Assembly of Phi29 pRNA Nanoparticles for Gene or Drug Delivery and for Application in Nanotechnology and Nanomedicine

Shu, Yi

26 October 2012

No description available.

Biomedical Research

Bacteriophage phi29

pRNA nanoparticles

bottom-up assembly

RNAi

RNA nanotechnology

nanomedicine

Examining Stability in Self-Assembled Systems for Biological Applications

Fry, Cathleen Marie

05 October 2022

No description available.

Chemistry

camptothecin

fluorouracil

drug delivery

dual drug delivery

nanomedicine

enzyme immobilization

rubisco

DEVELOPMENT AND CHARACTERIZATION OF POLYMER-OIL NANOSTRUCTURED CARRIER (PONC) FOR CONTROLLED DELIVERY OF ALL-TRANS RETINOIC ACID (ATRA)

Narvekar, Mayuri

January 2014

The commonly used PLGA-based delivery systems are often limited by their inadequate drug loading and release properties. This study reports the integration of oil into PLGA to form the prototype of a hybrid drug carrier PONC. Our primary goal is to confer the key strength of lipid-based drug carriers, i.e. efficient encapsulation of lipophilic compounds, to a PLGA system without taking away its various useful qualities. The PONC were formulated by emulsification solvent evaporation technique, which were then characterized for particle size, encapsulation efficiency, drug release and anticancer efficacy. The ATRA loaded PONC showed excellent encapsulation efficiency and release kinetics. Even after surface functionalization with PEG , controlled drug release kinetics was maintained, with 88.5% of the encapsulated ATRA released from the PEG-PONC in a uniform manner over 120 hours. It also showed favorable physicochemical properties and serum stability. PEG-PONC has demonstrated substantially superior activity over the free ATRA in ovarian cancer cells that are non-responsive to the standard chemotherapy. The newly developed PEG-PONC significantly reduced the IC50 values (p<0.05) in the chemoresistant cells in both MTT and colony formation assays. Hence, this new ATRA-nanoformulation may offer promising means for the delivery of lipophilic compounds like all-trans retinoic acid to treat highly resistant ovarian cancer. / Pharmaceutical Sciences

Pharmaceutical Sciences

Nanotechnology

All-trans Retinoic Acid

Controlled Drug Delivery

Nanomedicine

Plga

Poorly Water Soluble Drugs

Developing Photo-responsive Metal-Organic Frameworks towards Controlled Drug Delivery

Epley, Charity Cherie

14 July 2017

The development of therapeutic drugs or drug systems that enhance a cancer patient's quality of life during treatment is a primary goal for many researchers across a wide range of disciplines. Many investigators turn to nanoparticles (~50-200 nm in size) that tend to accumulate in tumor tissues in order to deliver active drug compounds to specific sites in the body. This targeted delivery approach would reduce the total body effects of current cancer drugs that result in unwanted (sometimes painful and even fatal) side effects. One of the main obstacles however, is ensuring that drugs incorporated into the nanoparticles are anchored such that premature drug release is prohibited. Also, while it is important to ensure strong drug-nanocarrier interactions, the nanocarrier must be able to release the drug when it has reached its biological target. We have developed a nanocarrier that provides a platform for drug systems that could achieve this drug release via the use of a light "trigger". Metal-Organic Frameworks (MOFs) are a relatively new class of often highly porous materials that act as "sponges" for the absorption of various small molecules. MOFs are so named because they consist of metal clusters that are linked by organic compounds to form networked solids that are easily tuned based on the choice of metal and organic "linker". We have developed a MOF nanocarrier incorporating benign zirconium (IV) metal clusters bridged by an organic component that changes shape when illuminated with a light source. The resulting material is therefore not stable upon irradiation due to the organic linker shape change that disturbs the MOF structure and causes it to degrade. When loaded with drugs, this photo-enhanced degradation results in the release of the cargo thereby, providing a handle on controlling drug release with the use of a light trigger. We have demonstrated that in the presence of the MOF nanocarrier incorporating 5-fluorouracil (a clinically available cancer drug), very low toxicity to human breast cancer cells is observed in the dark, however, cell death occurs in the presence of a light source. These reports offer a model MOF nanocarrier system that could be used to incorporate various drugs and therefore tune the system to an individual patient's needs. Furthermore, we also developed a material that is capable of providing magnetic resonance imaging (MRI) contrast by changing the metal to manganese (II). MRI contrast agents are compounds that serve to either darken or brighten an MRI image based on the agent used and therefore they aid in clinical diagnosis by making internal abnormalities easier to spot. Currently gadolinium (III) complexes are the most widely used contrast agents; however, the toxicity of gadolinium (III) has been shown to be responsible for the development of nephrogenic systemic fibrosis in some patients. This manganese material has also shown useful for the attachment of fluorescent dyes that can aid in the benchtop optical diagnosis of biopsies. These reports provide a basis for developing ways to offer controlled drug delivery in cancer patients and to aid in cancer diagnosis using MOF materials, in an effort to reach the goals of comfortable cancer treatment. / Ph. D.

metal-organic frameworks

nanocarriers

photodynamic therapy

theranostics

nanomedicine

drug delivery

post-synthetic modification

contrast agents

Engineering a versatile dendrimer-based nanomedicine platform for the development of advanced drug delivery for inflammation and pain

Bhansali, Divya

January 2024

This thesis presents the design and optimization of a dendrimer-based cationic nanoparticle system tailored for versatile applications, ranging from anti-inflammatory scavenging to targeted pain relief through endosomal delivery. By harnessing the unique attributes of this platform, various strategies were devised to overcome hurdles in drug delivery, offering promising avenues for nanomedicine in anti-inflammatory and nociceptive treatments. In our scavenging screening project, we rigorously screened various materials to find the best universal anti-inflammatory carrier. We started by exploring the potential of dendrimer-based materials as scavengers of inflammatory signals and studied how they could be used to develop therapeutic carriers. With intrinsic therapeutic properties and the ability to create tunable nanocarriers, dendrimer-based delivery systems are powerful multimodal delivery systems. The dendrimer base of our delivery system, cationic PAMAM Generation 3 dendrimer (PAMAM-G3), was selected due to its efficient scavenging ability and low biotoxicity. Conjugation with cholesterol facilitated the formation of polymeric micelles, exhibiting a cationic and hydrophilic exterior coupled with a hydrophobic interior, resulting in a high drug-loading capacity. Among the developed scavengers, PAMAM-Cholesterol (PAMAM-Chol) nanoparticles demonstrated a potent reduction in toll-like receptor activation with minimal toxicity and extended endosomal retention. We then exploited the endosomal retention of PAMAM-Chol nanoparticles to target the activated PAR2 receptor within endosomes of relevant cancer cells, aiming to alleviate oral cancer-induced nociception. Extensive characterization confirmed the platform's stability, physical attributes, and ability to encapsulate PAR2 inhibitor, AZ3451. The platform exhibited high drug loading capacity and sustained release profiles across various pHs. Cellular uptake studies demonstrated efficient endosomal targeting, with subsequent modulation of PAR2 signaling pathways. Preclinical studies in oral cancer pain models revealed a significant and prolonged reduction in nociception for over 24 hours, surpassing the efficacy of free drugs. Further diversification of the PAMAM-Chol platform explored its potential as a "Push" chemotherapy carrier and a "Pull" cfDNA scavenger against chemotherapy-induced neurological and neuropathic side effects. Evaluation in wild-type mice demonstrated the platform's effectiveness in mitigating chemobrain and chemotherapy-induced peripheral neuropathy, highlighting its translational potential for multimodal cancer therapy. We found that NPs loaded with chemotherapy significantly reduced the painful effects of chemotherapy-induced peripheral neuropathy and decreased recovery times. Collectively, this body of work underscores the potential of PAMAM-Chol as a versatile tool in drug delivery and endosome-localized pain therapeutics. It contributes to the evolving landscape of precision medicine through tailored therapeutic approaches for minimizing side effects and enhancing patient well-being. The innate therapeutic properties coupled with efficient and sustained drug delivery mechanisms position the PAMAM-Chol platform as a foundational element for the development and delivery of next-generation therapeutics.

Biomedical engineering

Dendrimers in medicine

Nanomedicine

Nanoparticles

Drug delivery systems

Anti-inflammatory agents

Analgesics

Chemotherapy

Chemistry, photophysics, and biomedical applications of gold nanotechnologies

Dreaden, Erik Christopher

04 June 2012

Gold nanoparticles exhibit a combination of physical, chemical, optical, and electronic properties unique from all other nanotechnologies. These structures can provide a highly multifunctional platform with which to diagnose and treat diseases and can dramatically enhance a variety of photonic and electronic processes and devices. The work herein highlights some newly emerging applications of these phenomena as they relate to the targeted diagnosis and treatment of cancer, improved charge carrier generation in photovoltaic device materials, and strategies for enhanced spectrochemical analysis and detection. Chapter 1 introduces the reader to the design, synthesis, and molecular functionalization of gold nanotechnologies, and provides a framework from which to discuss the unique photophysical properties and applications of these nanoscale materials and their physiological interactions in Chapter 2. Chapter 3 discusses ongoing preclinical research in our lab investigating the use of near-infrared absorbing gold nanorods as photothermal contrast agents for laser ablation therapy of solid tumors. In Chapter 4, we present recent work developing a novel strategy for the targeted treatment of hormone-dependent breast and prostate tumors using multivalent gold nanoparticles that function as highly selective and potent endocrine receptor antagonist chemotherapeutics. In Chapter 5, we discuss a newly-emerging tumor-targeting strategy for nanoscale drug carriers which relies on their selective delivery to immune cells that exhibit high accumulation and infiltration into breast and brain tumors. Using this platform, we further investigate the interactions of nanoscale drug carriers and imaging agents to a transmembrane protein considered to be the single most prevalent and single most important contributor to drug resistance and the failure of chemotherapy. Chapter 6 presents work from a series of studies exploring enhanced charge carrier generation and relaxation in a hybrid electronic system exhibiting resonant interactions between photovoltaic device materials and plasmonic gold nanoparticles. Chapter 7 concludes by presenting studies investigating the contributions from so-called “dark” plasmon modes to the spectrochemical diagnostic method known as surface enhanced Raman scattering.

Multidrug resistance

Exciton

Semiconductor

Computational electrodynamics

Lithography

Antiestrogen

Colloid chemistry

Pharmacokinetics

Pharmaceuticals

Plasmon resonance

Macrophage

Spectroscopy

Hormone therapy

GPRC6A

Bioconjugation

Photothermal therapy

Laser

Pharmacodynamics

SPR

Nanoscience

Ultrafast

Antiandrogen

Plasmonics

SERS

Nanomedicine

Drug delivery

EPR

Au

Nanoparticles

Nanomedicine

Cancer

Gold

A model for homeopathic remedy effects: low dose nanoparticles, allostatic cross-adaptation, and time-dependent sensitization in a complex adaptive system

Bell, Iris, Koithan, Mary

January 2012

BACKGROUND:This paper proposes a novel model for homeopathic remedy action on living systems. Research indicates that homeopathic remedies (a) contain measurable source and silica nanoparticles heterogeneously dispersed in colloidal solution / (b) act by modulating biological function of the allostatic stress response network (c) evoke biphasic actions on living systems via organism-dependent adaptive and endogenously amplified effects / (d) improve systemic resilience.DISCUSSION:The proposed active components of homeopathic remedies are nanoparticles of source substance in water-based colloidal solution, not bulk-form drugs. Nanoparticles have unique biological and physico-chemical properties, including increased catalytic reactivity, protein and DNA adsorption, bioavailability, dose-sparing, electromagnetic, and quantum effects different from bulk-form materials. Trituration and/or liquid succussions during classical remedy preparation create "top-down" nanostructures. Plants can biosynthesize remedy-templated silica nanostructures. Nanoparticles stimulate hormesis, a beneficial low-dose adaptive response. Homeopathic remedies prescribed in low doses spaced intermittently over time act as biological signals that stimulate the organism's allostatic biological stress response network, evoking nonlinear modulatory, self-organizing change. Potential mechanisms include time-dependent sensitization (TDS), a type of adaptive plasticity/metaplasticity involving progressive amplification of host responses, which reverse direction and oscillate at physiological limits. To mobilize hormesis and TDS, the remedy must be appraised as a salient, but low level, novel threat, stressor, or homeostatic disruption for the whole organism. Silica nanoparticles adsorb remedy source and amplify effects. Properly-timed remedy dosing elicits disease-primed compensatory reversal in direction of maladaptive dynamics of the allostatic network, thus promoting resilience and recovery from disease.SUMMARY:Homeopathic remedies are proposed as source nanoparticles that mobilize hormesis and time-dependent sensitization via non-pharmacological effects on specific biological adaptive and amplification mechanisms. The nanoparticle nature of remedies would distinguish them from conventional bulk drugs in structure, morphology, and functional properties. Outcomes would depend upon the ability of the organism to respond to the remedy as a novel stressor or heterotypic biological threat, initiating reversals of cumulative, cross-adapted biological maladaptations underlying disease in the allostatic stress response network. Systemic resilience would improve. This model provides a foundation for theory-driven research on the role of nanomaterials in living systems, mechanisms of homeopathic remedy actions and translational uses in nanomedicine.

Homeopathy

Nanoparticles

Silica

Epitaxy

Hormesis

Cross adaptation

Time dependent sensitization

Metaplasticity

Allostasis

Complex adaptive system

Stress response network

Resilience

Nanomedicine

Interactions of nanoparticles with cells for nanomedical applications

Stevenson, Amadeus

January 2014

Nanotechnology is a rapidly growing field focused on the manipulation and control of materials with dimensions under 100 nm. The novel electronic, optical and mechanical properties observed at the nanoscale have resulted in a number of applications in catalysis, light emitting devices, solar power, self-cleaning surfaces and medicine. Medical applications of nanotechnology (“nanomedicine”) are particularly promising for rapid clinical diagnosis and targeted treatments. Understanding the interactions of nanoparticles with living matter is of fundamental importance for all application areas: manufacture, use and disposal of the growing number of nanoproducts will result in increased environmental exposure in addition to direct exposure through nanomedical applications. However, there is a lack of standard methodologies for assessing these interactions. In this work the stability of silver-based nanoparticles was established by UV- Visible (UV-Vis) spectroscopy, atomic force microscopy (AFM) and transmission electron microscopy (TEM). The presence of a higher valence metal or polymer on the nanoparticle surface was demonstrated to improve stability. A standard methodology was developed to study nanoparticle-cell interactions: an “atlas” of the effects of known drugs on a cell is created, and compared with the effects of a nanoparticle. Escherichia coli was selected as a model organism and the effects of a range of antibiotics were characterised through a combination of microbiological assays and AFM. Susceptibility, population cell growth and individual heights, widths, lengths and volumes of bacteria were obtained on a 2% agarose substrate in air. The methodology was applied and adjusted for silver nanoparticles due to the interactions of silver with the bacterial growth medium. 10 and 30 nm silver nanoparticles and ions were found to kill E. coli through an internal mechanism of action, with a size-specific effect on the height of bacteria. Finally, a novel AFM characterisation method is described to examine the mechanical properties of live bacterial and human cells in liquid.

620.5

Estudo da imobilização do receptor tireoidiano humano TRβ1 em filmes finos nanoestruturados e aplicações em detecção de hormônios tireoidianos / Immobilization and sensing ability of human thyroid nuclear receptor in nanostructured thin films

Bendo, Luana

07 June 2010

A manipulação de materiais em escala nanométrica representa uma das fronteiras em nanociência e nanotecnologia, devido à possibilidade de controle de propriedades específicas do material. No caso de materiais biológicos, em particular, a manipulação e imobilização na forma de filmes ou camadas ultrafinas é crucial para seu emprego em dispositivos biotecnológicos. Neste trabalho, objetivou-se o estudo de detecção de diferentes hormônios tireoidianos (HTs) e análogos a partir da imobilização da região LBD do receptor de hormônio tireoidiano humano TRTRβ1 em um eletrodo interdigitado, para o desenvolvimento de um biossensor capacitivo. Este sistema consiste em um arranjo estrutural na forma de filme fino capaz de distinguir a interação específica receptor-ligante de outras interações possivelmente interferentes, visando a quantificação dos níveis de HTs. Para isto, a técnica de SAMs (Self-Assembled Monolayers) foi empregada, por permitir um alto controle da espessura e ordenamento molecular dos filmes, assim como a preservação das atividades das biomoléculas. Análises espectroscópicas e morfológicas foram realizadas para o estudo de adsorção das biomoléculas no filme. As interações específicas receptor-ligante foram avaliadas por meio de respostas elétricas (impedância) do biossensor contendo o TRβ1-LBD imobilizado em um filme orgânico ultrafino, e também por SPR (Surface Plasmon Resonance). Os resultados mostraram a capacidade dos eletrodos contendo TRTRβ1-LBD de detectar e diferenciar entre diferentes HTs em concentrações da ordem de nanomolar, compatível com níveis fisiológicos, evidenciando o grande potencial de aplicação para este sistema no diagnóstico e tratamento de disfunções tireoidianas. / Manipulation of materials at the nanoscale represents one of the frontiers in nanoscience and nanotechnology, mainly due to the possibility of specific controlling, improved properties, not observed if conventional bulk processing is applied. For biomolecules, in particular, processing via immobilization in the form of nanostructured films has allowed their use in biotechnological applications and devices. In this master dissertation, we aimed at investigating the immobilization of the LBD domain of human thyroid hormone receptor TRTRβ1 on interdigitated electrodes, to be used as capacitive biosensors for thyroid hormones (THs) and analogues detection. The nuclear receptors were immobilized via SAMs (Self-Assembled Monolayers), since this technique allows a high control of molecular order and thickness of the films, as well as the preservation of biological activities. Spectroscopic and morphological analyses were performed to investigate the adsorption of biomolecules on the nanostructured film. The interactions between receptor - ligand were also evaluated by means of electrical response (impedance) and SPR (Surface Plasmon Resonance). The bioelectrodes containing immobilized TRTRβ1 were capable of detecting and distinguishing among different HTs, including T3, T4, TRIAC and GC-1 at concentrations down to nanomolar, compatible with physiological levels. The latter results point to the possibility of applications of the bioelectrodes in the diagnosis and treatment of thyroid dysfunctions.

Biosensor

Biossensor

Hormônios tireoidianos

Human thyroid nuclear receptor

Imobilização

Nanomedicina

Nanomedicine

Protein immobilization

Receptor nuclear tireoidiano humano

Thyroid hormones

Hydrogel de nanocapsules lipidiques chargées en lauroyl-gemcitabine pour le traitement local du glioblastome / Lauroyl-gemcitabine lipid nanocapsule hydrogel for the local treatment of glioblastoma

Bastiancich, Chiara

12 April 2018

Le glioblastome (GBM) est une tumeur maligne du cerveau très agressive et actuellement incurable. Après le traitement standard, le GBM récidive toujours à cause de son caractère invasif et de sa résistance aux agents chimiothérapeutiques alkylants. Dans cette thèse, nous avons évalué la faisabilité, l'efficacité et la tolérance de l’hydrogel « nanocapsules lipidiques chargées en Lauroyl-gemcitabine » (GemC12-LNC) pour le traitement local du GBM. GemC12-LNC a été préparé par un procédé d'inversion de phase. Il est injectable, adapté à l'implantation cérébrale et capable de libérer de façon prolongée le médicament in vitro. Chez les souris saines, aucune inflammation, apoptose ou activation de la microglie n’a été observée après exposition à l'hydrogel, ce qui suggère que ce système est bien toléré. L'injection intra-tumorale de GemC12-LNC dans un modèle de GBM U87 sous-cutané et orthotopique a réduit de façon significative la croissance tumorale et a augmenté la survie médiane de l'animal par rapport aux contrôles, respectivement. De plus, en vue d’une meilleure relevance clinique, une technique de résection tumorale reproductible du GBM U87 et du gliosarcome 9L a été mise au point et l'hydrogel GemC12-LNC a réduit les récidives chez les souris et les rats, respectivement. En conclusion, l'efficacité et la tolérance de l’hydrogel GemC12-LNC ont été démontrées in vitro et in vivo. Cette formulation simple peut être injectée directement dans la cavité de résection du GBM, et combine les propriétés avantageuses des nanomédecines et des hydrogels. GemC12-LNC peut donc être considéré comme un système d'administration prometteur et innovant pour le traitement local du GBM. / Glioblastoma (GBM) is an aggressive malignant brain tumor characterized by rapid proliferation and propensity to infiltrate healthy brain tissue. Despite aggressive standard of care therapy GBM always recur, mainly because of its high invasiveness and chemoresistance to alkylating drugs. In this Thesis, we evaluate the feasibility, efficacy and safety of the nanomedicine hydrogel Lauroyl-gemcitabine lipid nanocapsule (GemC12-LNC) for the local treatment of GBM. GemC12-LNC was prepared by a phase-inversion technique process. It is injectable, adapted for brain implantation and able to sustainably release the drug in vitro. In healthy mice brain, no inflammation, apoptosis or microglia activation was observed after exposure to the hydrogel suggesting that this system is well tolerated and suitable for an application in the brain. Intratumoral injection of GemC12-LNC hydrogel in a U87subcutaneous and orthotopic GBM model significantly reduced tumor growth and increased the animal’s median survival compared to the controls, respectively. Moreover, to mimic the clinical setting, a reproducible tumor resection technique of U87 GBM and 9L gliosarcoma was developed and the GemC12-LNC hydrogel slowed down the formation of recurrences in mice and rats brain, respectively. In conclusion, the feasibility efficacy and safety of GemC12-LNC have been shown in vitro and in several preclinical in vivo models showing that this nanomedicine hydrogel is a promising and innovative delivery system for the local treatment of GBM. This gel can be directly injected in the GBM resection cavity, has a very simple formulation and combines the properties of nanomedicines and hydrogels.

Glioblastome

Délivrance locale des médicaments

Nanomédicine

Hydrogels

Modèles précliniques

Glioblastoma

Local delivery

Nanomedicine

Hydrogels

Preclinical models

616.994

615.58