A composition for treating a patient with a tissue disease or malformity has a composition containing amniotic fluid. The amniotic fluid has a quantity of gender specific amniotic fluid based on a gender of a fetal source. A method of treating a patient with a tissue disease or malformity comprises the steps of: identifying the tissue region to be treated and selecting a location to apply either topically or by injection or inhalation a composition containing amniotic fluid; selecting the composition containing amniotic fluid wherein the amniotic fluid has a quantity of gender specific amniotic fluid based on a gender of a fetal source allowing more specific targeted growth factors to be used for specific disease processes; and applying or injecting the composition at or into the selected location.

The present invention provides protein-polymer conjugates, and methods for generating biocompatible scaffolds formed of hydrogels comprising the conjugates and use of the scaffolds for tissue regeneration. The present invention provides improved processes for the preparation of the conjugates, wherein the conjugates of the invention are preferably produced in an environmentally friendly process avoiding polar organic solvents.

The invention relates to methods for producing a polymeric scaffold for use in tissue engineering applications or soft tissue surgery, as well as to the produced scaffolds and an associated kit. The method features a first fast drying step of applying a mechanical compression on a polymeric gel layer and a second slow drying step of the gel up to reach a polymer mass fraction of at least 60% w/w in the final scaffold. The method allows the production of scaffolds with high regeneration and healing properties of a grafted tissue via host cell invasion and colonization, and a good suturability. These goals are achieved through the formation within the scaffold of a non-uniform architecture creating softer and stiffer areas, which is maintained even upon re-swelling of the scaffold upon hydration of the final dried product.

Compositions are provided herein comprising a coacervate of a polycationic polymer, a polyanionic polymer, and platelet-rich plasma and/or serum, or a fraction or concentrate thereof. The composition is useful in wound healing. Compositions also are provided that comprise a hydrogel comprising TIMP-3; and a complex of a polycationic polymer, a polyanionic polymer, FGF-2 and SDF-1α embedded in the hydrogel, which is useful in treating a myocardial infarction.

The present disclosure provides a method for obtaining osteoblast cell-mixture which can be used for transplantation of osteoblast cells in a subject. The present disclosure further discloses a method for delivering osteoblast cells into a subject. The method for obtaining osteoblast cell-mixture as disclosed herein is devoid of any additives like calcium chloride and aprotinin. The method for delivering osteoblast cells as disclosed herein provides bone regeneration in the subject.

The invention relates to methods for producing a polymeric scaffold for use in tissue engineering applications or soft tissue surgery, as well as to the produced scaffolds and an associated kit. The method features a first fast drying step of applying a mechanical compression on a polymeric gel layer and a second slow drying step of the gel up to reach a polymer mass fraction of at least 60% w/w in the final scaffold. The method allows the production of scaffolds with high regeneration and healing properties of a grafted tissue via host cell invasion and colonization, and a good suturability. These goals are achieved through the formation within the scaffold of a non-uniform architecture creating softer and stiffer areas, which is maintained even upon re-swelling of the scaffold upon hydration of the final dried product.

The invention relates to a method for producing a bioartificial and primarily acellular fibrin-based construct, wherein a mixture of cell-free compositions containing fibrinogen and thrombin is applied to a surface and subsequently pressurised. An additional aspect of the invention is directed to such fibrin-based bioartificial acellular constructs obtained according to the invention, with improved biomechanical properties, as well as to the use of same in the field of implantology, cartilage replacement or tissue replacement.

Engineered human tissue seed constructs are provided that are suitable for implantation in subjects. Methods of making and using the engineered tissue seed constructs are provided.

Methods for producing a fibrin matrix comprising a fusion peptide are described herein. In some embodiments, the method includes providing three different components, including a first component containing fibrinogen or a fibrinogen precursor and optionally, transglutaminase or a transglutaminase precursor, a second component containing thrombin or a thrombin precursor, and a third component containing a fusion peptide. In these embodiments, neither the first component nor the second component includes the fusion peptide. In some embodiments, the first or second components are premixed with the third component. The first, second and third components are mixed to form a fibrin matrix comprising a covalently linked fusion peptide. The mixing is carried out in a time frame of not more than 5 days. A kit for producing the fibrin matrix comprising a covalently linked fusion peptide is also described herein.

A method and kit for stopping cerebrospinal fluid (CSF) leaks, comprising penetrating and passing through a dural tissue an applicator to access an interior dural space, injecting from the applicator a fibrinogen-containing solution into said dural space, applying a sealing member containing a fibrinogen polymerizing agent onto an exterior surface of the dural tissue, and forming a polymerized fibrinogen or polymerized fibrin clot by contacting the injected fibrinogen-containing solution and the fibrinogen polymerizing agent.