Platforms to test the temporospatial capabilities of carrier systems in delivering growth factors to benefit vascular bioengineering.

In this study we produced a set of in vitro culture platforms to model vascular cell responses to growth factors and factor delivery vehicles. Two of the systems (whole vessel and whole lung vascular development) were supported by microfluidic systems facilitating media circulation and waste removal. We assessed vascular endothelial growth factor (VEGF) delivery by Pluronic F-127 hydrogel, 30 nm pore-sized microparticles (MPs), 60 nm pore-sized MP or a 50/50 mixture of 30 and 60 nm pore-sized MP.

Production and transplantation of bioengineered lung into a large-animal model.

The inability to produce perfusable microvasculature networks capable of supporting tissue survival and of withstanding physiological pressures without leakage is a fundamental problem facing the field of tissue engineering. Microvasculature is critically important for production of bioengineered lung (BEL), which requires systemic circulation to support tissue survival and coordination of circulatory and respiratory systems to ensure proper gas exchange. To advance our understanding of vascularization after bioengineered organ transplantation, we produced and transplanted BEL without creation of a pulmonary artery anastomosis in a porcine model.

Giving new life to old lungs: methods to produce and assess whole human paediatric bioengineered lungs.

We report, for the first time, the development of an organ culture system and protocols to support recellularization of whole acellular (AC) human paediatric lung scaffolds. The protocol for paediatric lung recellularization was developed using human transformed or immortalized cell lines and single human AC lung scaffolds. Using these surrogate cell populations, we identified cell number requirements, cell type and order of cell installations, flow rates and bioreactor management methods necessary for bioengineering whole lungs.

Modeling the lung: Design and development of tissue engineered macro- and micro-physiologic lung models for research use.

Respiratory tract specific cell populations, or tissue engineered in vitro grown human lung, have the potential to be used as research tools to mimic physiology, toxicology, pathology, as well as infectious diseases responses of cells or tissues. Studies related to respiratory tract pathogenesis or drug toxicity testing in the past made use of basic systems where single cell populations were exposed to test agents followed by evaluations of simple cellular responses. Although these simple single-cell-type systems provided good basic information related to cellular responses, much more can be learned from cells grown in fabricated microenvironments which mimic in vivo conditions in specialized microfabricated chambers or by human tissue engineered three-dimensional (3D) models which allow for more natural interactions between cells.

Isotopic study of L-Arginine kinetics in the lung during pseudomonas sepsis in an ovine model.

Unlabelled: The objective of the study is to investigate how L-Arginine pulmonary metabolism is altered in response Pseudomonas aeruginosa (P. aeruginosa) induced septic conditions using an ovine model.

Methods: Seven female sheep were infused with a primed-constant infusion of L-[(15)N2-guanidino, 5, 5, (2)H2] L-Arginine for 28 hs.

Novel in vitro respiratory models to study lung development, physiology, pathology and toxicology.

Detailed studies of lung pathology in patients during the course of development of acute lung injury or respiratory distress are limited, and in the past information related to lung-specific responses has been derived from the study of lungs from patients who died at autopsy or from animal models. Development of good in vitro human tissue models would help to bridge the gap in our current knowledge of lung responses and provide a better understanding of lung development, physiology and pathology. In vitro models of simple one-cell or two-cell culture systems as well as complex multicellular lung analogs that reproduce defined components of specific human lung responses have already been realized.

Isotopic study of L-Arginine kinetics in the lung during pseudomonas sepsis in an ovine model.

Unlabelled: The objective of the study is to investigate how L-Arginine pulmonary metabolism is altered in response Pseudomonas aeruginosa (P. aeruginosa) induced septic conditions using an ovine model.

Methods: Seven female sheep were infused with a primed-constant infusion of L-[(15)N2-guanidino, 5, 5, (2)H2] L-Arginine for 28 hs.

Effects of the decellularization method on the local stiffness of acellular lungs.

Lung bioengineering, a novel approach to obtain organs potentially available for transplantation, is based on decellularizing donor lungs and seeding natural scaffolds with stem cells. Various physicochemical protocols have been used to decellularize lungs, and their performance has been evaluated in terms of efficient decellularization and matrix preservation. No data are available, however, on the effect of different decellularization procedures on the local stiffness of the acellular lung.

Production and assessment of decellularized pig and human lung scaffolds.

The authors have previously shown that acellular (AC) trachea-lung scaffolds can (1) be produced from natural rat lungs, (2) retain critical components of the extracellular matrix (ECM) such as collagen-1 and elastin, and (3) be used to produce lung tissue after recellularization with murine embryonic stem cells. The aim of this study was to produce large (porcine or human) AC lung scaffolds to determine the feasibility of producing scaffolds with potential clinical applicability. We report here the first attempt to produce AC pig or human trachea-lung scaffold.

Local micromechanical properties of decellularized lung scaffolds measured with atomic force microscopy.

Bioartificial lungs re-engineered from decellularized organ scaffolds are a promising alternative to lung transplantation. Critical features for improving scaffold repopulation depend on the mechanical properties of the cell microenvironment. However, the mechanics of the lung extracellular matrix (ECM) is poorly defined.

Neurogenic and neuro-protective potential of a novel subpopulation of peripheral blood-derived CD133+ ABCG2+CXCR4+ mesenchymal stem cells: development of autologous cell-based therapeutics for traumatic brain injury.

Introduction: Nervous system injuries comprise a diverse group of disorders that include traumatic brain injury (TBI). The potential of mesenchymal stem cells (MSCs) to differentiate into neural cell types has aroused hope for the possible development of autologous therapies for central nervous system injury.

Methods: In this study we isolated and characterized a human peripheral blood derived (HPBD) MSC population which we examined for neural lineage potential and ability to migrate in vitro and in vivo.

Production and utilization of acellular lung scaffolds in tissue engineering.

Pulmonary disease is a worldwide public health problem that reduces the quality of life and increases the need for hospital admissions as well as the risk for premature death for those affected. For many patients, lung transplantation is the only chance for survival. Unfortunately, there is a significant shortage of lungs for transplantation and since the lung is the most likely organ to be damaged during procurement many lungs deemed unacceptable for transplantation are simply discarded.

Influence of acellular natural lung matrix on murine embryonic stem cell differentiation and tissue formation.

We report here the first attempt to produce and use whole acellular (AC) lung as a matrix to support development of engineered lung tissue from murine embryonic stem cells (mESCs). We compared the influence of AC lung, Gelfoam, Matrigel, and a collagen I hydrogel matrix on the mESC attachment, differentiation, and subsequent formation of complex tissue. We found that AC lung allowed for better retention of cells with more differentiation of mESCs into epithelial and endothelial lineages.

In vitro human bone marrow analog: clinical potential.

Bone marrow is the primary site of hematopoiesis in adult humans. Bone marrow can be cultured in vitro but few simple culture systems fully support hematopoiesis beyond a few months. Human bone marrow analogs are long-term in vitro cultures of marrow stromal and hematopoietic stem cells that can be used to produce cells and products normally harvested from human donors.

Design and development of tissue engineered lung: Progress and challenges.

Before we can realize our long term goal of engineering lung tissue worthy of clinical applications, advances in the identification and utilization of cell sources, development of standardized procedures for differentiation of cells, production of matrix tailored to meet the needs of the lung and design of methods or techniques of applying the engineered tissues into the injured lung environment will need to occur. Design of better biomaterials with the capacity to guide stem cell behavior and facilitate lung lineage choice as well as seamlessly integrate with living lung tissue will be achieved through advances in the development of decellularized matrices and new understandings related to the influence of extracellular matrix on cell behavior and function. We have strong hopes that recent developments in the engineering of conducting airway from decellularized trachea will lead to similar breakthroughs in the engineering of distal lung components in the future.

In vitro analog of human bone marrow from 3D scaffolds with biomimetic inverted colloidal crystal geometry.

In vitro replicas of bone marrow can potentially provide a continuous source of blood cells for transplantation and serve as a laboratory model to examine human immune system dysfunctions and drug toxicology. Here we report the development of an in vitro artificial bone marrow based on a 3D scaffold with inverted colloidal crystal (ICC) geometry mimicking the structural topology of actual bone marrow matrix. To facilitate adhesion of cells, scaffolds were coated with a layer of transparent nanocomposite.

Engineering of a complex organ: progress toward development of a tissue-engineered lung.

Although there has been slow progress in the engineering of the lung, recent advances in the use of stem or progenitor cells leading to the reliable production of component parts of the lung show promise for the future development of engineered lung tissue. Progress toward the goal of developing an engineered lung will only be accomplished through the parallel development of effective and functional tissue-engineered components that include both upper and lower respiratory tract as well as scaffold material suitable for use in the lung. The knowledge acquired from developing each individual component of lung will, over time, be integrated to allow for the development of larger complex organ structures.

Tissue-engineered lung: an in vivo and in vitro comparison of polyglycolic acid and pluronic F-127 hydrogel/somatic lung progenitor cell constructs to support tissue growth.

In this study, we describe the isolation and characterization of a population of adult-derived or somatic lung progenitor cells (SLPC) from adult mammalian lung tissue and the promotion of alveolar tissue growth by these cells (both in vitro and in vivo) after seeding onto synthetic polymer scaffolds. After extended in vitro culture, differentiating cells expressed Clara cell 10kDa protein, surfactant protein-C, and cytokeratin but did not form organized structures. When cells were combined with synthetic scaffolds, polyglycolic acid (PGA) or Pluronic F-127 (PF-127), and maintained in vitro or implanted in vivo, they expressed lung-specific markers for Clara cells, pneumocytes, and respiratory epithelium and organized into identifiable pulmonary structures (including those similar to alveoli and terminal bronchi), with evidence of smooth muscle development.

Inverted colloidal crystals as three-dimensional cell scaffolds.

A new type of three-dimensional scaffold with inverted colloidal crystal geometry for the investigation of topological effects in cell cultures is introduced in this publication. The scaffolds are made by infiltration of the hexagonal crystal lattice of polystyrene spheres with sol-gel formulation and subsequent annealing. It possesses a relatively high degree of order among existing cell scaffolds and affords tight control over the scaffold porosity and tissue organization.

Comparison of tracheal and nasal chondrocytes for tissue engineering of the trachea.

Background: This study was undertaken to evaluate the feasibility of creating engineered tracheal equivalents grown in the shape of cylindrical cartilaginous structures using sheep nasal cartilage-derived chondrocytes. We also tested sheep tracheal and nasal septum for cell yield and quality of the engineered cartilage each produced.

Methods: Nasal septum and tracheal tissue were harvested from sheep.

A composite tissue-engineered trachea using sheep nasal chondrocyte and epithelial cells.

This study evaluates the feasibility of producing a composite engineered tracheal equivalent composed of cylindrical cartilaginous structures with lumens lined with nasal epithelial cells. Chondrocytes and epithelial cells isolated from sheep nasal septum were cultured in Ham's F12 media. After 2 wk, chondrocyte suspensions were seeded onto a matrix of polyglycolic acid.

Autologous tissue-engineered trachea with sheep nasal chondrocytes.

Objective: This study was designed to evaluate the ability of autologous tissue-engineered trachea shaped in a helix to form the structural component of a functional tracheal replacement.

Methods: Nasal septum were harvested from six 2-month-old sheep. Chondrocytes and fibroblasts were isolated from tissue and cultured in media for 2 weeks.

Diffusion of nitrous oxide into the pleural cavity.

We postulated that nitrous oxide transfer into the pleural cavity can occur by diffusion from the alveoli, independent of vascular transport. Under general anaesthesia, six sheep were studied in two phases, a control and an experimental phase. The sheep were anaesthetized, intubated, and received positive pressure mechanical ventilation.

Identification and initial characterization of spore-like cells in adult mammals.

We describe the identification and initial characterization of a novel cell type that seems to be present in all tissues. To date we have isolated what we term "spore-like cells" based on the characteristics described below. They are extremely small, in the range of less than 5 microm, and appear to lie dormant and to be dispersed throughout the parenchyma of virtually every tissue in the body.

Identifying a site for maximum delivery of oxygen to transplanted cells.

For in vivo cell implantation techniques to be successful, the energy and metabolic substrate requirement of the cells being grown must be met. Certain cells with high-energy requirements (e.g.