Kim C. O'Connor

Evaluation of metallic and polymeric biomaterial surface energy and surface roughness characteristics for directed cell adhesion.

Directed cell adhesion remains an important goal of implant and tissue engineering technology. In this study, surface energy and surface roughness were investigated to ascertain which of these properties show more overall influence on biomaterial-cell adhesion and colonization. Jet impingement was used to quantify cellular adhesion strength. Cellular proliferation and extracellular matrix secretion were used to characterize colonization of 3T3MC fibroblasts on: HS25 (a cobalt based implant alloy, ASTM F75), 316L stainless steel, Ti-6Al4V (a titanium implant alloy), commercially pure tantalum (Ta), polytetrafluoroethylene (PTFE), silicone rubber (SR), and high-density polyethylene (HDPE). The metals exhibited a nearly five-fold greater adhesion strength than the polymeric materials tested. Generally, surface energy was proportional to cellular adhesion strength. Only polymeric materials demonstrated significant increased adhesion strength associated with increased surface roughness. Cellular adhesion on metals demonstrated a linear correlation with surface energy. Less than half as much cellular proliferation was detected on polymeric materials compared to the metals. However the polymers tested demonstrated greater than twice the amount of secreted extracellular matrix (ECM) proteins on a per cell basis than the metallic materials. Thus, surface energy may be a more important determinant of cell adhesion and proliferation, and may be more useful than surface roughness for directing cell adhesion and cell colonization onto engineered tissue scaffoldings.

In Vitro High‐Capacity Assay to Quantify the Clonal Heterogeneity in Trilineage Potential of Mesenchymal Stem Cells Reveals a Complex Hierarchy of Lineage Commitment

In regenerative medicine, bone marrow is a promising source of mesenchymal stem cells (MSCs) for a broad range of cellular therapies. This research addresses a basic prerequisite to realize the therapeutic potential of MSCs by developing a novel high‐capacity assay to quantify the clonal heterogeneity in potency that is inherent to MSC preparations. The assay utilizes a 96‐well format to (1) classify MSCs according to colony‐forming efficiency as a measure of proliferation capacity and trilineage potential to exhibit adipo‐, chondro‐, and osteogenesis as a measure of multipotency and (2) preserve a frozen template of MSC clones of known potency for future use. The heterogeneity in trilineage potential of normal bone marrow MSCs is more complex than previously reported: all eight possible categories of trilineage potential were detected. In this study, the average colony‐forming efficiency of MSC preparations was 55–62%, and tripotent MSCs accounted for nearly 50% of the colony‐forming cells. The multiple phenotypes detected in this study infer a more convoluted hierarchy of lineage commitment than described in the literature. Greater cell amplification, colony‐forming efficiency, and colony diameter for tri‐ versus unipotent clones suggest that MSC proliferation may be a function of potency. CD146 may be a marker of multipotency, with ∼2‐fold difference in mean fluorescence intensity between tri‐ and unipotent clones. The significance of these findings is discussed in the context of the efficacy of MSC therapies. The in vitro assay described herein will likely have numerous applications given the importance of heterogeneity to the therapeutic potential of MSCs. STEM CELLS 2010;28:788–798

Vesicle traffic through intercellular bridges in DU 145 human prostate cancer cells

We detected cell‐to‐cell communication via intercellular bridges in DU 145 human prostate cancer cells by fluorescence microscopy. Since DU 145 cells have deficient gap junctions, intercellular bridges may have a prominent role in the transfer of chemical signals between these cells. In culture, DU 145 cells are contiguous over several cell diameters through filopodial extensions, and directly communicate with adjacent cells across intercellular bridges. These structures range from 100 nm to 5 μm in diameter, and from a few microns to at least 50–100 μm in length. Time‐lapse imagery revealed that (1) filopodia rapidly move at a rate of microns per minute to contact neighboring cells and (2) intercellular bridges are conduits for transport of membrane vesicles (1–3 μm in diameter) between adjacent cells. Immunofluorescence detected alpha‐tubulin in intercellular bridges and filopodia, indicative of microtubule bundles, greater than a micron in diameter. The functional meaning, interrelationship of these membrane extensions are discussed, along with the significance of these findings for other culture systems such as stem cells. Potential applications of this work include the development of anticancer therapies that target intercellular communication and controlling formation of cancer spheroids for drug testing.

Three-dimensional cultures of prostatic cells: tissue models for the development of novel anti-cancer therapies.

This review addresses the application of three-dimensional cultures of prostatic cells to the development of novel anti-cancer therapies. A variety of therapeutic agents to combat prostate cancer are currently under development. These include cytotoxins, differentiation agents and, more recently, genetically modified tumor vaccines. Three-dimensional cultures of prostatic cells are increasingly used in preclinical research in the design of new therapies and in the development of delivery strategies for these treatments. These tissue-like structures more realistically model the structural architecture and differentiated function of the human prostate than a cellular monolayer. In doing so, three-dimensional cultures produce an in vivo-like response to therapeutic agents. Advances in tissue engineering have improved the variety, fidelity and quantity of these prostate models. To date, they have been applied to estimate the dose of new drug therapies, evaluate drug penetration into solid tumors, assess the effectiveness of drug combinations, and develop tumor vaccines.

Clonal analysis of the proliferation potential of human bone marrow mesenchymal stem cells as a function of potency

Human mesenchymal stem cells (MSCs) from bone marrow are a heterogeneous ensemble of progenitors and lineage‐committed cells, with a broad range of regenerative properties. Ex vivo expansion to produce sufficient quantities of MSCs is essential for most therapeutic applications. The present study resolves the relationship between proliferation potential of MSCs and their potency. Clonal analysis generated single‐cell derived colonies of MSCs that were classified according to their trilineage potential to exhibit adipo‐ (A), chondro‐ (C), and osteogenesis (O) as a measure of potency. Multipotent OAC clones were highly proliferative with colony‐forming efficiencies that ranged from 35% to 90%; whereas, O clones formed colonies with an efficiency of 5% or less (P < 0.01). Similar trends were evident during ex vivo expansion: for example, the median specific growth rate was 0.85 day−1 (20 h doubling time) for cultures inoculated with OAC clones and was 5‐fold less for inocula of O clones (P < 0.01). OA and OC clones had similar proliferation potentials. More than 75% of cells in subconfluent cultures inoculated with O clones stained positive for senescence‐associated β‐galactosidase activity vs. less than 10% for OAC clones (P < 0.001). Apoptotic cells were in the minority for all potency groups. Preliminary data generated during clonal analysis suggest that osteogenic potential of MSCs to produce mineralized matrix is a function of potency, as well. These results are discussed in the context of the preparation of efficacious MSC therapies by ex vivo expansion. Biotechnol. Bioeng. 2011;108: 2716–2726.

Dynamics of spheroid self-assembly in liquid-overlay culture of DU 145 human prostate cancer cells.

The in vitro self-assembly of multicellular spheroids generates highly organized structures in which the three-dimensional structure and differentiated function frequently mimic that of in vivo tissues. This has led to their use in such diverse applications as tissue regeneration and drug therapy. Using Smoluchowski-like rate equations, herein we present a model of the self-aggregation of DU 145 human prostate carcinoma cells in liquid-overlay culture to elucidate some of the physical parameters affecting homotypic aggregation in attachment-dependent cells. Experimental results indicate that self-aggregation in our system is divided into three distinct phases: a transient reorganization of initial cell clusters, an active aggregation characterized by constant rate coefficients, and a ripening phase of established spheroid growth. In contrast to the diffusion-controlled aggregation previously observed for attachment-independent cells, the model suggests that active aggregation in our system is reaction-controlled. The rate equations accurately predict the aggregation kinetics of spheroids containing up to 30 cells and are dominated by spheroid adhesive potential with lesser contributions from the radius of influence. The adhesion probability increases with spheroid size so that spheroid-spheroid adhesions are a minimum of 2.5 times more likely than those of cell-cell, possibly due to the upregulation of extracellular matrix proteins and cell-adhesion molecules. The radius of influence is at least 1.5 to 3 times greater than expected for spherical geometry as a result of ellipsoidal shape and possible chemotactic or Fröhlich interactions. Brownian-type behavior was noted for spheroids larger than 30 microm in diameter, but smaller aggregates were more motile by as much as a factor of 10 for single cells. The model may improve spheroid fidelity for existing applications of spheroids and form the basis of a simple assay for quantitatively evaluating cellular metastatic potential as well as therapies that seek to alter this potential.

Characterization of bimodal cell death of insect cells in a rotating-wall vessel and shaker flask

In previous publications, we reported the benefits of a high-aspect rotating-wall vessel (HARV) over conventional bioreactors for insect-cell cultivation in terms of reduced medium requirements and enhanced longevity. To more fully understand the effects that HARV cultivation has on longevity, the present study characterizes the mode and kinetics of Spodoptera frugiperda cell death in this quiescent environment relative to a shaker-flask control. Data from flow cytometry and fluorescence microscopy show a greater accumulation of apoptotic cells in the HARV culture, by a factor of at least 2 at the end of the cultivation period. We present a kinetic model of growth and bimodal cell death. The model is unique for including both apoptosis and necrosis, and further, transition steps within the two pathways. Kinetic constants reveal that total cell death is reduced in the HARV and the accumulation of apoptotic cells in this vessel results from reduced depletion by lysis and secondary necrosis. The ratio of early apoptotic to necrotic cell formation is found independent of cultivation conditions. In the model, apoptosis is only well represented by an integral term, which may indicate its dependence on accumulation of some factor over time; in contrast, necrosis is adequately represented with a first-order term. Cell-cycle analysis shows the percent of tetraploid cells gradually decreases during cultivation in both vessels. For example, between 90% and 70% viability, tetraploid cells in the HARV drop from 43 +/- 1% to 24 +/- 4%. The data suggests the tetraploid phase as the likely origin for apoptosis in our cultures. Possible mechanisms for these changes in bimodal cell death are discussed, including hydrodynamic forces, cell-cell interactions, waste accumulation, and mass transport. These studies may benefit insect-cell cultivation by increasing our understanding of cell death in culture and providing a means for further enhancing culture longevity. Copyright 1999 John Wiley & Sons, Inc.

Effects of simulated microgravity on DU 145 human prostate carcinoma cells

The high aspect rotating‐wall vessel (HARV) was recently designed by NASA to cultivate animal cells in an environment that simulates microgravity. This work examines the effects of HARV cultivation on DU 145 human prostate carcinoma cells. In the HARV, these prostate cells grew in suspension on Cytodex‐3 microcarrier beads to form bead aggregates with extensive three‐dimensional growth between beads and on the aggregate surface. HARV and spinner‐flask control cultures of DU 145 cells had similar doubling times, but the former was characterized by a higher percentage of G1‐phase cells, larger bead aggregates, enhanced development of filopodia and microvilli‐like structures on the aggregate surface, and stronger staining for select cytoskeletal proteins (cytokeratins 8 and 18, actin, and vimentin). When compared with static controls grown in a T‐flask and Transwell insert, HARV cultures grew more slowly and differences in the cell cycle and immunostaining became more pronounced. These results suggest that HARV cultivation produced a culture that was less aggressive from the perspective of proliferation, more differentiated and less pliant than any of the three control cultures examined in this work. Possible factors effecting this change are discussed including turbulence and three‐dimensional growth.

Tri‐dimensional prostate cell cultures in simulated microgravity and induced changes in lipid second messengers and signal transduction

The high aspect rotating‐wall vessel (HARV) was designed to cultivate cells in an environment that simulate microgravity. We studied previously the effects of HARV cultivation on DU‐145 human prostate carcinoma cells. We determined that HARV cultivation produced a less aggressive, slower growing, less proliferative, more differentiated and less pliant cell than other cell cultivation methods. The result was a 3‐dimensional (3D) growth model of prostate cancer which mimics in vivo tissue growth. This work examines the signal transduction‐second messenger pathways existing temporarily in these HARV cells and correlates these features with the special properties in growth and 3D spheroid formation. We found an initial very active ceramide, a diacylglycerol increase together with increases in PI‐PLC and PLA2 a central defect in PLD (no phosphatic acid or phosphatidylethanol at any time during 15 days of HARV cultivation). There is a cross‐talk between ceramide and PI3K pathways with activation of PI3K, after 6 days of HARV growth concomitant with down‐regulation of ceramide. At this time, there is also an increase of cAMP (seen by increases in arachidonic acid). Taken together these results can explain the 3D organoidlike growth. We therefore developed a model for growth in HARV prostate cancer cells which involve temporal “switches” between second messengers, activation and cross‐talk between multiplicity of signaling pathways and a central defect in PLD pathways. Essential to the late slow growth, and 3D organotypic formation are the apoptotic, anti‐survival, anti‐proliferation and differentiation pathways in the first days of HARV, with growth of “new” different types of prostate cancer cells which set‐up for later “switch” in ceramide‐PI3K to survival and proliferation.

Differentiation Kinetics of in Vitro 3T3-L1 Preadipocyte Cultures

Engineering autologous adipose constructs from cell culture is a promising strategy to overcome limitations of conventional soft-tissue implants. A methodology is presented to experimentally determine and mathematically model the differentiation kinetics of in vitro 3T3-L1 preadipocyte cultures that can aid in construct design. Relative rates of morphological and interfacial events during adipogenesis were compared. Model results suggest that maturation of an intermediate multilocular phenotype was the rate-limiting step in morphological differentiation and had an intrinsic rate of 0.012 day(-1). Dislodgment of multilocular fat cells was the primary mechanism of cell loss during adipogenesis. The maximum rate of lipid droplet nucleation was predicted to precede that of coalescence by 10 days and to be three times faster. Coalescence probability was estimated to decrease from 33 to 11% for 4- and 8-microm-diameter droplets, respectively. Fluid drainage and the cytoskeleton between droplets could have impeded coalescence. The kinetic analysis suggests that droplet ripening was the dominant mechanism of lipid production. Applications of this research include engineering of an adipose construct and predicting surgical outcome of patients requiring soft-tissue augmentation.