A method for extracting animal-derived pulmonary surfactants, including forming an extract of an animal lung, forming a precipitate by mixing the extract of the animal lung with a cationic flocculant solution containing poly(diallyldimethyl ammonium chloride) (pDADMAC), separating an organic phase containing pulmonary surfactants from the precipitate, recovering the pulmonary surfactants from the organic phase.

A reagent for differentiating somatic cells into alveolar epithelial cells includes an NK2 homeobox family gene expression vector, and a Fox family gene expression vector.

A reagent for differentiating somatic cells into alveolar epithelial cells includes an NK2 homeobox family gene expression vector, and a Fox family gene expression vector.

A method of conditioning a subject in need of transplantation of progenitor cells in suspension of a tissue of interest is disclosed. The method comprising: (a) administering to a subject a therapeutically effective amount of an agent capable of inducing damage to the tissue of interest, wherein the damage results in proliferation of resident stem cells in the tissue; and subsequently (b) subjecting the subject to an agent which ablates the resident stem cells in the tissue. A method of transplanting progenitor cells in suspension of a tissue of interest to a subject in need thereof is also disclosed.

A method of conditioning a subject in need of transplantation of progenitor cells in suspension of a tissue of interest is disclosed. The method comprising: (a) administering to a subject a therapeutically effective amount of an agent capable of inducing damage to the tissue of interest, wherein the damage results in proliferation of resident stem cells in the tissue; and subsequently (b) subjecting the subject to an agent which ablates the resident stem cells in the tissue. A method of transplanting progenitor cells in suspension of a tissue of interest to a subject in need thereof is also disclosed.

A method of conditioning a subject in need of transplantation of progenitor cells in suspension of a tissue of interest is disclosed. The method comprising: (a) administering to a subject a therapeutically effective amount of an agent capable of inducing damage to the tissue of interest, wherein the damage results in proliferation of resident stem cells in the tissue; and subsequently (b) subjecting the subject to an agent which ablates the resident stem cells in the tissue. A method of transplanting progenitor cells in suspension of a tissue of interest to a subject in need thereof is also disclosed.

Methods of treatment are provided herein, including administration of a population cells modified to enforce expression of an E-selectin and/or an L-selectin ligand, the modified cell population having a cell viability of at least 70% after a treatment to enforce such expression.

Methods of treatment are provided herein, including administration of a population cells modified to enforce expression of an E-selectin and/or an L-selectin ligand, the modified cell population having a cell viability of at least 70% after a treatment to enforce such expression.

Particulated and reconstituted tissues comprising small, densely packed tissue microparticles encapsulated in a tissue specific promoting gel packed at a percolation threshold that can be transplanted into damaged tissue thereby facilitating regeneration following trauma to the tissue. The engineered microparticle construct for tissue replacement and repair, as taught herein, provides numerous benefits including (1) encouraging a regenerative response in damaged tissue regions, (2) mimicking the structural support of native tissue, (3) establishing an environment that promotes attachment, migration, and differentiation of infiltrating stem cells, and (4) providing a source of growth factors and other anti-catabolic growth factors and cytokines. Tissue specific microparticles packed together at, or past, their percolation threshold will provide the necessary mechanical environment and to best recapitulate and integrate with native tissue. The packing of microparticles, derived from the ECM of native tissue, to a concentration past the percolation point will yield both the necessary biochemical and biomechanical properties necessary for reconstituting a specific tissue.

Particulated and reconstituted tissues comprising small, densely packed tissue microparticles encapsulated in a tissue specific promoting gel packed at a percolation threshold that can be transplanted into damaged tissue thereby facilitating regeneration following trauma to the tissue. The engineered microparticle construct for tissue replacement and repair, as taught herein, provides numerous benefits including (1) encouraging a regenerative response in damaged tissue regions, (2) mimicking the structural support of native tissue, (3) establishing an environment that promotes attachment, migration, and differentiation of infiltrating stem cells, and (4) providing a source of growth factors and other anti-catabolic growth factors and cytokines. Tissue specific microparticles packed together at, or past, their percolation threshold will provide the necessary mechanical environment and to best recapitulate and integrate with native tissue. The packing of microparticles, derived from the ECM of native tissue, to a concentration past the percolation point will yield both the necessary biochemical and biomechanical properties necessary for reconstituting a specific tissue.