Elastin-like Polypeptide Enriched Surfaces for Cardiovascular Applications through the use of Bioactive Fluorinated Surface Modifiers

Blit, Patrick

20 March 2012

Currently used small diameter synthetic vascular grafts are prone to high rates of failure related to thrombosis and neointimal hyperplasia. Biomimetic materials, based on the extracellular matrix (ECM) composition of native tissues, represent an attractive solution to address these complications. The inherent low thrombogenicity and cell signalling properties of elastin-like polypeptides (ELPs) make them a suitable option for these applications. In this thesis, ELP surface modification has been achieved through the use of elastin cross-linking peptide bioactive fluorinated surface modifiers (ECP-BFSMs). The synthesis of these low molecular weight fluorinated additives was described and their subsequent blending with a base polycarbonate-urethane (PCNU) was shown to successfully enrich the surface to allow for ELP surface cross-linking. The kinetic surface migration of fluorescent ECP-BFSMs was studied over a 2 week casting period by two-photon confocal microscopy. Contact angle and x-ray photoelectron spectroscopy (XPS) confirmed the surface localization of the ECP-BFSMs. Changes in contact angle and XPS spectrums following ELP surface cross-linking confirmed the success of the surface modification approach. The novel ELP surface modified materials were demonstrated to inhibit fibrinogen surface adsorption and platelet adhesion under physiological flow conditions and inhibit bulk platelet activation following blood-material contact. Moreover, these ELP modified surfaces were shown to promote increased endothelial and smooth muscle cell adhesion, spreading and retention over a 7 day culture period relative to their non-ELP analogs. Endothelial and smooth muscle cells seeded on the elastin-like materials were shown to express endothelial nitric oxide synthase (eNOS) and smooth muscle myosin heavy chain (SM-MHC) cell specific phenotypic markers, respectively. Furthermore, competitive inhibition experiments revealed that initial smooth muscle cell adhesion to ELP surface modified materials was mediated through elastin-laminin cell surface receptors binding to VGVAPG peptide sequences on the ELP molecules. Hence, these materials may have broad applicability in cardiovascular applications, from blood contacting materials to scaffold structures for vascular graft tissue engineering. Furthermore, this surface modifying additive approach represents a versatile technique that can be custom tailored for various biomimetic applications to generate stable bioactive ECM-like surfaces retained onto a relatively inert fluorinated background.

biomaterials

elastin-like polypeptides

0541

Elastin-like Polypeptide Enriched Surfaces for Cardiovascular Applications through the use of Bioactive Fluorinated Surface Modifiers

Blit, Patrick

20 March 2012

Currently used small diameter synthetic vascular grafts are prone to high rates of failure related to thrombosis and neointimal hyperplasia. Biomimetic materials, based on the extracellular matrix (ECM) composition of native tissues, represent an attractive solution to address these complications. The inherent low thrombogenicity and cell signalling properties of elastin-like polypeptides (ELPs) make them a suitable option for these applications. In this thesis, ELP surface modification has been achieved through the use of elastin cross-linking peptide bioactive fluorinated surface modifiers (ECP-BFSMs). The synthesis of these low molecular weight fluorinated additives was described and their subsequent blending with a base polycarbonate-urethane (PCNU) was shown to successfully enrich the surface to allow for ELP surface cross-linking. The kinetic surface migration of fluorescent ECP-BFSMs was studied over a 2 week casting period by two-photon confocal microscopy. Contact angle and x-ray photoelectron spectroscopy (XPS) confirmed the surface localization of the ECP-BFSMs. Changes in contact angle and XPS spectrums following ELP surface cross-linking confirmed the success of the surface modification approach. The novel ELP surface modified materials were demonstrated to inhibit fibrinogen surface adsorption and platelet adhesion under physiological flow conditions and inhibit bulk platelet activation following blood-material contact. Moreover, these ELP modified surfaces were shown to promote increased endothelial and smooth muscle cell adhesion, spreading and retention over a 7 day culture period relative to their non-ELP analogs. Endothelial and smooth muscle cells seeded on the elastin-like materials were shown to express endothelial nitric oxide synthase (eNOS) and smooth muscle myosin heavy chain (SM-MHC) cell specific phenotypic markers, respectively. Furthermore, competitive inhibition experiments revealed that initial smooth muscle cell adhesion to ELP surface modified materials was mediated through elastin-laminin cell surface receptors binding to VGVAPG peptide sequences on the ELP molecules. Hence, these materials may have broad applicability in cardiovascular applications, from blood contacting materials to scaffold structures for vascular graft tissue engineering. Furthermore, this surface modifying additive approach represents a versatile technique that can be custom tailored for various biomimetic applications to generate stable bioactive ECM-like surfaces retained onto a relatively inert fluorinated background.

biomaterials

elastin-like polypeptides

0541

Evaluation of a Family of Elastin-like Polypeptide Coatings for Blood Contacting Devices

Srokowski, Elizabeth Martha

07 January 2013

Blood contacting devices are frequently limited by complications such as surface-induced thrombosis. This thesis investigated the feasibility of using a family of recombinant elastin-like polypeptides (ELPs), namely ELP1, ELP2 and ELP4 that differ by molecular weight and sequence length, as potential thromboresistant coatings. The ELP coatings were prepared by physical adsorption onto the surface of Mylar, with surface modification confirmed by goniometry, X-ray photoelectron spectroscopy (XPS), and chemical force microscopy (CFM). Both surface wettability and hydrophilic adhesion force increased as the ELP sequence length decreased. The ELP adsorption process monitored by using quartz crystal microbalance with dissipation (QCM-D) showed that the ELPs adsorbed within a monolayer. Additionally, ELP surface coverage was found to increase with the polypeptide sequence length. The QCM-D studies also revealed that the longer polypeptides (ELP2 and ELP4) exhibited higher specific dissipation values indicating that they established adsorbed layers with greater structural flexibility and associated water content compared to ELP1. Exposure of the ELP coatings to flowing reconstituted blood demonstrated that both the ELP2 and ELP4 coatings reduced the quantity of adsorbed fibrinogen (Fg), with the ELP4 coating resulting in the lowest levels of adherent platelets. Energy dissipation versus frequency shift plots obtained from QCM-D studies indicated that adsorbed Fg on the ELP4 coating maintained a softer, more flexible film then on the other ELPs. The ELP4 coating also demonstrated an altered binding activity for GPIIb/IIIa where only the AGDV motif in the adsorbed Fg gamma-chain appeared to be exposed and bioactive. Conversely, on the other ELP coatings both the AGDV and RGD motifs (found within the Fg alpha-chain) were available for binding, suggesting that a different Fg conformational state exists on the ELP1 and ELP2 coatings. Moreover, both the ELP2 and ELP4 coatings displayed minimal bulk platelet reactivity following extended whole blood shear exposure (up to an hour) compared to Mylar. This was not observed with the ELP1 coating. Overall, the results suggest that the structural flexibility and associated water content of the ELP coatings appear to be important criteria influencing their thrombogenicity, with ELP4 displaying the most favourable blood-material response compared to ELP1 and ELP2.

biomaterial

elastin-like polypeptides

hemocompatibility

surface properties

0541

0542

Evaluation of a Family of Elastin-like Polypeptide Coatings for Blood Contacting Devices

Srokowski, Elizabeth Martha

07 January 2013

Blood contacting devices are frequently limited by complications such as surface-induced thrombosis. This thesis investigated the feasibility of using a family of recombinant elastin-like polypeptides (ELPs), namely ELP1, ELP2 and ELP4 that differ by molecular weight and sequence length, as potential thromboresistant coatings. The ELP coatings were prepared by physical adsorption onto the surface of Mylar, with surface modification confirmed by goniometry, X-ray photoelectron spectroscopy (XPS), and chemical force microscopy (CFM). Both surface wettability and hydrophilic adhesion force increased as the ELP sequence length decreased. The ELP adsorption process monitored by using quartz crystal microbalance with dissipation (QCM-D) showed that the ELPs adsorbed within a monolayer. Additionally, ELP surface coverage was found to increase with the polypeptide sequence length. The QCM-D studies also revealed that the longer polypeptides (ELP2 and ELP4) exhibited higher specific dissipation values indicating that they established adsorbed layers with greater structural flexibility and associated water content compared to ELP1. Exposure of the ELP coatings to flowing reconstituted blood demonstrated that both the ELP2 and ELP4 coatings reduced the quantity of adsorbed fibrinogen (Fg), with the ELP4 coating resulting in the lowest levels of adherent platelets. Energy dissipation versus frequency shift plots obtained from QCM-D studies indicated that adsorbed Fg on the ELP4 coating maintained a softer, more flexible film then on the other ELPs. The ELP4 coating also demonstrated an altered binding activity for GPIIb/IIIa where only the AGDV motif in the adsorbed Fg gamma-chain appeared to be exposed and bioactive. Conversely, on the other ELP coatings both the AGDV and RGD motifs (found within the Fg alpha-chain) were available for binding, suggesting that a different Fg conformational state exists on the ELP1 and ELP2 coatings. Moreover, both the ELP2 and ELP4 coatings displayed minimal bulk platelet reactivity following extended whole blood shear exposure (up to an hour) compared to Mylar. This was not observed with the ELP1 coating. Overall, the results suggest that the structural flexibility and associated water content of the ELP coatings appear to be important criteria influencing their thrombogenicity, with ELP4 displaying the most favourable blood-material response compared to ELP1 and ELP2.

biomaterial

elastin-like polypeptides

hemocompatibility

surface properties

0541

0542

Modification of Behavior of Elastin-like Polypeptides by Changing Molecular Architecture

Ghoorchian, Ali

11 May 2012

No description available.

elastin like polypeptides

molecular architecture

environmentally responsive materials

Leukocyte Response to Elastin-Like Polypeptide Coatings

Rooney, Meghan

15 October 2013

Small diameter synthetic vascular grafts have yet to be clinically successful due to luminal narrowing from thrombosis and intimal hyperplasia. Current attempts to address this issue include the development of materials that support endothelialisation and protein modification to the material surfaces that reduce thrombosis. The extracellular matrix protein elastin has been found to be one of the least thrombogenic components of blood vessels, and its purified and recombinant forms have shown reduced thrombogenicity in both in vitro and in vivo models. Biomaterial coatings of elastin-like polypeptides (ELPs) recombinantly produced in the Woodhouse laboratory showed reduced fibrinogen adsorption, platelet adhesion, and platelet activity. However, the reason for their relative non-thrombogenicity is still not fully understood. In this work, the leukocyte response to ELP-coated materials was investigated. In particular, ELP1 and ELP4, which differ in molecular weight and sequence length, were physically adsorbed to a polyethylene terephthalate surface (MylarTM), yielding 0.22 ± 0.13 μg/cm2 and 0.37 ± 0.19 μg/cm2 surface coverage, respectively, as determined by the colorimetric assay, FastinTM Elastin. These surfaces were exposed to flowing citrated whole blood for surface and bulk evaluation of leukocyte activity using scanning electron microscopy and flow cytometry, respectively. Little leukocyte activation was observed on the surface of the controls, low-density polyethylene and uncoated MylarTM. In the bulk, tissue factor (TF) expression (monocytes: ELP1 = 38.6 ± 16.3 %, ELP4 = 33.9 ± 18.1 %) and platelet-leukocyte aggregates determined by CD61 (monocytes: ELP1 = 63.1 ± 17.1 %, ELP4 = 61.8 ± 16.8 %; granulocytes: ELP1 = 62.7 ± 17.0 %, ELP4 = 60.5 ± 20.1 %) were both decreased compared to uncoated MylarTM, while CD11b upregulation (monocytes: ELP1 = 18.7 ± 2.2 %, ELP4 = 19.7 ± 2.7 %; granulocytes: ELP = 21.4 ± 3.7 %, ELP4 = 22.0 ± 3.2 %) was increased. The statistical dependence of TF expression and platelet-monocyte aggregates was tested; however, no correlation was found. Overall, platelet-leukocyte aggregate formation was reduced and there were conflicting results with regards to the reduction of leukocyte activation for the ELP coatings on MylarTM. / Thesis (Master, Chemical Engineering) -- Queen's University, 2013-10-10 15:34:51.802

elastin-like polypeptides

cone and plate

blood-contacting devices

shear rate

leukocytes

tissue factor

CD11b

elastin

Expression, Purification, And Characterization Of Elastin-Like Polypeptides Containing Chondroitin Sulphate Binding Domains

Murphy, MARY

07 January 2013

The development of small-diameter artificial blood vessels that mimic the properties of natural blood vessels has proven to be a clinical challenge. While autologous vessels are the standard, they can be difficult to obtain and require invasive surgeries. Synthetic materials have been successful in large diameter applications, but they have been unsuccessful in small-caliber environments due to a number of factors including thrombus formation, intimal hyperplasia, and infection. Intimal hyperplasia, of particular interest in this study, involves the build up of smooth muscle cells (SMCs) in the intimal layer of the artery due to abnormal migration and proliferation. This work focuses on the development of a new polymer that has the potential to function as an intimal/medial component of a small-diameter blood vessel. Using recombinant elastin-like polypeptides (ELPs) developed by the Woodhouse laboratory, as well as chondroitin sulphate-specific binding sequences (CSBD1 and CSBD2) determined by the Panitch laboratory, a new elastin-like polypeptide-chondroitin sulphate binding domain (ELP-CSBD) block copolymer has been developed and characterized. The expression of the ELP1-CSBDs was accomplished using E. coli BL21 cells in a bioreactor or shaker flask systems. The polypeptides were purified using dialysis and ion exchange chromatography and expression and purity were characterized using mass spectrometry and amino acid analysis. Both ELP1-CSBDs were successfully expressed using these methods and ELP1-CSBD1 was produced to high purities. ELP1-CSBD1 was able to undergo coacervation in vitro, suggesting that ELP1-CSBD1 is able to self-assemble in a manner similar to native elastin. In the presence of the glycosaminoglycan chondroitin sulphate (CS), the temperature of coacervation of ELP1-CSBD1 is increased, the rate and extent of coacervation is decreased, and aggregates remain in solution even at higher temperatures. The influence of heparin was also explored as previous studies indicated that the CS binding domains were shown to also bind to heparin. Studies completed in the presence of heparin showed that there were no significant changes to the coacervation characteristics of ELP1-CSBD1. It is anticipated that when combined with CS, ELP1-CSBD1 will gel, forming a basis for an intimal/medial layer of a TEBV that will modulate SMC response and increase graft integrity. / Thesis (Master, Chemical Engineering) -- Queen's University, 2013-01-06 21:03:37.788

tissue engineered blood vessels (TEBVs)

hyperplasia

chondroitin sulphate

coacervation

elastin

elastin-like polypeptides

Understanding Elastin-Like Polypeptide Block Copolymer Self-assembly Behavior

Hassouneh, Wafa Saadat

January 2013

<p>Elastin-like polypeptides (ELPs) are thermally responsive polymers composed of the pentapeptide repeat Valine-Proline-Glycine-X-Glycine where X is any amino acid except proline. ELP diblocks have been engineered by creating two ELP blocks with hydrophilic and hydrophobic guest residues. The hydrophobic block desolvates at a lower temperature and forms the core of a micelle while the still hydrated hydrophilic block forms the corona. ELP micelles are promising drug delivery vehicles for cancer therapeutics. ELP diblocks offer a unique method to display targeting proteins multivalently on micelles to improve tumor cell uptake. As ELPs are genetically encoded, proteins can be seamlessly fused at the genetic level to the ELP diblock. The protein ELP diblock fusions can be synthesized as one polypeptide chain that is of precise molecular weight and highly monodisperse, and no post-synthesis modification is necessary. Self-assembly behavior of ELP diblocks is known to tolerate fusion to small peptides (< 10 amino acids) but their self-assembly behavior has not be examined when fused to proteins that are 100-200 amino acids. Here, we hypothesize that molecular weight of the protein and the surface properties of the protein will be factors in determining its effect on ELP diblock self-assembly. In addition, the ELP block lengths and composition are hypothesized to be factors in the self-assembly behavior of protein ELP diblock fusions. This hypothesis is tested by fusing four proteins with different properties to various ELP diblocks and characterizing their self-assembly behavior. The proteins were found to dominate the self-assembly behavior. Proteins that disrupted self-assembly did so for all ELP diblock lengths and compositions. Protein that did not disrupt self-assembly behavior affected the thermal behavior of the hydrophilic block. Hydrophilic proteins increased the micelle-to-aggregate transition temperature while hydrophobic proteins decreased it. We also sought to understand the self-assembly of ELP diblocks on a theoretical basis. A previously developed model for the self-assembly of synthetic polymers was applied to our polypeptide system. Two parameters, solvent quality of the corona and surface tension of the hydrophobic block, were experimentally measured and used to fit the model. Predictions of micelle radius and aggregation numbers were in good agreement with experimental data. However, the corona was found to be unstretched compared to its Gaussian size by this model. Therefore, a new model was developed describing what is termed as weak micelles in which the corona is not stretched but rather close to Gaussian size. The weak micelle model prediction were also in good agreement with experimental data suggesting that ELP micelles are in the crossover regime between the previous model and the new model.</p> / Dissertation

Biomedical engineering

block copolymer

Elastin-like polypeptides

micelles

multivalent display

protein fusion

self-assembly

Glucagon-Like Peptide-1 Depots for the Treatment of Type-2 Diabetes

Amiram, Miriam

January 2012

<p>Peptide drugs are an exciting class of pharmaceuticals currently in development for the treatment of a variety of diseases; however, their main drawback is a short half-life, which dictates multiple and frequent injections. We have developed two novel peptide delivery approaches -Protease Operated Depots (PODs) and GLP-1-ELP depots- to provide sustained and tunable release of a peptide drug from an injectable s.c. depot. </p><p>We demonstrate proof-of-concept of these delivery systems, by fusion of monomer or protease cleavable oligomers of glucagon-like peptide-1 (GLP-1), a type-2 diabetes peptide drug, and a thermally responsive, depot-forming elastin-like-polypeptide (ELP) that undergoes thermally triggered inverse phase transition below body temperature, thereby forming an injectable depot. Utilizing a novel system we designed for repetitive gene synthesis, various GLP-1 polymers were designed and tested as potential therapeutic payload for PODs. By attachment to various ELPs, designed to transition above or below body temperature, we created both depot forming GLP-ELP fusions and soluble control. All fusion constructs maintained alpha helical content and were shown to be resistant to proteolytic degradation. In vitro activated PODs and GLP-ELP fusions were able to activate the GLP-1 receptor and remarkably, a single injection of both GLP-1 PODs and GLP-ELP fusions were able to reduce blood glucose levels in mice for up to 5 days, 120 times longer than an injection of the native peptide drug. These findings suggest that ELP based peptide depots may offer a modular, genetically encoded alternative to various synthetic peptide delivery schemes for sustained delivery of peptide therapeutics.</p> / Dissertation

Biomedical engineering

Drug Delivery

Elastin Like Polypeptides

Glucagon Like Peptide-1

In Vivo and In Vitro Application of Elastin-Like Polypetides

Ge, Xin

05 1900

Elastin-like polypeptides (ELP) are artificially designed protein biopolymers that can be produced by living organisms. These proteins have the unique ability to undergo reversible inverse phase transition, in response to changes in temperature and/or addition of chaotropic salts. Below the transition temperature (T1) , ELP is soluble in water. Increasing the temperature above Ti, ELP coacervates into an aqeous ELP-rich phase. In this thesis, this unique feature of ELP was used in for recombinant protein purification and for the formation of aqueous multiple-phase systems. For protein purification, ELP was fused with an intein and a model protein (thioredoxin), to demonstrate a simple and inexpensive approach for recombinant protein purification. The ELP tags replace the chromatographic media and the intein replaces the use of the protease in conventional methods. Using ELP tags was found to be consistent with large -scale recombinant protein production/purification by purifying an ELP tagged protein using a stirred cell equipped with a microfiltration membrane. When the temperature and/or salt concer.tration is increased for mixtures containing free ELP and ELP tagged proteins, simultaneous phase transition takes place. This served as the basis for the development of a method suitable for selectively recovering molecules from complex mixtures with high specificity, full reversibility, and virtually unlimited affinity. The second parts of this thesis focus on the ability of ELP to form aqueous twophase systems (A TPS) in vitro and most importantly, in vivo- with the formation of aqueous microcompartments in living cells. These compartments exclude the protein making machinery of the cell, acting as depots for newly expressed protein. It is also shown (in vitro) that ELP bastd droplets exclude proteases, protecting proteins from degradation. These observations are important for high-level production of recombinant proteins. Also described, is the formation of protein based aqueous multiphasic systems, with tunable morphologies. / Thesis / Doctor of Philosophy (PhD)

elastin-like polypeptides

protein biopolymers

aqueous multi-phase system

reversible inverse phase transition

recombinant proteins