Development of Novel Multi-nutrient Nanoparticle Systems for Crop Health management

Pereira, Jorge

01 January 2024

By 2050, the global population is expected to reach 9.7 billion, prompting a projected surge in food demand ranging from 30 to 62 percent. To avert hunger and meet food demand, the United Nations established "Zero Hunger" as part of their sustainable goals. To accomplish this endeavor, it is anticipated that sustainably increasing crop yield and optimizing current agricultural practices are crucial. There is a need for developing advanced crop protection methods given that more than a fourth of crops are lost to pests and pathogens. In recent years, nanotechnology has been utilized to increase the effectiveness of active ingredients, reduce the environmental impact of pesticides, and improve crop yield. Initial work in the field focused on early transition metal oxides, leaving most other nutrients and their combinations unexplored. In this work, Bz, a Boron-Zinc multi-nutrient nanosystem was rationally designed to target the stomata and epidermal cell junctions. This novel formulation was utilized to target the delivery of oxytetracycline (OTC) to improve the antibiotic’s efficacy. The interaction between the agrochemicals was thoroughly studied and evaluated. Furthermore, this combination was evaluated for synergic/antagonistic activity and delivery of oxytetracycline on peach leaves. Additionally, the tank-mix of a Magnesium Hydroxide (MgSol) and Sodium Polysulfide (NaPs) was studied to understand how nanotechnology can be used in tandem with already registered active ingredients. The antimicrobial potency at different concentration ratios of these components was assessed using the checkerboard assay. To understand its properties, the effect of MgSol on the reactivity of NaPs was tested using a colorimetric radical scavenging assay. Subsequently, the physicochemical changes these formulations undergo when suspended in water were correlated with their biological effects on bacteria and plants. Overall, the findings presented in this work demonstrate that multi-nutrient nanoparticle systems exhibit unique properties that can improve crop health management.

Nanotechnology

agriculture

sustainability

targeted delivery

synergistic

antimicrobial

Engineering nanoparticles using chemical and biological approaches for tumor targeted delivery

Nguyen, Tuyen

January 1900

Doctor of Philosophy / Department of Chemistry / Santosh Aryal / Nanotechnology offers exciting options for the site-selective delivery of chemotherapeutics and diagnostic agents using nanoparticles. Varieties of organic and inorganic nanomaterials have been explored extensively as a delivery system either in the form of drug carriers or imaging agents. Successful stories include the clinical translation of anticancer nanomedicines such as PEGylated liposomal doxorubicin (DOXIL®), albumin-bound paclitaxel (Abraxane®), and polymeric micelle loaded paclitaxel (Genexol®), which are currently used in the clinic as one of the first lines for cancer chemotherapies. These conventional nanomedicines rely on passive-drug targeting taking advantage of leaky tumor vasculature, called the Enhanced Permeability and Retention (EPR) effect. However, delivering biologically active components selectively to the diseased cell, for example, cancer, is highly challenging due to the biological barriers in the body including blood pool cells/proteins, heterogeneous microenvironment, and intracellular degradation. Therefore, the goal of this dissertation is to develop nanoplatforms that can deliver the agents of interest in targeted fashion to cancer while bypassing or collaborating with the biological barriers. The design consideration of these nanoplatforms centralizes on using simple chemical reactions and cell biology to engineer nanoparticles. The presented nanoparticles were extensively studied and evaluated for their biological functions using in vitro and in vivo models. These nanoconstructs described herein address current limitations of conventional nanomedicine such as (1) the lack of understanding of the interaction of nanoparticle and biological system, and (2) the lack of an effective targeting strategy to deliver drugs to the cancer cell in the tumors. The significant findings of each system will be highlighted and discussed throughout this dissertation. Results obtained highlight key findings such as NP intracellular fate, maximized tumor accumulation, and unique pharmacokinetics could open the avenues for systemic investigations for personalized medicine and lay the foundation for nanomedicine design to accelerate clinical translation.

nanomedicine

MRI contrast agents

Biomimetic

Cancer

Targeted delivery

polymeric nanoparticles

Improving histone deacetylase inhibition therapy through isoform selectivity and targeted delivery

Sodji, Quaovi Hemeka

08 June 2015

Histone deacetylase (HDAC) inhibition has recently emerged as a novel therapy for cancer treatment. However, currently approved histone deacetylase inhibitors (HDACi) are pan-inhibitors thus inhibiting all 11 zinc dependent HDAC isoforms including those not involved in tumorigenesis. These inhibitors are also associated with various side effects including a potentially fatal cardiotoxicity. To address these issues, isoform selective HDACi were designed and synthesized. The use of 3-hydroxy-pyridin-2-thione (3HPT) as zinc chelation group resulted in small molecules devoid of HDAC1 inhibition but active against HDAC6 and/or 8. Selected 3HPT containing HDACi displayed anticancer activity against various cancer cell lines including DU145, LNCaP and Jurkat. Surprisingly, the lead-compounds were very potent against Jurkat Jγ cells which are resistant to SAHA-induced apoptosis. HDACi were also targeted to cancer cells using folic or pteroic acids as targeting groups. Incorporation of the folic acid into the HDACi pharmacophoric model resulted in inhibitors selective for HDAC6, whereas pteroic-based HDACi inhibited both HDAC1 and 6. Only the pteroic-based inhibitors displayed anticancer activities against folate receptor overexpressing tumors such KB and HeLa. Furthermore, cell-based studies established the inhibition of HDAC1 as the basis for the anticancer activities of the pteroic-based HDACi.

Histone deacetylase (HDAC)

HDAC inhibitors

Isoform selectivity

Targeted delivery

Polymeric Micelles for SiRNA and AON Delivery

Chan, Dianna

21 November 2012

Immuno-nanoparticles of poly(ᴅ,ʟ-lactide-co-2-methyl-2-carboxytrimethylene carbonate)-g-poly(ethylene glycol) (poly(LA-co-TMCC)-g-PEG) have been used to target breast cancer cells through the specific binding of trastuzumab antibodies to over-expressed human epidermal growth factor receptor 2 (HER2). Small interfering RNA (siRNA) and antisense oligonucleotides (AONs) disrupt the synthesis of select proteins. It is hypothesized that oligonucleotides coupled to polymeric immuno-nanoparticles can be used for gene silencing and specifically to target luciferase. The first objective is to demonstrate the capacity to create dual functional micelles with antibodies and oligonucleotides. The second objective is in vitro testing of the nanoparticle for gene silencing activity. Oligonucleotides are conjugated to the nanoparticle by sequential click reactions of Diels Alder chemistry and copper catalyzed azide-alkyne cycloadditions, respectively. A luciferase assay is used to quantify knockdown of luciferase levels in SKOV-3luc cells (HER2+, luc+). When used in conjunction with a targeted drug delivery vehicle, the nanoparticles provide selective interactions with SKOV-3luc cells.

polymer nanoparticles

targeted delivery

gene therapy

drug delivery

0542

Polymeric Micelles for SiRNA and AON Delivery

Chan, Dianna

21 November 2012

Immuno-nanoparticles of poly(ᴅ,ʟ-lactide-co-2-methyl-2-carboxytrimethylene carbonate)-g-poly(ethylene glycol) (poly(LA-co-TMCC)-g-PEG) have been used to target breast cancer cells through the specific binding of trastuzumab antibodies to over-expressed human epidermal growth factor receptor 2 (HER2). Small interfering RNA (siRNA) and antisense oligonucleotides (AONs) disrupt the synthesis of select proteins. It is hypothesized that oligonucleotides coupled to polymeric immuno-nanoparticles can be used for gene silencing and specifically to target luciferase. The first objective is to demonstrate the capacity to create dual functional micelles with antibodies and oligonucleotides. The second objective is in vitro testing of the nanoparticle for gene silencing activity. Oligonucleotides are conjugated to the nanoparticle by sequential click reactions of Diels Alder chemistry and copper catalyzed azide-alkyne cycloadditions, respectively. A luciferase assay is used to quantify knockdown of luciferase levels in SKOV-3luc cells (HER2+, luc+). When used in conjunction with a targeted drug delivery vehicle, the nanoparticles provide selective interactions with SKOV-3luc cells.

polymer nanoparticles

targeted delivery

gene therapy

drug delivery

0542

Dual-use nano-neurotechnology: An assessment of the implications of trends in science and technology

Nixdorff, K., Borisova, T., Komisarenko, S., Dando, Malcolm

29 November 2018

No / The chemical and biological nonproliferation regime stands at a watershed moment, when failure seems a real possibility. After the unsuccessful outcome of the 2016 Eighth Review Conference, the future of the Biological and Toxin Weapons Convention is uncertain. As the Chemical Weapons Convention (CWC) approaches its Fourth Review Conference in 2018, it has almost completed removing the huge stocks of chemical weapons, but it now faces the difficult organizational task of moving its focus to preventing the reemergence of chemical weapons at a time when the international security situation appears to be increasingly more difficult and dangerous. In this article, we assess the current and near-term state (5–10 years) and impact of three related areas of science and technology that could be of dual-use concern: targeted delivery of agents to the central nervous system (CNS), particularly by means of nanotechnology; direct impact of nanomaterials on synaptic functions in the CNS; and neuronal circuits in the brain that might be targeted by those with hostile intent. We attempt to assess the implications of our findings, particularly for the consideration of the problem of state-level interest in so-called nonlethal incapacitating chemical agents for law enforcement at the CWC Review Conference in 2018, but also more generally for the longer-term future of the chemical and biological nonproliferation regime.

Nano-neurotechnology

Targeted delivery

Neurotoxicity

Neuronal circuits

Biochemical security

Hypoxia-Responsive Prodrug of ATR Inhibitor, AZD6738, Selectively Eradicates Treatment-Resistant Cancer Cells

Mprah Barnieh, Francis, Ribeiro Morais, Goreti, Loadman, Paul, Falconer, Robert A., El-Khamisy, Sherif

24 June 2024

Yes / Targeted therapy remains the future of anti-cancer drug development, owing to the lack of specificity of current treatments which lead to damage in healthy normal tissues. ATR inhibitors have in recent times demonstrated promising clinical potential, and are currently being evaluated in the clinic. However, despite the considerable optimism for clinical success of these inhibitors, reports of associated normal tissues toxicities remain a concern and can compromise their utility. Here, ICT10336 is reported, a newly developed hypoxia-responsive prodrug of ATR inhibitor, AZD6738, which is hypoxia-activated and specifically releases AZD6738 only in hypoxic conditions, in vitro. This hypoxia-selective release of AZD6738 inhibited ATR activation (T1989 and S428 phosphorylation) and subsequently abrogated HIF1a-mediated adaptation of hypoxic cancers cells, thus selectively inducing cell death in 2D and 3D cancer models. Importantly, in normal tissues, ICT10336 is demonstrated to be metabolically stable and less toxic to normal cells than its active parent agent, AZD6738. In addition, ICT10336 exhibited a superior and efficient multicellular penetration ability in 3D tumor models, and selectively eradicated cells at the hypoxic core compared to AZD6738. In summary, the preclinical data demonstrate a new strategy of tumor-targeted delivery of ATR inhibitors with significant potential of enhancing the therapeutic index. / University of Bradford STARTER Fellowship

ATR

AZD6738

DNA repair

Hypoxia

Prodrugs

Targeted delivery

Hypoxia-responsive prodrug of ATR inhibitor, AZD6738, selectively eradicates treatment-resistant cancer cells

Mprah Barnieh, Francis, Morais, Goreti R., Loadman, Paul, Falconer, Robert A., El-Khamisy, Sherif

24 June 2024

Yes / Targeted therapy remains the future of anti-cancer drug development, owing to the lack of specificity of current treatments which lead to damage in healthy normal tissues. ATR inhibitors have in recent times demonstrated promising clinical potential, and are currently being evaluated in the clinic. However, despite the considerable optimism for clinical success of these inhibitors, reports of associated normal tissues toxicities remain a concern and can compromise their utility. Here, ICT10336 is reported, a newly developed hypoxia-responsive prodrug of ATR inhibitor, AZD6738, which is hypoxia-activated and specifically releases AZD6738 only in hypoxic conditions, in vitro. This hypoxia-selective release of AZD6738 inhibited ATR activation (T1989 and S428 phosphorylation) and subsequently abrogated HIF1a-mediated adaptation of hypoxic cancers cells, thus selectively inducing cell death in 2D and 3D cancer models. Importantly, in normal tissues, ICT10336 is demonstrated to be metabolically stable and less toxic to normal cells than its active parent agent, AZD6738. In addition, ICT10336 exhibited a superior and efficient multicellular penetration ability in 3D tumor models, and selectively eradicated cells at the hypoxic core compared to AZD6738. In summary, the preclinical data demonstrate a new strategy of tumor-targeted delivery of ATR inhibitors with significant potential of enhancing the therapeutic index. / UoB STARTER Fellowship Award

ATR

AZD6738

DNA repair

Hypoxia

Prodrugs

Targeted delivery

CD-44 targeted nanoparticles for combination therapy in an in vitro model of triple-negative breast cancer: Targeting the tumour inside out

Gómez-Pastor, S., Maugard, A., Walker, Harriet R., Elies, Jacobo, Børsum, K.E., Grimaldi, Giulia, Reina, G., Ruiz, Amalia

07 January 2025

Yes / Triple-negative breast cancer (TNBC) is an aggressive form of breast cancer defined by the lack of three key receptors: estrogen, progesterone, and HER2. This lack of receptors makes TNBC difficult to treat with hormone therapy or drugs, and so it is characterised by a poor prognosis compared to other kinds of breast cancer. This study explores photoactive Poly(lactic-co-glycolic acid) (PLGA) nanoparticles as a potential therapeutic strategy for TNBC. The nanoparticles are functionalised with hyaluronic acid (HA) for targeted delivery to CD-44 receptors overexpressed in TNBC cells, especially under hypoxic conditions. Additionally, we co-loaded the nanoparticles with Doxorubicin (Dox) and Indocyanine Green (ICG) to enable combinatorial chemo-photothermal therapy. After carefully optimising the formulation, we propose an effortless and reproducible preparation of the nanodrugs. We demonstrate that HA-conjugated nanoparticles effectively target TNBC cells and inhibit their proliferation while the treatment efficiency is enhanced during near-infrared light irradiation. We also prove that our treatment is effective in a 3D cell culture model, highlighting the importance of tumour architecture and the metabolic stage of the cells in the tumour microenvironment. This approach is promising for a tumour-targeted theragnostic for TNBC with improved efficacy in hypoxic microenvironments. / A.R would like to thank The Royal Society for the Research Grant (RGS\R1\221399) and the MRC Confidence in Concept University of Bradford grant (RM0039). H.R.W acknowledges support from the University of Bradford PhD studentship (DP154). G.G. and A.R would like to thank the University of Bradford (project RIEDA 66007/002GRI) for funding this research. G.R. acknowledges support from EU-NOVA European Union's Horizon Europe Framework Programme: 101058554.

Targeted delivery

Hyaluronic acid

CD44-targeting

PLGA nanoparticles

Combinatory therapy

Lipooligosaccharide-modified polymeric particles for targeted pulmonary drug delivery

Tu, Mai H.

01 May 2015

Targeted delivery of drugs directly to the lung epithelium is a promising, though challenging, strategy for the treatment of diseases that affect the lung tissues, such as infections caused by cell-penetrating pathogens, cystic fibrosis, and cancer. With appropriate surface functionality, such as through the attachment of ligands that recognize receptors on cellular surfaces, particulate carriers show improved efficiency in penetrating cells in vitro. A useful class of ligands is produced by many natural human pathogens that infect the respiratory tract. A variety of phylogenetically distinct respiratory bacterial pathogens, such as Haemophilus influenzae, invade host cells in the upper airways by binding of the platelet-activating factor (PAF) receptor via lipooligosaccharide (LOS) glycoforms. By expressing host carbohydrate structures, including phosphorylcholine (ChoP), as a terminal structure on the LOS, the bacteria exhibit molecular mimicry of the host and are able to evade the host immune system. The effectiveness of LOS to induce cellular uptake of the bacteria is dependent on the specific glycoform, with higher ChoP content inducing more bacterial adherance into the lung epithelial. These ligands naturally expressed on bacterial cell surfaces can be isolated and utilized as targeting ligands for delivery vehicles. The studies described in this thesis focus on the development of particulate drug carriers coated with LOS bacterial ligands to enhance the targeting and binding of the carriers to the lung epithelium. Three NTHi clinical isolates were screened to select the strain with the highest ChoP level, and NTHi 3198, an isolate from a patient with chronic obstructive pulmonary disease (COPD), was selected due to its high ChoP activity. LOS from NTHi 3198 was isolated from the bacterial cell membrane, and its activity verified using dot immunoblot and ELISA techniques. Particles (0.2 and 1 µm) composed of polystyrene or poly(lactic-co-glycolic acid) were passively coated with 0.005-50 µg/mL of the isolated LOS 3198 with or without gelatin, coated with gelatin alone, or left uncoated. The LOS coating on the particles was verified using either XPS or ELISA. The association of particles with human bronchial epithelial cells was investigated using two cell culture models, 16HBE14o- and Calu-3, as a function of particle concentration and incubation time. The expression of PAFR on both cells types was confirmed, though the expression of PAFR on 16HBE14o- cells was significantly greater than on Calu-3 cells. Enhancement of 0.2 µm particle-cell association was achieved through coating of the particles with LOS. However, no significant difference in particle-cell association was observed for the 1 µm particles based on particle coating. Control particles of 0.2 µm size, those coated with gelatin (with or without LOS) or uncoated, exhibited low cell binding with a maximum of about 10-18% of cells associated with particles. The ability of the LOS ligand to enhance particle-cell association was coating concentration dependent, with a low coating concentration of LOS having little effect on association, but a concentration 1000-fold higher causing a doubling of the percentage of cells associated with particles at 24 hours. This enhancement was attributed to increased cellular binding of the 0.2 µm particles to the cell surface by confocal microscopy, and was further increased by activating the PAFR prior to incubation with particles. These results suggest the potential application of LOS as a targeting ligand for lung epithelial cells, especially under conditions where PAFR has been activated, such as occurs in lungs infected with Haemophilus influenzae. A significant reduction in particle-cell association was observed when particles were incubated with Calu-3 cells due to the presence of mucus on the cellular surface. This suggests that further optimization of the drug carrier system is needed to efficiently overcome the mucosal fluids.

lipooligosaccharide

lung cells

nanoparticle

pharmacy

pulmonary delivery

targeted delivery

Pharmacy and Pharmaceutical Sciences