are virally inactivated. Various compositions of the invention include deoxygenated hemoglobin, which may be conjugated with one or more water-soluble polymer. PEGylated hemoglobin includes those species in which the iron atom of the hemoglobin molecule is not bound to oxygen or any other species, and hemoglobin molecules in which a species other than oxygen, e.g., carbon monoxide, is bound to the iron atom. The compositions of the invention are formulated as hypo-, iso- or hypertonic solutions of the PEGylated hemoglobin. The compositions are of use to treat and/or ameliorate disease, injury and insult by providing for the oxygenation of tissues and/organs.

Disclosed herein is a formulation comprising an extracellular vesicle (EV), and a therapeutic active agent induced or embedded in the EV. According to preferred embodiments of the present disclosure, the EV is isolated from umbilical cord mesenchymal stem cells, and the active agent may be a growth factor, an immune-modulating agent, a small molecule, an siRNA, cDNA or a plant ingredient; for example, curcumin. Also disclosed herein are methods for producing the present formulation, and uses of the present formulation in the treatment of various diseases.

The invention relates to a method for inactivating viruses, characterized in that an immunogenic composition or vaccine comprising at least one virus is irradiated with electron beams, said immunogenic composition or vaccine comprising at least one virus (i) being liquid, in particular being a suspension and (ii) comprising at least one viral immunogen, wherein the antigen structure is preferably substantially retained.

The present invention provides compositions and methods of use of nanoparticle-based probes for in vivo imaging and therapy. The probes can be used to track diseased target cells by non-invasive imaging in the near-infrared range. Additionally, the probes can induce cell death of the target cells via photodynamic treatment.

A method and apparatus for reducing or inactivating pathogens in units of whole blood. A plurality of superparamagnetic nanoparticles (SPN) is coated with a mixture of chemiluminescence light-generating compounds and photodynamic broad-spectrum anti-viral compounds, and the mixture in introduced into a bag of whole blood. A rapidly-changing electromagnetic field is applied to the bag to cause uniform distribution of the nanoparticles within the whole blood throughout all regions of the blood bag, including the opaque interior of the bag. The blood is processed for a predetermined processing time period, during which the chemiluminescence light activates the broad-spectrum antiviral capacity of the photodynamic compounds to achieve reduction or inactivation of pathogens throughout the blood bag. After the processing time is elapsed, the nanoparticles are removed from the processed blood by a magnetic field. The processed blood may be washed by conventional means, to remove residual reagents, and transferred into a new, sterile blood bag.

A method and apparatus for reducing or inactivating pathogens in units of whole blood. A plurality of superparamagnetic nanoparticles (SPN) is coated with a mixture of chemiluminescence light-generating compounds and photodynamic broad-spectrum anti-viral compounds, and the mixture in introduced into a bag of whole blood. A rapidly-changing electromagnetic field is applied to the bag to cause uniform distribution of the nanoparticles within the whole blood throughout all regions of the blood bag, including the opaque interior of the bag. The blood is processed for a predetermined processing time period, during which the chemiluminescence light activates the broad-spectrum antiviral capacity of the photodynamic compounds to achieve reduction or inactivation of pathogens throughout the blood bag. After the processing time is elapsed, the nanoparticles are removed from the processed blood by a magnetic field. The processed blood may be washed by conventional means, to remove residual reagents, and transferred into a new, sterile blood bag.

The invention relates to a method for inactivating viruses, characterized in that an immunogenic composition or vaccine comprising at least one virus is irradiated with electron beams, said immunogenic composition or vaccine comprising at least one virus (i) being liquid, in particular being a suspension and (ii) comprising at least one viral immunogen, wherein the antigen structure is preferably substantially retained.

The present invention provides compositions and methods of use of nanoparticle-based probes for in vivo imaging and therapy. The probes can be used to track diseased target cells by non-invasive imaging in the near-infrared range. Additionally, the probes can induce cell death of the target cells via photodynamic treatment.