Xiomara Calderon-Colon

Structure and properties of collagen vitrigel membranes for ocular repair and regeneration applications

The frequency of ocular injuries on the battlefield has been steadily increasing during recent conflicts. Combat-related eye injuries are difficult to treat and solutions requiring donor tissue are not ideal and are often not readily available. Collagen vitrigels have previously been developed for corneal reconstruction, but increased transparency and mechanical strength are desired for improved vision and ease of handling. In this study, by systematically varying vitrification temperature, relative humidity and time, the collagen vitrigel synthesis conditions were optimized to yield the best combination of high transparency and high mechanical strength. Optical, mechanical, and thermal properties were characterized for each set of conditions to evaluate the effects of the vitrification parameters on material properties. Changes in denaturing temperature and collagen fibril morphology were evaluated to correlate properties with structure. Collagen vitrigels with transmittance up to 90%, tensile strength up to 12 MPa, and denaturing temperatures that significantly exceed the eye/body temperature have been synthesized at 40 °C and 40% relative humidity for one week. This optimal set of conditions enabled improvements of 100% in tensile strength and 11% in transmittance, compared to the previously developed collagen vitrigels.

Evaluation of the biocompatibility of regenerated cellulose hydrogels with high strength and transparency for ocular applications

Prompt emergency treatment for ocular injury, particularly in a battlefield setting, is essential to preserve vision, reduce pain, and prevent secondary infection. A bandage contact lens that could be applied in the field, at the time of injury, would protect the injured ocular surface until hospital treatment is available. Cellulose, a natural polymer, is widely used in biomedical applications including bandage materials. Hydrogels synthesized from different cellulose sources, such as plants, cotton, and bacteria, can have the optical transparency and mechanical strength of contact lenses, by tailoring synthesis parameters. Thus, we optimized the fabrication of cellulose-based hydrogels and evaluated their in vivo biocompatibility and related physical properties. Our data demonstrate that along with tailorable physical properties, our novel cellulose-based hydrogels could be made with contact lens geometry, exhibit no significant signs of material toxicity after 22 days of in vivo testing, and show significant promise for use as a corneal bandage immediately following ocular trauma.

Influence of collagen source on fibrillar architecture and properties of vitrified collagen membranes.

Collagen vitrigel membranes are transparent biomaterials characterized by a densely organized, fibrillar nanostructure that show promise in the treatment of corneal injury and disease. In this study, the influence of different type I collagen sources and processing techniques, including acid-solubilized collagen from bovine dermis (Bov), pepsin-solubilized collagen from human fibroblast cell culture (HuCC), and ficin-solubilized collagen from recombinant human collagen expressed in tobacco leaves (rH), on the properties of the vitrigel membranes was evaluated. Postvitrification carbodiimide crosslinking (CX) was also carried out on the vitrigels from each collagen source, forming crosslinked counterparts BovXL, HuCCXL, and rHXL, respectively. Collagen membrane ultrastructure and biomaterial properties were found to rely heavily on both collagen source and crosslinking. Bov and HuCC samples showed a random fibrillar organization of collagen, whereas rH vitrigels showed remarkable regional fibril alignment. After CX, light transmission was enhanced in all groups. Denaturation temperatures after CX increased in all membranes, of which the highest increase was seen in rH (14.71°C), suggesting improved thermal stability of the collagen fibrils in the membranes. Noncrosslinked rH vitrigels may be reinforced through CX to reach levels of mechanical strength and thermal stability comparable to Bov.

Multiscale modeling of high-strength fibers and fabrics

Using a combination of electronic structure calculations, molecular dynamics simulations, and finite-element analysis, we examine the physical mechanisms governing the performance of Kevlar®/carbon composite fibers over a variety of length scales. To begin, we use electronic structure calculations to examine the molecular structure of Kevlar polymers, and quantitatively compare the intramolecular interactions to the non-bonded intermolecular interactions. We then quantify the potential energy landscape between polymers, and fit this data to a potential function for use in molecular dynamics simulations. From molecular dynamics simulations, we calculate the stiffness and elastic modulus of pristine Kevlar fibrils and Kevlar/carbon composite fibrils. We then use a finite-element model of Kevlar fabric to examine how changes in the mechanical properties of the fibers affect the ballistic response of the fabric. These findings provide insight into how carbon fragments, which influence the nanostructure of the polymer, can enhance the ballistic performance of Kevlar fabric layers.

Solid Lipid Nanoparticles (SLNs) for Intracellular Targeting Applications.

Nanoparticle-based delivery vehicles have shown great promise for intracellular targeting applications, providing a mechanism to specifically alter cellular signaling and gene expression. In a previous investigation, the synthesis of ultra-small solid lipid nanoparticles (SLNs) for topical drug delivery and biomarker detection applications was demonstrated. SLNs are a well-studied example of a nanoparticle delivery system that has emerged as a promising drug delivery vehicle. In this study, SLNs were loaded with a fluorescent dye and used as a model to investigate particle-cell interactions. The phase inversion temperature (PIT) method was used for the synthesis of ultra-small populations of biocompatible nanoparticles. A 3-(4,5-dimethylthiazol-2-yl)-2,5-diphenylphenyltetrazolium bromide (MTT) assay was utilized in order to establish appropriate dosing levels prior to the nanoparticle-cell interaction studies. Furthermore, primary human dermal fibroblasts and mouse dendritic cells were exposed to dye-loaded SLN over time and the interactions with respect to toxicity and particle uptake were characterized using fluorescence microscopy and flow cytometry. This study demonstrated that ultra-small SLNs, as a nanoparticle delivery system, are suitable for intracellular targeting of different cell types.

Multi-scale Testing Techniques for Carbon Nanotube Augmented Kevlar

We explore a method for improving the ballistic performance of Kevlar by augmentation with multi-walled carbon nanotubes (MWNTs). When developing new and improved soft armor, ballistic testing is expensive while the crude data obtained provide limited insight into those mechanisms which enable smart design. Therefore, we tested and modeled yarns and fabrics at various length scales to optimize our synthesis process and understand mechanisms contributing to ballistic performance, thus necessitating ballistic testing of only the potential best performers. Tensile testing of treated yarns was performed to measure the strength and modulus, both linked to ballistic performance, and to evaluate the relative success in infiltrating the Kevlar with MWNTs. Yarn friction and yarn pull-out tests were performed to measure the static and kinetic yarn-to-yarn interactions (friction), also critical to performance during a ballistic event. Example results from mechanical testing over multiple length scales, including ballistic testing, are reported. Finite element modeling was also used to study the effects of the fabric material properties and friction on ballistic performance. Simulation results were correlated with experimental data and used to guide materials optimization.

Banded structures in collagen vitrigels for corneal injury repair.

There is a growing interest in using collagen vitrigels for corneal injury repair. We recently reported the synthesis and thermal denaturation behavior of these gels. In this paper, the banded structure in these vitrified gels is studied by small-angle X-ray scattering (SAXS) one-dimensional (1-D) correlation function analysis and transmission electron microscopy (TEM). Results demonstrate that the collagen vitrigel possess banded structures similar to those of the starting type I collagen, with an average D-spacing of 64nm (by SAXS) or 57nm (by TEM). A combination of SAXS 1-D correlation function analyses and TEM show that overlap and gap distances ranged from 30 to 33nm and from 23 to 25nm, respectively. Changing the vitrification condition does not impact on the banded structure significantly.