Larry V. McIntire

Host response to tissue engineered devices

The two main components of a tissue engineered device are the transplanted cells and the biomaterial, creating a device for the restoration or modification of tissue or organ function. The implantation of polymer/cell constructs combines concepts of biomaterials and cell transplantation. The interconnections between the host responses to the biomaterial and transplanted cells determines the biocompatibility of the device. This review describes the inflammatory response to the biomaterial component and immune response towards transplanted cells. Emphasis is on how the presence of the transplanted cell construct affects the host response. The inflammatory response towards a biomaterial can impact the immune response towards transplanted cells and vice versa. Immune rejection is the most important host response towards the cellular component of tissue engineered devices containing allogeneic, xenogeneic or immunogenic ex vivo manipulated autologous cells. The immune mechanisms towards allografts and xenografts are outlined to provide a basis for the mechanistic hypotheses of the immune response towards encapsulated cells, with antigen shedding and the indirect pathway of antigen presentation predominating. A review of experimental evidence illustrates examples of the inflammatory response towards biodegradable polymer scaffold materials, examples of devices appropriately integrated as assessed morphologically with the host for various applications including bone, nerve, and skin regeneration, and of the immune response towards encapsulated allogeneic and xenogeneic cells.

Chemotactic factors regulate lectin adhesion molecule 1 (LECAM-1)-dependent neutrophil adhesion to cytokine-stimulated endothelial cells in vitro.

Monoclonal antibodies recognizing CD18, CD11a, CD11b, and neutrophil lectin adhesion molecule 1 (LECAM-1), i.e., the human homologue of the murine MEL-14 antigen, were used to assess the relative contribution of these glycoproteins to neutrophil-endothelial adhesion. Under static conditions, the adhesion of neutrophils to IL-1-stimulated human umbilical vein endothelial cell (HUVEC) monolayers was inhibited by antibodies to CD18, CD11a, and the neutrophil LECAM-1, and the effect of combining anti-LECAM-1 and anti-CD11a was almost additive. Under flow at a wall shear stress 1.85 dyn/cm2, a condition where CD18-dependent adhesion is minimal, anti-LECAM-1 inhibited adhesion by greater than 50%. Chemotactic stimulation of neutrophils induced a rapid loss of LECAM-1 from the neutrophil surface, and the level of neutrophil surface LECAM-1 was closely correlated with adhesion under flow. Neutrophils contacting the activated endothelial cells for 30 min lost much of their surface LECAM-1, a phenomenon induced by a soluble factor or factors released into the medium by the stimulated monolayers, and a high percentage migrated through the HUVEC monolayer. This migration was almost completely inhibited by anti-CD18, but was unaffected by antibodies to neutrophil LECAM-1. These results support the concept that LECAM-1 is a neutrophil adhesion molecule that participates in the adherence of unstimulated neutrophils to cytokine-stimulated endothelial cells under conditions of flow, and is then lost from the neutrophil surface coincident with the engagement of CD18-dependent mechanisms leading to transendothelial migration.

Growth Factor Delivery for Tissue Engineering

A tissue-engineered implant is a biologic-biomaterial combination in which some component of tissuehas been combined with a biomaterial to create a device for the restoration or modification of tissue ororgan function. Specific growth factors, released from a delivery device or from co-transplanted cells,would aid in the induction of host paraenchymal cell infiltration and improve engraftment of co-deliveredcells for more efficient tissue regeneration or ameliorate disease states. The characteristic properties ofgrowth factors are described to provide a biological basis for their use in tissue engineered devices. Theprinciples of polymeric device development for therapeutic growth factor delivery in the context of tissueengineering are outlined. A review of experimental evidence illustrates examples of growth factor deliveryfrom devices such as micropaticles, scaffolds, and encapsulated cells, for their use in the applicationareas of musculoskeletal tissue, neural tissue, and hepatic tissue.

DNA microarray reveals changes in gene expression of shear stressed human umbilical vein endothelial cells

Using DNA microarray screening (GeneFilter 211, Research Genetics, Huntsville, AL) of mRNA from primary human umbilical vein endothelial cells (HUVEC), we identified 52 genes with significantly altered expression under shear stress [25 dynes/cm2 for 6 or 24 h (1 dyne = 10 μN), compared with matched stationary controls]; including several genes not heretofore recognized to be shear stress responsive. We examined mRNA expression of nine genes by Northern blot analysis, which confirmed the results obtained on DNA microarrays. Thirty-two genes were up-regulated (by more than 2-fold), the most enhanced being cytochromes P450 1A1 and 1B1, zinc finger protein EZF/GKLF, glucocorticoid-induced leucine zipper protein, argininosuccinate synthase, and human prostaglandin transporter. Most dramatically decreased (by more than 2-fold) were connective tissue growth factor, endothelin-1, monocyte chemotactic protein-1, and spermidine/spermine N1-acetyltransferase. The changes observed suggest several potential mechanisms for increased NO production under shear stress in endothelial cells.

Effects of fluid dynamic forces on vascular cell adhesion.

Cell adhesion plays a key role in a number of diverse biological processes, including inflammation and thrombosis. In the cardiovascular system, cells are exposed constantly to hemodynamic forces due to the flow of blood. Cell attachment to vessel wall depends on the balance between the dispersive hydrodynamic forces and the adhesive forces generated by the interaction of membrane-bound receptors and their ligands. Understanding the complex interplay among blood flow, cell adhesion, and vascular biology at the molecular level is crucial for developing specific approaches for altering vessel pathology. The extravasation of leukocytes from the vasculature to the tissue space is the pivotal event of the immune response and represents a relevant example of this dynamic adhesion process.

E-selectin supports neutrophil rolling in vitro under conditions of flow.

E-selectin was evaluated for its ability to support neutrophil adhesion under conditions of flow. At a wall shear stress of 1.85 dyn/cm2, neutrophils were found to attach to E-selectin expressed on the apical surface of L cell monolayers. The initial intercellular contact was most often evidenced by neutrophils rolling on the monolayer at a mean rate of congruent to 10 microns/s. Anti-E-selectin monoclonal antibody, CL2/6, inhibited this interaction by > 90%. Rolling neutrophils often transiently stopped, but in contrast to the behavior on stimulated endothelial cells, they remained spherical in shape and did not migrate on or beneath the monolayer. A possible contribution of neutrophil L-selectin to this interaction was indicated by the findings that anti-L-selectin monoclonal antibody, DREG-56, inhibited E-selectin-dependent adhesion under flow by > 65%, and there was a highly significant correlation between surface levels of L-selectin and E-selectin-dependent adhesion under flow. E-selectin also appeared to support neutrophil adhesion to IL-1 beta-stimulated endothelial cells under conditions of flow, but it accounted for only congruent to 30% of the level of adherence, in contrast to L-selectin which accounted for > 65%. Thus, both L-selectin and E-selectin can support neutrophil adhesion at wall shear stresses that preclude intercellular adhesion molecule-1-dependent adhesion, and they participate in neutrophil adherence to stimulated endothelial cells under conditions of flow.

P-selectin mediates neutrophil rolling on histamine-stimulated endothelial cells

In postcapillary venules, marginating neutrophils (PMNs) are often seen rolling along the vessel wall prior to stopping and emigrating. There is substantial evidence in vitro and in vivo that the adhesion receptors E- and L-selectin participate in this phenomenon on cytokine-stimulated endothelium, and recent evidence has shown that a closely related adhesion receptor, P-selectin, is capable of mediating neutrophil rolling on an artificial membrane. Here we demonstrate and characterize PMN rolling on monolayers of human umbilical vein endothelial cells (HUVECs) stimulated with histamine to induce surface expression of P-selectin. Peak association of PMNs with the HUVECs occurs 10 min after histamine stimulation, and at a postcapillary venular wall shear stress of 2.0 dyn/cm2 the rolling velocity is 14 microns/s. Approximately 95% of the PMNs roll on the endothelial cells, 5% adhere firmly, and none migrate beneath the endothelial monolayer. Monoclonal antibody (MAb) G1, which binds P-selectin and blocks its adhesive function, completely prevents association of the PMNs with histamine-stimulated HUVEC, whereas the nonblocking anti-P-selectin MAb S12 does not. Treatment of PMNs with the anti-L-selectin MAb DREG56 reduces PMN adherence by approximately 50%. Anti-CD54 MAb R6.5 and anti-CD18 MAb R15.7 have little effect on the number of PMNs rolling on the HUVECs but completely prevent PMNs from stopping and significantly increase rolling velocity. Nonblocking control MAbs for R6.5 (CL203) and R15.7 (CL18/1D1) lack these effects. Rolling adhesion of PMNs on histamine-stimulated HUVECs therefore appears to be completely dependent on endothelial cell P-selectin, with a minor adhesion-stabilizing contribution from intercellular adhesion molecule 1 and beta 2 integrins. The partial inhibition of rolling with DREG56 suggests that L-selectin may also play a role in neutrophil interactions with histamine-stimulated endothelium. We further characterize these interactions by determining the effects of the various MAbs and wall shear stresses on adhesion patterns, rolling velocities, and distributions of rolling velocities.

Mechanical effects on endothelial cell morphology: In vitro assessment

SummaryEndothelial cells are subjected to fluid mechanical forces which accompany blood flow. These cells become elongated and orient their long axes parallel to the direction of shear stress when the cultured cells are subjected to flow in an in vitro circulatory system. When the substrate is compliant and cyclically deformed, to simulate effects of pressure in the vasculature, the cells elongate an orient perpendicular to the axis of deformation. Cell shape changes are reflected in the alignment of microtubule networks. The systems described provide tools for assessing the individual roles of shear stress, pressure, and mechanical strain on vascular cell structure and function.

Shear stress increases inositol trisphosphate levels in human endothelial cells

To elucidate some of the early mechanisms underlying the response of primary human endothelial cells to the initiation of flow, we investigated the changes in inositol lipid metabolism in cells exposed to arterial and venous levels of shear stress. We used a radioimmunoassay specific for inositol-1,4,5-trisphosphate (Ins1,4,5P3) to demonstrate that initiation of an arterial shear stress caused a rapid rise in Ins1,4,5P3 levels which peaked after approximately 30 seconds of flow (2.1 +/- 0.2 fold stimulation) and remained elevated for at least 6 minutes after the initiation of flow. This increased Ins1,4,5P3 concentration is similar in magnitude to the increase caused by 10 microM histamine (2.8 +/- 0.3 fold stimulation). Thus these cells may detect the presence of mechanical stress by a signal transduction pathway involving inositol lipid metabolism.

Fluid flow decreases preproendothelin mRNA levels and suppresses endothelin-1 peptide release in cultured human endothelial cells

Endothelin-1, a 21-amino acid peptide secreted by endothelial cells, has constrictor and mitogenic activity for vascular smooth muscle cells, and its mitogenic activity is synergistic with that of platelet-derived growth factor. Endothelial cell-derived endothelin-1 might therefore contribute to intimal hyperplasia in reendothelialized segments of vascular grafts or of endarterectomy and angioplasty sites. Because intimal hyperplasia occurs most often at sites with disordered flow patterns and lower fluid shear stress, we tested the effects of static culture versus high laminar shear stress (25 dyne/cm2) on endothelin-1 precursor (preproendothelin) gene mRNA transcript levels and endothelin-1 peptide release in cultured human endothelial cells. Primary cultures of human umbilical vein endothelial cells were subjected to controlled levels of shear stress in parallel plate flow chambers for 24 hours. To detect preproendothelin mRNA we applied a linked reverse transcriptase-polymerase chain reaction (RT/PCR) to RNA extracted from cultures. Southern blots of RT/PCR reaction products were hybridized with radioactive phosphorous (32P) labeled probes for the amplified preproendothelin complementary deoxyribonucleic acid (cDNA). Detection by RT/PCR of mRNA for glyceraldehyde 3-phosphate dehydrogenase was used to measure a constitutively expressed control signal. Endothelin-1 release into culture medium was measured by radioimmunoassay. Application of 25 dyne/cm2 of shear stress for 24 hours sharply reduced endothelial cell levels of precursor preproendothelin mRNA.(ABSTRACT TRUNCATED AT 250 WORDS)