Three Dimensional OCT in the Engineering of Tissue Constructs: A Potentially Powerful Tool for Assessing Optimal Scaffold Structure.

Optical Coherence Tomography (OCT) provides detailed, real-time information on the structure and composition of constructs used in tissue engineering. The focus of this work is the OCT three-dimensional assessment of scaffolding architecture and distribution of cells on it. PLGA scaffolds were imaged in two and three-dimensions, both seeded and unseeded with cells. Then two types of scaffolds were reconstructed in three dimensions. Both scaffolding types were examined at three different seeding densities. The importance of three-dimensional assessments was evident, particularly with respect to porosity and identification of asymmetrical cell distribution.

Three-dimensional visualization of microvessel architecture of whole-mount tissue by confocal microscopy.

The three-dimensional architecture of the nascent microvascular network is a critical determinant of vascular perfusion in the setting of regenerative growth, vasculopathies and cancer. Current methods for microvessel visualization are limited by insufficient penetration and instability of endothelial immunolabels, inadequate vascular perfusion by the high-viscosity polymers used for vascular casting, and destruction of tissue stroma during the processing required for scanning electron microscopy. The aim of this study was to develop whole-mount tissue processing methods for 3D in situ visualization of the microvasculature that were also compatible with supplementary labeling for other structures of interest in the tissue microenvironment. Here, we present techniques that allow imaging of the microvasculature by confocal microscopy, to depths of up to 1500 mum below the specimen surface. Our approach includes labeling luminal surfaces of endothelial cells by i.v. injection of fluorescently conjugated lectin and filling the microvasculature with carbon or fluorescent nanoparticles/Mercox, followed by optical clearing of thick tissue sections to reduce light scatter and permit 3D visualization of microvessel morphology deep into the sample. Notably, tissue stroma is preserved, allowing simultaneous labeling of other structures by immunohistochemistry or nuclear dyes. Results are presented for various murine tissues including fat, muscle, heart and brain under conditions of normal health, as well as in the setting of a glioma model growing in the subcutaneous space or orthotopically in the brain parenchyma.

Chemotaxis of human microvessel endothelial cells in response to acidic fibroblast growth factor.

Migration of microvessel endothelial cells (MEC) in response to angiogenic stimuli is a key aspect of angiogenesis, whether in physiologic or pathologic situations. In this work, we provide a rigorous quantitative assessment of the chemokinetic and chemotactic responses of human MEC to acidic fibroblast growth factor (aFGF). A uniform concentration of 1 micrograms/ml of heparin was included in most experiments to exploit heparin's potentiating effect on aFGF activity. The migration is measured in an under-agarose assay with a linear geometry, and evaluated in terms of the random motility and chemotaxis coefficients, mu and chi, which are defined in a mathematical model. The change in value of mu with changes in aFGF concentration provides a quantitative description of the stimulated random motility response, a process known as chemokinesis. This allows the true directional response in gradients to be quantified by the chemotaxis coefficient, chi, and its variation with attractant concentration. The effect of aFGF on MEC random motility is relatively small, with the random motility coefficient ranging from 4.6 +/- 0.4 x 10(-9) to 9.9 +/- 0.3 x 10(-9) cm2/second (mean +/- SE) over four orders of magnitude of aFGF concentration (10(-11) to 10(-8) M). On the other hand, the magnitude of the chemotaxis coefficient at optimal concentrations is quite large (2600 +/- 750 cm2/second-M around 10(-10) M aFGF), demonstrating a significant degree of MEC directional sensitivity to aFGF gradients. The chemotaxis coefficient shows a biphasic dependence on aFGF concentration, suggestive of a receptor-mediated response in which apparent differences in receptor occupancy govern directional bias. These results provide support for the hypothesis that MEC chemotaxis accounts for the directed microvessel growth observed in angiogenesis.

Endothelialization of vascular prosthetic surfaces after seeding or sodding with human microvascular endothelial cells.

The rapid establishment of an endothelial cell (EC) monolayer on the luminal surface of small-diameter vascular grafts may be necessary to prevent early thrombosis and failure. We have studied procedures used to promote EC coverage of vascular grafts and have compared preclotting prosthetic surfaces with ECs in platelet-rich plasma (seeding) with plating ECs onto a preestablished clot (sodding). We evaluated the rate of monolayer formation, the subsequent resistance to shear stress, and the effects of EC growth factors (ECGF and heparin) on these functions. Woven Dacron was seeded or sodded at a density of 2 x 10(5) cells/cm2 with human adult microvessel ECs derived from adipose tissue. In the presence of ECGF-heparin, the immediate establishment of an EC layer after sodding was observed, whereas seeded grafts required almost 48 hours for cells to reach the surface. In the absence of ECGF-heparin, sodded grafts still exhibited a complete monolayer of EC, whereas ECs were not observed at the surface of seeded grafts after 48 hours. After exposure to shear stress (up to 20 dynes/cm2) for 2 hours, most freshly sodded EC remained attached; however, the loss of loosely adherent cells did occur. EC seeded grafts remained covered with fibrin matrix after exposure to shear stress. We conclude that the use of a microvessel sodding technique as an alternative to previously reported seeding techniques is necessary for the immediate formation of an EC monolayer before implantation.

Quantitative analysis of random motility of human microvessel endothelial cells using a linear under-agarose assay.

Angiogenesis is a multistep process intimately involved in embryonic development and subsequent cardiovascular homeostasis and pathology. A major event in the process of angiogenesis is endothelial cell migration. Common in vitro assays (filter, under-agarose, phagokinetic track) used for the evaluation of migration are interpreted by measurements such as leading front distance, total cells migrated, and total area of migration. However, these quantities depend very heavily upon the physical aspects of the assay such as geometry, chemoattractant concentration and diffusivity, and observation time. Thus, while these common cell motility measurements are convenient, they do not represent solely the intrinsic cell response to an attractant. Alternatively, cell motility responses can be described by parameters which do not depend on the physical aspects of the assay system. Such parameters, termed phenomenologic parameters, have been defined for cell migration in a mathematical model derived by others. This model defines two parameters, the random motility coefficient, mu, and the chemotaxis coefficient, chi, which describe the migration responses to uniform concentrations and to gradients of stimulant, respectively. We have used this approach to evaluate the random motility response of human microvessel endothelial cells isolated from omental fat. Human microvessel endothelial cell random motility was measured in uniform concentrations of heparin (10(-3) to 10(3) micrograms/ml) using an under-agarose assay with linear geometry. The value of mu was found to remain constant at 8.2 x 10(-9) cm2/second for all concentrations tested and without heparin. These data indicate that heparin at these concentrations does not significantly stimulate random migration of human microvessel endothelial cell. These results suggest that the potentiating effect of heparin on angiogenesis may not be mediated through a direct affect on endothelial cell migration. Because the random motility coefficient and chemotaxis coefficient are representative of intrinsic cell motility behavior, their use should provide more specific information on endothelial cell migration than other commonly used measurements.

Phenotypic diversity in cultured cerebral microvascular endothelial cells.

Diversity exists in both the structure and function of the endothelial cells (EC) that comprise the microvasculature of different organs. Studies of EC have been aided by our ability to first isolate and subsequently establish cultures from microvascularized tissue. After the isolation of microvessel endothelial cells (MEC) derived from rat cerebrum, we observed morphologic differences in colonies of cells that grew in primary cultures. The morphologies ranged from a cobblestone phenotype considered typical of EC in culture to elongated and stellate cell appearances. Serially passaged cell lines were established based on two parameters: initially by growth and, seconds, on differences in primary colony morphology using selective weeding techniques. Each culture was examined for the presence of EC-characteristic markers which include Factor-VIII-related antigen, angiotensin-I-converting enzyme activity, collagen type IV synthesis, and PGI2 production. Variable expression of each of these characteristics among the established EC lines was observed. Growth curves established for each of the EC cultures demonstrated differences in both population doubling rates and cell densities at confluence. The endocytic capacity of each EC line was also evaluated. Our ability to isolate and establish a number of morphologically distinct EC cultures indicates that diversity exists within the EC that comprise the cerebral microvasculature. Diversity in the established cell lines suggests either the EC that line the brain microvasculature exist as a mosaic or that morphologically distinct cultures may originate from different microanatomical origins (arteriolar, true capillary, or venular) or may have resulted from cells at different points in their in vitro life spans at the time of isolation.

Kinetics of endothelial cell-surface attachment forces.

Physical and biochemical forces exist that are necessary for the persistent attachment and function of ECs on native and prosthetic blood vessels. The optimization of conditions that permit regeneration of these attachment forces may allow rapid establishment of a durable, biocompatible EC monolayer. We examined the effects of three major factors, protein substrate, EC incubation time, and shear stress, on the attachment kinetics of human adult ECs to two different polymers. ECs were incubated up to 30 minutes on polymers (PS or PET) coated with extracellular matrix proteins: collagen I/III, fibronectin, collagen IV/V, laminin, gelatin, or saline control. After incubation, continued attachment in the presence of shear stress (created in a rotating disc device) between zero and 90 dynes/cm2 for 30 minutes was evaluated. Maximal adherence was observed on all substrates by 30 minutes. Therefore, after a 30-minute incubation, the percentage of cells attached (postshear ECs/preshear ECs/preshear ECs X 100) was measured as a function of shear stress. ECs attached to a matrix of fibronectin or collagen I/III demonstrated shear-resistant adherence after as little as 5 minutes of static incubation before initial shear exposure. By 30 minutes, more than 90% of the ECs on both matrices demonstrated the ability to remain attached in the presence of 90 dynes/cm2 of shear stress. We conclude that forces that attach ECs to surfaces are affected by temporal factors (incubation time) and substrate composition and may be quantified with a defined shear stress detachment assay. Understanding and manipulating these temporal physiochemical parameters should allow one to re-create an optimal EC monolayer on a blood-contacting surface.