Andrew R. Garcia scite author profile

The human insulin (HI) Langmuir monolayer at the air-water interface was systematically investigated in the presence and absence of Zn(II) ions in the subphase. HI samples were dissolved in acidic (pH 2) and basic (pH 9) aqueous solutions and then spread at the air-water interface. Spectroscopic data of aqueous solutions of HI show a difference in HI conformation at different pH values. Moreover, the dynamics of the insulin protein showed a dependence on the concentration of Zn(II) ions. In the absence of Zn(II) ions in the subphase, the acidic and basic solutions showed similar behavior at the air-water interface. In the presence of Zn(II) ions in the subphase, the surface pressure-area and surface potential-area isotherms suggest that HI may aggregate at the air-water interface. It was observed that increasing the concentration of Zn(II) ions in the acidic (pH 2) aqueous solution of HI led to an increase of the area at a specific surface pressure. It was also seen that the conformation of HI in the basic (pH 9) medium had a reverse effect (decrease in the surface area) with the increase of the concentration of Zn(II) ions in solution. From the compression-decompression cycles we can conclude that the aggregated HI film at air-water interface is not stable and tends to restore a monolayer of monomers. These results were confirmed from UV-vis and fluorescence spectroscopy analysis. Infrared reflection-absorption and circular dichroism spectroscopy techniques were used to determine the secondary structure and orientation changes of HI by zinc ions. Generally, the aggregation process leads to a conformation change from α-helix to β-strand and β-turn, and at the air-water interface, the aggregation process was likewise seen to induce specific orientations for HI in the acidic and basic media. A proposed surface orientation model is presented here as an explanation to the experimental data, shedding light for further research on the behavior of insulin as a Langmuir monolayer.

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Magnetic particle templating of hydrogels: engineering naturally derived hydrogel scaffolds with 3D aligned microarchitecture for nerve repair

Lacko

Singh

Wall

et al. 2020

J. Neural Eng.

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Objective. Hydrogel scaffolds hold promise for a myriad of tissue engineering applications, but often lack tissue-mimetic architecture. Therefore, in this work, we sought to develop a new technology for the incorporation of aligned tubular architecture within hydrogel scaffolds engineered from the bottom-up. Approach. We report a platform fabrication technology—magnetic templating—distinct from other approaches in that it uses dissolvable magnetic alginate microparticles (MAMs) to form aligned columnar structures under an applied magnetic field. Removal of the MAMs yields scaffolds with aligned tubular microarchitecture that can promote cell remodeling for a variety of applications. This approach affords control of microstructure diameter and biological modification for advanced applications. Here, we sought to replicate the microarchitecture of the native nerve basal lamina using magnetic templating of hydrogels composed of glycidyl methacrylate hyaluronic acid and collagen I. Main results. Magnetically templated hydrogels were characterized for particle alignment and micro-porosity. Overall MAM removal efficacy was verified by 96.8% removal of iron oxide nanoparticles. Compressive mechanical properties were well-matched to peripheral nerve tissue at 0.93 kPa and 1.29 kPa, respectively. In vitro, templated hydrogels exhibited approximately 36% faster degradation over 12 h, and were found to guide axon extension from dorsal root ganglia. Finally, in a pilot in vivo study utilizing a 10 mm rat sciatic nerve defect model, magnetically templated hydrogels demonstrated promising results with qualitatively increased remodeling and axon regeneration compared to non-templated controls. Significance. This simple and scalable technology has the flexibility to control tubular microstructure over long length scales, and thus the potential to meet the need for engineered scaffolds for tissue regeneration, including nerve guidance scaffolds.

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Processing-size correlations in the preparation of magnetic alginate microspheres through emulsification and ionic crosslinking

Garcia

Lacko

Snyder

et al. 2017

Colloids and Surfaces A: Physicochemical and Engineering Aspect

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Magnetic alginate microspheres are biocompatible due to their alginate matrix, and motion-controllable by applied magnetic fields due to their magnetic character. Therefore, they have the potential of being used as vessels to a broad variety of materials, including drugs and therapeutic agents, facilitating entry to biological systems in a relatively non-invasive manner. Here, magnetic alginate microspheres were prepared through an emulsification and ionic cross-linking process, where a mixture of alginate and iron oxide magnetic nanoparticles was initially dispersed in a continuous phase, followed by gelation of this dispersed phase into microspheres by cross-linking the dispersion with calcium ions. The resulting magnetic alginate microspheres were found to be superparamagnetic and to respond to applied magnetic fields by chain formation. The effect of shear rate, alginate concentration, and magnetic nanoparticle concentration on microsphere size was investigated with the aim to control the size of microspheres with respect to process and formulation parameters. Two of these parameters, shear rate and alginate concentration, were used to correlate experimental results with a theoretical model for the case where the dispersed phase is more viscous than the continuous phase.

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Andrew R. Garcia

Human insulin fibril-assisted synthesis of fluorescent gold nanoclusters in alkaline media under physiological temperature

Study of the Aggregation of Human Insulin Langmuir Monolayer

Magnetic particle templating of hydrogels: engineering naturally derived hydrogel scaffolds with 3D aligned microarchitecture for nerve repair

Processing-size correlations in the preparation of magnetic alginate microspheres through emulsification and ionic crosslinking

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