Microgel bioconjugates for targeted delivery to cancer cells

Blackburn, William H.

25 August 2008

The use of hydrogel nanoparticles, or nanogels, as targeted delivery vehicles to cancer cells was described. The nanogels were synthesized by free radical precipitation polymerization, with poly(N-isopropylmethacrylamide) as the main monomer, and have a core/shell architecture. The nanogels were near 50 nm in radius, contained fluorescein for visualization, and had an amine-containing shell for bioconjugation, making these particles ideal for delivery studies. The nanogels were conjugated with the YSA (YSAYPDSVPMMSC) peptide, which is an ephrin mimic, allowing for uptake by the EphA2 (erythropoietin-producing hepatocellular) receptor. We have delivered YSA-conjugated nanogels to Hey cells and BG-1 cells, as evidenced by fluorescence microscopy. We have shown that the nanogels can encapsulate siGLO Red Transfection Indicator (siGLO) and deliver the siGLO to Hey cells in vitro. After successful delivery of the non-targeting siGLO, we delivered siRNA for knockdown of epidermal growth factor receptor (EGFR). We have shown protein knockdown from 24-120 h after nanogel delivery, as well as knockdown with different siRNA concentrations delivered to the cells. Furthermore, addition of taxol following EGFR knockdown suggests that the chemosensitivity of the Hey cells is increased. Successful in vitro delivery of the nanogels prompted in vivo studies with the nanogels. The nanogels were used to encapsulate silver nanoclusters for potential bioimaging applications. Targeting of the nanogels to MatrigelTM plugs in mice suggest that the particles hold promise as in vivo delivery agents.

In vivo

In vitro

SiRNA

Nanogels

Targeted delivery

Colloids

Colloids in medicine

Drug delivery systems

Mechanical regulation of bone regeneration and vascular growth in vivo

Boerckel, Joel David

03 May 2011

Regeneration of large bone defects presents a critical challenge to orthopaedic clinicians as the current treatment strategies are severely limited. Tissue engineering has therefore emerged as a promising alternative to bone grafting techniques. This approach features the delivery of bioactive agents such as stem cells, genes, or proteins using biomaterial delivery systems which together stimulate endogenous repair mechanisms to regenerate the tissue. Because bone is a highly mechanosensitive tissue which responds and adapts dynamically to its mechanical environment, application of mechanical stimuli may enhance endogenous tissue repair. While mechanical loading has been shown to stimulate bone fracture healing, the ability of loading to enhance large bone defect regeneration has not been evaluated. The goal of this thesis was to evaluate the ability of sustained osteogenic growth factor delivery and functional biomechanical loading to stimulate vascularized repair of large bone defects in a rat segmental defect model. First, we evaluated the hypothesis that the relationship between protein dose and regenerative efficacy depends on delivery system. We determined the dose-response relationship between dose of recombinant human bone morphogenetic protein-2 (rhBMP-2) and bone regeneration in a hybrid alginate-based protein delivery system and compared with the current clinically-used collagen sponge. The hybrid delivery system improved bone formation and reduced the effective dose due to its sustained delivery properties in vivo. Next, we tested the hypothesis that transfer of compressive ambulatory loads during segmental defect repair enhances bone formation and subsequent limb regeneration. We found that delayed application of axial loads enhanced bone regeneration by altering bone formation, tissue differentiation and remodeling, and local strain distribution. Finally, we evaluated the hypothesis that in vivo mechanical loading can enhance neovascular growth to influence bone formation. We found that early mechanical loading disrupted neovascular growth, resulting in impaired bone healing, while delayed loading induced vascular remodeling and enhanced bone formation. Together, this thesis presents the effects of dose and delivery system on BMP-mediated bone regeneration and demonstrates for the first time the effects of in vivo mechanical loading on vascularized regeneration of large bone defects.

Bone regeneration

Vascular growth

Mechanical loading

Bone regeneration

Guided tissue regeneration

Drug delivery systems

Loads (Mechanics)

The impact of physical and biological factors on intracellular uptake, trafficking and gene transfection after ultrasound exposure

Liu, Ying

23 March 2011

We used megahertz pulsed ultrasound and studied gene transfection with a human prostate cancer cell line. We first studied the compromise of cell viability and uptake efficiency and found out that increasing sonication temperature or changing US contrast agents could improve drug/gene delivery mediated by US exposure. We also found that accounting for cell debris after sonication was important to correctly determine cell viability. Next, we verified the capability of US to deliver DNA into the cell nuclei, which is necessary for successful gene transfection. Under the optimal sonication conditions, ~ 30% of cells showed DNA uptake right after US exposure and most had a portion of DNA already localized in the cell nuclei. The maximum transfection efficiency was ~ 12% at 8 h post US exposure. From the DNA perspective, ~ 30% of DNA was localized in the cell nuclei immediately after US exposure and ~ 30% was in the autophagosomes/ autophagolysosomes with the rest ¡°free¡± in the cytoplasm. At later time up to 24 h, DNA continued to be distributed ~ 30% in the nuclei and most or all of the rest in autophagosomes/autophagolysosomes. Our results showed that US was able to deliver DNA into the cell nuclei shortly after the treatment and that the rest of DNA was mostly cleared by autophagosomes/autophagolysosomes. To further increase transfection efficiency, we then studied the differences between live cells with DNA uptake and those with successful gene transfection post US exposure using cell sorting, cell cycle and microarray analysis. Cells with gene transfection were found to accumulate at the G1 phase of cell cycle and associate with the up-regulation of 32 genes (e.g., GADD45¦Á) and the down-regulation of 46 genes (e.g., TOP2¦Á). Drugs that regulate the expression levels of GADD45¦Á and TOP2¦Á were found to further enhance the transfection mediated by US. A maximun increase of ~ 2 fold in transfection efficiency was observed when cells were sonicated with 0.6 mg/mL ethyl methanesulfonate to up-regulate GADD45¦Á. These results suggestted that using drugs that regulate certain introcellular processes could further enhance US-mediated gene transfection. Over a broad range of US conditions, the integrity of three common gene delivery vectors, plasmid DNA, siRNA and adeno-associated virus, were not affected by US exposure. This thesis verified that US was able to delivery DNA into the cell nuclei to facilitate rapid gene transfection, and provided a proof of princible that by modulating certain intracellular processes, the efficiency of US-mediated gene transfection could be further increased. US could potentially be a safe and efficient method for gene therapy.

Drug delivery

Gene therapy

Gene transfection

Ultrasound

Drug delivery systems

Ultrasonics in medicine

Cell death

Nanoparticle use in the modulation of transplant rejection in a murine model

Kassis, Elias Noah

10 September 2010

Solid organ transplant has emerged over the last half century as an important treatment for solid organ failure. Management has matured dramatically over the past two decades with improvements in acute rejection, but long-term graft survival has improved very little and current treatment is limited by the side-effects and toxicities of immunosuppressive medications. Nanoparticle delivery of therapeutics, improving transport characteristics and decreasing systemic and local toxicity has emerged as a dynamic treatment modality, but little work has been done using nanoparticles in transplantation. Our research examined the use of CD4-targeted nanoparticles encapsulated with mycophenolic acid (MPA), a commonly used immunosuppressant in organ transplantation. This work is the first to examine antigen-specific targeting of nanoparticles in any transplant model. MPA-loaded particles show a slow and continuous release profile and biodistribution suggested retention in the spleen. Targeting of nanoparticles to CD4 T cells was suggested using ex vivo and in vitro flow cytometry. In the fully allogeneic MHCII mismatch BALB/C to C57BL/6 mice we found improved graft survival in the non-targeted MPA group and even greater graft survival in the CD4-targeted group. Targeted and non-targeted particle groups showed equal delay in rejection in the less immunogenic single MHC mismatch B6.H-2bm12 to C57BL/6 model that we showed to be CD4 dependent. In both models, graft survival times were increased over free drug and controls with roughly one thousand fold lower dose of drug in the nanoparticles as compared with free MPA. Consistent with these findings were decreased proliferation with targeted and non-targeted MPA-nanoparticles using in vitro and ex vivo mixed lymphocyte reactions. We postulated that the similar rejection times in targeted and non-targeted groups was due to dendritic cell (DC) involvement and we found active uptake of nanoparticles in DCs, a decrease in inflammatory cytokine production and a decrease in treated DCs ability to stimulate T cells via mixed lymphocyte reactions. Furthermore we found a possible mechanism in the DC interaction with T cells through the upregulation of the inhibiting co-stimulatory molecules B7-DC and B7-H1 on DCs treated with MPA-nanoparticles. We also found possible upregulation of CD4+CD25+ Foxp3 expressing Tregs which may serve to increase graft acceptance. These results explore the involvement of dendritic cells in the process of nanoparticle-induced graft acceptance and suggest the feasibility of using nanoparticle drug vectors in clinical transplant.

nanoparticles

drug delivery systems

mycophenolic acid

dendritic cells

graft rejection

transplantation tolerance

Solubilization and release studies of small molecules in polymeric micelles /

Teng, Yue,

January 2000

Thesis (Ph. D.)--University of Texas at Austin, 2000. / Vita. Includes bibliographical references (leaves 166-173). Available also in a digital version from Dissertation Abstracts.

PLGA-based nanoparticles for targeting of dendritic cells in cancer immunotherapy and immunomonitoring

Ghotbi, Zahra.

January 2010

Thesis (M.Sc.)--University of Alberta, 2010. / A thesis submitted to the Faculty of Graduate Studies and Research in partial fulfillment of the requirements for the degree of Master of Science in Pharmaceutical Sciences. Title from pdf file main screen (viewed on February 17, 2010). Includes bibliographical references.

Quantification and control of ultrasound-mediated cell death modes

Hutcheson, Joshua Daniel.

January 2008

Thesis (M. S.)--Chemical Engineering, Georgia Institute of Technology, 2009. / Committee Chair: Prausnitz, Mark; Committee Member: Bommarius, Andreas; Committee Member: Jones, Christopher; Committee Member: Sambanis, Athanassios. Part of the SMARTech Electronic Thesis and Dissertation Collection.

The modification of insulin to enhance oral delivery systems

Kanzelberger, Melissa Ann

09 August 2012

While a number of PEGylated proteins have been studied for injectable applications and reviewers have used this data to speculate possible oral delivery improvements, a detailed investigation of PEGylated insulin for oral delivery and the development of an optimized pH-sensitive carrier for PEGylated insulin conjugates had yet to be accomplished. In order to proceed with oral delivery study, improvements in yield, with respect to previous PEGylation methods were necessary to enable the completion of high throughput drug delivery studies. Subsequently, a reaction scheme for the covalent attachment of PEG to insulin using nitrophenyl carbonate-PEG was developed. It was demonstrated that this reaction occurred at a 1:1 ratio and was site specific at the B29Lys position. A P(MAA-g-EG) hydrogel carrier was developed to optimize loading and release behavior for PEGylated insulin. It was demonstrated that the density and length of polymer grafts affected both loading and release behavior of PEGylated insulin. The best performing grafted polymers had a 3:1 methacrylic acid: ethylene glycol (MAA:EG) ratio and achieved loading efficiencies from 96% to nearly 100%. With respect to release, polymer particles containing fewer, but longer grafts shown to release faster than polymers with shorter grafts with the same MAA:EG ratio. Finally, the effects of PEGylation on intestinal absorption was investigated using an intestinal epithelial model as well as a rat model. It was demonstrated that PEGylated insulin in the presence of P(MAA-g-EG) microparticles did not significantly alter the tight junctions over unmodified insulin. However, the conjugate permeabilities across the membrane were reduced. The pharmacological availability (PA) was then verified by injecting the insulin conjugates subcutaneously in fasted Sprague-Dawley rats. It was determined that PEG 1000 insulin (1KPI) had a PA roughly equivalent to insulin, while it was reduced by 59% for 2KPI and by 81% for 5KPI. The effectiveness of utilizing PEGylated insulin as an oral drug delivery candidate was evaluated with a closed loop intestinal study, in which PEGylated insulin or insulin in solution was delivered directly to the jejunum. It was shown that 1KPI and insulin performed identically; with a pharmacological availability of 0.56%. 2KPI, however improved the pharmacological availability of insulin by 2.8 times. These results demonstrate that PEGylation holds promise for improving the oral delivery of proteins. / text

Insulin

Oral delivery systems

PEGylated insulin

Drug delivery systems

PEG

Hydrogel carrier

PEGylation

In vivo and ex vivo studies of intraocular tamponade agents and their clinical relevance in intraocular drug delivery

Ma, Da, 马达

January 2010

published_or_final_version / Anatomy / Master / Master of Philosophy

Ophthalmic drugs.

Ocular pharmacology.

Biocompatibility.

Drug delivery systems.

Therapeutics, Ophthalmological.

Retinal detachment - Surgery.

Spray freezing into liquid to produce protein microparticles

Yu, Zhongshui

14 May 2015

Recent advances in molecular biology have led to an explosive growth in the number of peptide and protein drugs derived from both recombinant technology and conventional peptide drug design. However, development of peptide and protein therapeutics has proven to be very challenging because of inadequate physical and chemical stability. In recent years, particle engineering processes have become promising approaches for enhancement of protein stability as well as provide options for more delivery routes. In this research program, spray freezing into liquid (SFL) process was developed and optimized in order to achieve broad platform and application in protein and peptide drug delivery systems. The overall goal of this research was to produce stabilized protein and peptide microparticles for various drug delivery systems by using SFL particle engineering technology. Firstly, the use of the SFL process to produce peptide microparticles was investigated. Insulin microparticles produced by the SFL process were highly porous, low tap density and narrow particle size distribution. The influence of the SFL process parameters and excipients on the physicochemical properties of peptide microparticles was determined and compared to the widely used particle formation technique--freeze-drying. The SFL process was further used to produce protein microparticles. In the study, bovine serum albumin (BSA), a medium sized protein, was used as a model drug. The influence of SFL process parameters and excipients on the stability of BSA was studied. Very low monomer loss of BSA was found in this study even though the specific surface area of the powder was very high. Results also demonstrated that the SFL process had minimal influence on protein structure. The SFL process was further investigated by comparing the SFL process to spray freeze drying process (SFD), which is a relatively new process to produce protein and peptide microparticles. The influence of atomization, freezing and drying on the stability of lysozyme was investigated for both the SFL and SFD process. This study tested the hypothesis that the SFL process is a better process than SFD process because of avoiding air-liquid interface and minimum interfacial surface absorption of protein in SFL process. The particle size of protein and peptide microparticles produced by SFL process was further reduced to nanoparticles by sonication or homogenization processes in organic solvent. In this study, the influence of process parameters on the particle size and enzyme activity of lysozyme was investigated. The results showed that sonication or homogenization did not influence the enzyme activity of lysozyme. Lastly, insulin and insulin/dextran microparticles produced by SFL the process was encapsulated into polymer microspheres for oral delivery. Complexation and polymer composition was studied in order to optimize release and stability of insulin. Insulin nanoparticles in microspheres minimized the release of insulin in acid with high drug loading compared to other studies. The stability of insulin was decreased by complexation to dextran sulfate. The results of this research demonstrated that the SFL process offers a highly effective approach to produce protein and peptide powders suitable for different drug delivery systems. The microparticles produced by the SFL process had desirable characteristics such as narrow particle size distribution and high porosity. The stability of protein and peptide was well maintained through the SFL process. Therefore, SFL process is an effective particle engineering process for protein and peptide pharmaceuticals. / text

Particle engineering processes

Protein stability

Spray freezing into liquid

Protein microparticles

Peptide drug delivery systems

SFL