Fc coated micro/nanoparticles for humoral immune system modulation

Pacheco, Patricia Marie

07 January 2016

The body’s humoral immune response plays a larger role in the body’s defenses beyond screening for invading pathogens. Modulation of this response is also vital for tissue regeneration, drug delivery, and vaccine development. The immune system operates within a complicated feedback loop and as such, altering the strength of the immune response can be approached from an engineering perspective. While a strong initial input can direct the response to either a pro- or anti-inflammatory bias, extreme responses can be deleterious, as in the case of allergic reactions or sepsis. Therefore, the objective of this thesis was to develop a novel biomaterials platform that can be used to alter the immune response in a tunable manner. Antibodies are not only the workhorses of the adaptive immune response but are also powerful immunomodulators through their Fc (constant fragment) regions. By coating microparticles with Fc ligands in variable surface densities, we were able to utilize the sensitivity of multivalent signaling to tune the response of the immune response. Microparticle size was also varied to decouple the effects of physical versus biochemical signaling. The goal of this thesis was to analyze the effects of Fc coated particles on two major components of the humoral immune responses: macrophages and the complement system. We first looked at the mechanical response of macrophages through phagocytosis and found that both Fc density and microparticle size had significant impacts on macrophage phagocytosis. These results also provide a particle delivery “toolbox” for future applications. We then analyzed the downstream effects of Fc particles on macrophage phenotype and on phenotype plasticity. This showed that the addition of Fc particles lead to increased production of TNFα and IL-12 and inverted the response of LPS treated macrophages. Finally, we applied our particles to activate the complement system, an often overlooked cascade of serum protein activation that results in bacterial cell lysis. Cleaved components of the complement system are also powerful chemokines and can act as a vaccine adjuvant. Fc density on particles played a large role in complement system activation, both through the classical and alternative pathway, as it lead to a binary response for smaller particles and a tunable response for larger particles. We then applied these results to create a novel form of antibiotic by using Fc particles to direct complement-mediated bacterial cytotoxicity. The use of immune activation by Fc particles was also applied to better understand and improve the tuberculosis vaccine. Our findings are significant to the biomaterials and immunology fields as we showed that Fc microparticles can generally be used to alter the immune response in a tunable manner for a broad range of applications, as well answering fundamental immunology questions.

Fc

Macrophages

Complement system

Micro- and nanoparticles

Biomaterials

Immunoengineering

Tuberculosis

Hyaluronanové mikro- a nanočástice / Hyaluronan micro- and nanoparticles

Mourycová, Jana

January 2013

The aim of this thesis was to prepare hyaluronic acid micro- and nanoparticles based on electrostatic interactions with oppositely charged molecules. Following parameters were monitored: correlation function behavior, the particle size and zeta potential value. At the beginning, it was necessary to study the behavior of hyaluronan in solution by dynamic light scattering measurement. Micro- and nanoparticles were prepared by mixing different volume ratios of negatively charged hyaluronan and positively charged polyarginine or cetyltrimethylammonium bromide. Micro- and nanoparticles were prepared in aqueous solution as well as in 0,15 M sodium chloride solution (physiological solution). In the case of the hyaluronan solution a polydisperse character of hyaluronan was detected. It was found that the dissolution of hyaluronan in the physiological solution gives us the smaller particle size in opposite to particle size obtained from the same concentrations of hyaluronan dissolved in water. Furthermore, it was found that systems composed of hyaluronan and polyarginine create particle size of about 100 nm. Whereas systems consisting of cetyltrimethylaminoum bromide and hyaluronan form larger particles, in units of hundreds of nanometers, the particle size in physiological solution were smaller than the same systems dissolved in aqueous solution.

SCALABLE SPRAY DEPOSITION OF MICRO-AND NANOPARTICLES AND FABRICATION OF FUNCTIONAL COATINGS

Semih Akin (14193272)

01 December 2022

<p>Micro- and nanoparticles (MNP) attract much attention owing to their unique properties, structural tunability, and wide range of practical applications. To deposit these important materials on surfaces for generating functional coatings, a variety of special delivery systems and coating/printing techniques have been explored. Herein, spray coating technique is a promising candidate to advance the field of nanotechnology due to its low-cost, high-deposition rate, manufacturing flexibility, and compatibility with roll-to-roll processing. Despite great advances, direct scalable spray writing of functional materials at high-spatial resolution through fine patterning without a need of vacuum and mask equipment still remains challenging. Addressing these limitations requires the development of efficient spray deposition techniques and novel manufacturing approaches to effectively fabricate functional coatings. To this end, this dissertation employs three different spray coating methods of (1) cold spray; (2) atomization-assisted supersonic spray, and (3) dual velocity regime spray to address the aforementioned limitations. A comprehensive set of coating materials, design principles, and operational settings for each spray system are tailored for rapid, direct, and sustainable deposition of MNP on various substrates. Besides, through the two-phase flow modeling, droplets dispersion and deposition characteristics were investigated under both subsonic and supersonic flow conditions to uncover the process-structure-property relationships of the established spray systems. Moreover, novel spray-based manufacturing approaches are developed to fabricate functional coatings in various applications, including (i) functional polymer metallization, (ii) printed flexible electronics, (iii) advanced thin-film nanocoating, (iv) laser direct writing, and (v) electronic textiles.</p>

Additive manufacturing

Flexible manufacturing systems

Composite and hybrid materials

Functional materials

Nanomanufacturing

cold spray

spray dynamics

micro-and nanoparticles

functional coating

additive manufacturing

advanced manufacturing

supersonic flow

computational fluid dynamics

electroless plating

flexible electronics

energy harvesting

laser direct writing

electronic textiles