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

Discriminative eradication of cancer cells using quantum dots functionalised with peptide-directed delivery of a pro-apoptotic peptide

Swartz, Lauren Taryn

January 2013

>Magister Scientiae - MSc / The therapeutic goal of cancer treatment is to trigger selective cell death in cancer cells. To eliminate cancerous cells effectively, the anti–cancer drugs must be targeted to the affected cells. However, anti–cancer drugs are often distributed non–specifically giving rise to systemic toxicities and other adverse effects. Cancer specific peptides are useful cancer targeting agents that can be used for the targeted delivery of anti-cancer drugs. Several cancer targeting peptides and some of their corresponding protein targets have been identified. Previous work investigated the specific binding of five of these peptides (p.C, p.H, p6.1, Frop-1 and p.L) conjugated to fluorescent nanoparticles (quantum dots) to a panel of human cell lines, which included four cancerous cell lines (Caco-2, HeLa, HT29 and HepG2) and one non-cancerous cell line (KMST-6). Flow cytometry showed that the p.L peptide preferentially bind to HT29 cells; suggesting that the expression levels of the target for the p.L peptide are higher in these cells. The objective of this study was to make use of target specific functionalised quantum dots (QDs) to deliver Second mitochondria-derived activator of caspases/ Direct AIP binding protein with low PI (Smac/DIABLO) to HT29 cells with the aim of enhancing the effects of pro-apoptotic drugs. Smac/DIABLO is a pro-apoptotic peptide that is able to interact with inhibitor of apoptosis proteins (IAPs), thereby inducing pro-apoptotic signalling. Methodology: CdSe/ZnS core-shell QDs were synthesised using the one-pot synthesis method. These QDs were characterised using photoluminescence (PL) spectroscopy, high resolution transmission electron microscopy (HR-TEM) and energy dispersive x-ray spectroscopy (EDS). The CdSe/ZnS core-shell QDs were solubilised with L-cysteine (Cys- QDs). The Cys-QDs were bi-conjugated to the p.L peptide and Smac peptide using 1-ethyl-3- (30-dimethylamino) carbodiimide (EDC) chemistry. Cultured HT29 cells were exposed to the 10 | P a g e QD peptide bi-conjugates and fluorescence microscopy was employed to assess targeting and internalisation. The cytotoxicity of the QD peptide bi-conjugates in combinatorial treatment with ceramide was evaluated using the WST-1 Cell Proliferation assay. A commercially available QD with similar chemistry was used to carry out a comparative study to relate the efficiency of the in-house synthesized QD.

Apoptosis

Bi-conjugation

Cancer specific peptides

EDC

Fluorescence

Nanotechnology

QDs

Smac/Diablo

Selective killing

Targeted delivery

TARGETABLE MULTI-DRUG NANOPARTICLES FOR TREATMENT OF GLIOBLASTOMA WITH NEUROIMAGING ASSESSMENT

Shelby Brentyn Smiley (8786417)

01 May 2020

Glioblastoma (GBM) is a deadly, malignant brain tumor with a poor long-term prognosis. The current median survival is approximately fifteen to seventeen months with the standard of care therapy which includes surgery, radiation, and chemotherapy. An important factor contributing to recurrence of GBM is high resistance of GBM cancer stem cells (CSCs), for which a systematically delivered single drug approach will be unlikely to produce a viable cure. Therefore, multi-drug therapies are needed. Currently, only temozolomide (TMZ), which is a DNA alkylator, affects overall survival in GBM patients. CSCs regenerate rapidly and over-express a methyl transferase which overrides the DNA-alkylating mechanism of TMZ, leading to drug resistance. Idasanutlin (RG7388, R05503781) is a potent, selective MDM2 antagonist that additively kills GBM CSCs when combined with diagnostics in a truly theranostic manner for enhancing personalized medicine against GBM. The goal of this thesis was to develop a multi-drug therapy using mutli-functional nanoparticles (NPs) that preferentially target the GBM CSC subpopulation and provide in vivo preclinical imaging capability. Polymer-micellar NPs composed of poly(styrene-<i>b</i>-ethylene oxide) (PS-<i>b</i>-PEO) and poly(lactic-<i>co</i>-glycolic) acid (PLGA) were developed investigating both single and double emulsion fabrication techniques as well as combinatinos of TMZ and RG7388. The NPs were covalently bound to a 15 base-pair CD133 aptamer in order to target a specific epitope on the CD133 antigen expressed on the surface of GBM CSC subpopulation. For theranostic functionality, the NPs were also labelled with a positron emission tomography (PET) radiotracer, zirconium-89 (⁸⁹Zr). The NPs maintained a small size of less than 100 nm, a relatively neutral charge and exhibited the ability to produce a cytotoxic effect on CSCs. There was a slight increase in killing with the aptamer-bound NPs compared to those without a targeting agent. This work has provided a potentially therapeutic option for GBM specific for CSC targeting and future in vivo biodistribution

Nanoparticles

Cancer Cancers

Targeted Delivery

theranostic delivery

Cancer Stem Cells Cells

Development and evaluation of novel structurally simplified sialyl LewisX mimic-decorated liposomes for targeted drug delivery to E-selectin-expressing endothelial cells. / E-セレクチン発現内皮細胞への標的指向化薬物送達を目的とした新規構造単純化シアリルルイスXミミック修飾リポソームの開発と評価

CHANTARASRIVONG, CHANIKARN

25 March 2019

京都大学 / 0048 / 新制・課程博士 / 博士(薬科学) / 甲第21715号 / 薬科博第106号 / 新制||薬科||11(附属図書館) / 京都大学大学院薬学研究科薬科学専攻 / (主査)教授 山下 富義, 教授 髙倉 喜信, 講師 樋口 ゆり子 / 学位規則第4条第1項該当 / Doctor of Pharmaceutical Sciences / Kyoto University / DFAM

targeted delivery

liposomes

E-selectin

sialyl LewisX mimic

inflamed endothelial cells

anti-angiogenesis

499.3

Receptor-mediated DNA-based therapeutics delivery

Chiu, Shihjiuan

08 November 2005

No description available.

Health Sciences, Pharmacy

Gene delivery

antisense delivery

Her2

Herceptin

Folate

Transferrin

targeted delivery

Development of Nanoparticle Systems for Therapeutic Drug Delivery

Yang, Xiaojuan

11 September 2009

No description available.

Pharmaceuticals

nanoparticle

drug delivery system

TfR-targeted delivery

nucleic acid delivery

chemotherapy drug delivery

CARBONIC ANHYDRASE MODULATORS FOR DETECTION AND TREATMENT OF HUMAN DISEASES

Mondal, Utpal Kumar

January 2019

Carbonic anhydrases (CAs, EC 4.2.1.1) are a class of metalloenzymes that catalyze the hydration of CO2 under physiologic conditions and are involved in many physiological and pathological processes. Modulation of CA activity, particularly CA inhibition is exploited pharmacologically for the treatment of many diseases such as cancer, glaucoma, edemas, mountain sickness. CA activation has been less frequently investigated till recently. Genetic deficiencies of several CA isozymes are reported in the literature and reflect the important role of carbonic anhydrases in human physiology and homeostasis. Activation of CA isozymes in brain have been correlated recently with spatial learning and memory. Based on these premises, activators of CA isozymes have the potential to alleviate mild dementias and to act as potential nootropic agents. In chapter 3, continuing our long-term interests towards the development of potent and selective CAAs, we carried out X-ray crystallographic studies with a small series of pyridinium histamine derivatives, previously developed as CAAs by our group. This study revealed important insights into the binding of this class of activators into the active site of CA II isozyme. A potent pyridinium histamine CAA 25i was successfully crystallized with CA II isozyme and was found to bind into the hydrophobic region of the active site, with two binding conformations being observed. This is one of the very few X-ray crystal structures of a CAA available. Based on the findings of this X-ray crystallographic study and building on our previously developed ethylene bis-imidazole CAAs, we advanced a novel series of lipophilic bis-imidazoles. Enzymatic assays carried out on purified human CA isozymes revealed several low nanomolar potent activators against various brain-relevant CA isozymes. Bis-imidazole 30e was found to be a nanomolar potent activator for CA IV, CA VA and CA IX. Due to their conjugated structure, these CAAs were also fluorescent and therefore were fully characterized in terms of photophysical properties, with several representatives proving to display very good fluorophores. The very good activation profile against several different CA isozymes, along with excellent fluorescence properties recommend these compounds as great molecular tools for elucidation of role of CA isozymes in brain physiology, as well as towards improvement of memory and learning. Focusing on inhibition of CA isozymes, it must be stressed that over the last decade a clear connection had been established between the expression of CA IX and CA XII and cancer. Since cancer is the second most common cause of death in the world, we explored the possibility to kill cancer cells via inhibition of different CA isozymes present in cancer cells. The membrane bound carbonic anhydrase IX (CA IX) isozyme represents a particularly interesting anticancer target as it is significantly overexpressed in many solid tumors as compared to normal tissues. In malign tissues this CA isozyme was found to play important role in pH homeostasis and promotes tumor cell survival, progression and metastasis. Thus, CA IX represents a potential biomarker and an appealing therapeutic target for the detection and treatment of cancer. CA IX can be targeted either through the development of small or large molecular weight, potent, and selective inhibitors or through the development of CA IX targeted drug delivery systems for selective delivery of potent chemotherapeutic agents. Building on these premises, in this dissertation, we also revealed our continuing efforts towards the development of potent and selective CA IX inhibitors along with their translation into the development of CA IX targeted drug delivery systems. In chapter 4, we designed a series of small molecular weight (MW) ureido 1,3,4-thiadiazole sulfonamide derivatives employing the “tail approach”, through the decoration of established sulfonamide CA inhibitor warheads with different tail moieties via ureido linker. The generated CAIs were tested against tumor associated CA IX and CA XII isozymes and off-target cytosolic isozymes CA I and CA II, and were revealed to be moderate to highly selective and nanomolar, even sub-nanomolar, potent CA IX inhibitors. Several potent pan-inhibitors were also identified in this section. We assessed these CAIs for their in vitro cell killing ability using MDA-MB 231 breast cancer cell line expressing CA IX and CA XII. The most efficient CAI proved to be ureido-1,3,4-thiadiazole-2-sulfonamide 69, which showed subnanomolar potency against purified human CA IX and CA XII isozymes, with good selectivity against CA I and CA II, and consistent, statistically significant cancer cell killing. In Chapter 5, continuing our efforts towards the development of potent and selective CA IX inhibitors, we designed, synthesized, characterized and evaluated a new series of PEGylated 1,3,4-thiadiazole-2-sulfonamide CAIs, bearing different PEG backbone length. We increased the PEG size from 1K to 20K, in order to better understand the impact of the PEG linker length on the in vitro cell killing ability against CA IX expressing cancer cell lines and also against a CA IX negative cell line. In vitro cell viability assays revealed the optimum PEG linker length for this type of bifunctional bis-sulfonamide CAIs in killing the tumor cells. The most efficient PEGylated CAI was found to bis-sulfonamide DTP1K 91, which showed consistent and significant cancer cell killing at concentrations of 10−100 μM across different CA IX and CA XII expressing cancer cell lines. DTP1K 91 did not affect the cell viability of CA IX negative NCI-H23 tumor cells, thus revealing a CA IX mediated cell killing for these inhibitors. In chapter 6, we decided to further explore the possibility of using CA IX as a targeting epitome for the development of a gold nanoparticle-based drug delivery system. We translated the oligoEG- and PEGylated CAI conjugates into efficient targeting ligands for gold nanoparticle decoration along with chemotherapeutic agent doxorubicin (Dox), in a novel multi-ligand gold nanoplatform designed to selectively release the drug intracellularly, in order to enhance the selective tumor drug uptake and tumor killing. We were successful in developing compatible CAI- and Dox- ligands for efficient dual functionalization of gold nanoparticles. Our optimized, CA IX targeted gold nanoplatform was found to be very efficient towards killing HT-29 tumor cells especially under hypoxic conditions, reducing the hypoxia-induced chemoresistance, thus confirmed the potentiating role of CA IX as a targeting epitome. / Pharmaceutical Sciences

Pharmaceutical Sciences

Ca Activators

Ca Inhibitors

Ca Ix Selective

Cancer

Carbonic Anhydrases

Targeted Delivery

Controlled Trans-lymphatic Delivery of Chemotherapy for the Treatment of Lymphatic Metastasis in Lung Cancer

Liu, Jiang

28 July 2008

Lymph node metastasis is a critical prognostic factor for lung cancer. Effective therapy to control lymphatic metastasis may improve survival. The work described in this thesis focuses on the development of a microparticulate lymphatic targeting system, which can be applied as an adjuvant therapy in the control of lymphatic metastasis in lung cancer. The study shows that intrapleural administered colloidal particulates are predominantly taken up by regional lymphatic tissue in rat models including healthy rats, rats bearing orthotopic lung tumours and rats following pneumonectomy. The effect of particle size on lymphatic particle distribution was examined by intrapleural administration of 111In-aminopolystyrene beads. Approximately 2 µm is a suitable size for intrapleural lymphatic targeting. Biodegradable polylactide-co-glycolide (PLGA) microparticles containing the anticancer agent paclitaxel (PTX) were subsequently formulated in the desired size by spray drying. PLGA-PTX microspheres were incorporated into a biodegradable and biocompatible gelatin sponge matrix to form an implantable lymphatic targeted drug delivery system. The system was characterized in vitro and its lymphatic targeting ability was examined in vivo. Fluorescence labeled microspheres embedded within the sponge were selectively taken up by regional lymphatics as the sponge matrix disintegrated following intrapleural implantation. A pharmacokinetic study showed that the total PTX exposure in lymphatic tissue was dramatically higher than that achieved through intravenous administration. The peak plasma drug concentration, which governs systemic toxicity, was significantly reduced. The low but persistent detection of plasma PTX indicates that PTX was control released from the system after intrapleural implantation. In a therapeutic efficacy study performed in the H460 orthotopic lung cancer model, gelatin sponges containing PLGA-PTX microspheres were placed in the pleural cavity as an adjuvant treatment after surgical resection of the primary lung tumour. Trans-lymphatic chemotherapy resulted in a significantly lower incidence of lymphatic tumour recurrence (20%) compared to no treatment and placebo control animals (100%). PLGA-PTX microspheres were seen in regional lymphatic tissue over 4 weeks after the sponge placement. It is concluded that the trans-lymphatic targeting drug delivery system described in this thesis may improve the control of lymphatic metastasis in lung cancer.

trans-lymphatic

chemotherapy

targeted delivery

lung cancer

metastasis

lymph node

polymeric microparticulate

biodegradable gelatin sponge

paclitaxel

PLGA

Controlled Trans-lymphatic Delivery of Chemotherapy for the Treatment of Lymphatic Metastasis in Lung Cancer

Liu, Jiang

28 July 2008

Lymph node metastasis is a critical prognostic factor for lung cancer. Effective therapy to control lymphatic metastasis may improve survival. The work described in this thesis focuses on the development of a microparticulate lymphatic targeting system, which can be applied as an adjuvant therapy in the control of lymphatic metastasis in lung cancer. The study shows that intrapleural administered colloidal particulates are predominantly taken up by regional lymphatic tissue in rat models including healthy rats, rats bearing orthotopic lung tumours and rats following pneumonectomy. The effect of particle size on lymphatic particle distribution was examined by intrapleural administration of 111In-aminopolystyrene beads. Approximately 2 µm is a suitable size for intrapleural lymphatic targeting. Biodegradable polylactide-co-glycolide (PLGA) microparticles containing the anticancer agent paclitaxel (PTX) were subsequently formulated in the desired size by spray drying. PLGA-PTX microspheres were incorporated into a biodegradable and biocompatible gelatin sponge matrix to form an implantable lymphatic targeted drug delivery system. The system was characterized in vitro and its lymphatic targeting ability was examined in vivo. Fluorescence labeled microspheres embedded within the sponge were selectively taken up by regional lymphatics as the sponge matrix disintegrated following intrapleural implantation. A pharmacokinetic study showed that the total PTX exposure in lymphatic tissue was dramatically higher than that achieved through intravenous administration. The peak plasma drug concentration, which governs systemic toxicity, was significantly reduced. The low but persistent detection of plasma PTX indicates that PTX was control released from the system after intrapleural implantation. In a therapeutic efficacy study performed in the H460 orthotopic lung cancer model, gelatin sponges containing PLGA-PTX microspheres were placed in the pleural cavity as an adjuvant treatment after surgical resection of the primary lung tumour. Trans-lymphatic chemotherapy resulted in a significantly lower incidence of lymphatic tumour recurrence (20%) compared to no treatment and placebo control animals (100%). PLGA-PTX microspheres were seen in regional lymphatic tissue over 4 weeks after the sponge placement. It is concluded that the trans-lymphatic targeting drug delivery system described in this thesis may improve the control of lymphatic metastasis in lung cancer.

trans-lymphatic

chemotherapy

targeted delivery

lung cancer

metastasis

lymph node

polymeric microparticulate

biodegradable gelatin sponge

paclitaxel

PLGA

Development and Intratumoral Distribution of Block Copolymer Micelles as Nanomedicines for the Targeted Delivery of Chemotherapy to Solid Tumors

Mikhail, Andrew

20 June 2014

Recent advancements in pharmaceutical technology based on principles of nanotechnology, polymer chemistry, and biomedical engineering have resulted in the creation of novel drug delivery systems with the potential to revolutionize current strategies in cancer chemotherapy. In oncology, realization of significant improvements in therapeutic efficacy requires minimization of drug exposure to healthy tissues and concentration of the drug within the tumor. As such, encapsulation of chemotherapeutic agents inside nanoparticles capable of enhancing tumor-targeted drug delivery is a particularly promising innovation. Yet, initial investigations into the intratumoral fate of nanomedicines have suggested that they may be heterogeneously distributed and achieve limited access to cancer cells located distant from the tumor vasculature. As such, uncovering the determinants of nanoparticle transport at the intratumoral level is critical to the development of optimized delivery vehicles capable of fully exploiting the therapeutic potential of nanomedicines. In this work, the chemotherapeutic agent, docetaxel (DTX), was incorporated into nano-sized, biocompatible PEG-b-PCL block copolymer micelles (BCMs). Encapsulation of DTX in micelles via chemical conjugation or physical entrapment resulted in a dramatic increase in drug solubility and customizable drug release rate. The use of multicellular tumor spheroids (MCTS) was established as a viable platform for assessing the efficacy and tumor tissue penetration of nanomedicines in vitro. A series of complementary assays was validated for analysis of DTX-loaded micelle (BCM+DTX) toxicity in monolayer and spheroid cultures relative to Taxotere®. Cells cultured as spheroids were less responsive to treatment relative to monolayer cultures due to mechanisms of drug resistance associated with structural and microenvironmental properties of the 3-D tissue. Computational, image-based methodologies were used to assess the spatial and temporal penetration of BCMs in spheroids and corresponding human tumor xenografts. Using this approach, the tumor penetration of micelles was found to be nanoparticle-size-, tumor tissue type- and time- dependent. Furthermore, spheroids were found to be a valuable platform for the prediction of trends in nanoparticle transport in vivo. Overall, the results reported herein serve to demonstrate important determinants of nanoparticle intratumoral transport and to establish computational in vitro and in vivo methodologies for the rational design and optimization of nanomedicines.

cancer

nanoparticle

nanomedicine

block copolymer micelle

chemotherapy

biomaterials

tumor

tumor penetration

tumor distribution

docetaxel

Taxotere

targeted delivery

0572

0541