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Understanding the role of colon-specific microparticles based on retrograded starch/pectin in the delivery of chitosan nanoparticles along the gastrointestinal tract


Journal Article
Dos Santos, A. M. and Meneguin, A. B. and Akhter, D. T. and Fletcher, N. and Houston, Z. H. and Bell, C. and Thurecht, K. J. and Gremiao, M. P. D.
1. Dos Santos, A. M.; Meneguin, A. B.; Akhter, D. T.; Fletcher, N.; Houston, Z. H.; Bell, C.; Thurecht, K. J.; Gremiao, M. P. D., Understanding the role of colon-specific microparticles based on retrograded starch/pectin in the delivery of chitosan nanoparticles along the gastrointestinal tract. Eur J Pharm Biopharm 2021, 158, 371-378.
Publication year: 2021

The encapsulation of nanoparticles within microparticles designed for specific delivery to the colon is a relevant strategy to avoid premature degradation or release of nanoparticles during their passage through the stomach and upper gastrointestinal tract (GIT), allowing the targeted delivery of chemotherapeutics to the colon after oral administration. Here, we designed an oral multiparticulate system to achieve targeted release in the colon. In this sense, chitosan nanoparticles (CS NPs) encapsulated with 5-fluorouracil (5-FU) and incorporated into retrograded starch and pectin (RS/P) microparticles were developed and their in vivo distribution along the mouse GIT after oral administration was monitored using multispectral optical imaging. In vitro release studies revealed that the encapsulation of CS NPs into RS/P microparticles promoted greater control of 5-FU release rates, with a significant reduction (53%) in acid media that might replicate that found in the stomach following oral administration. The evaluation of the in vivo biodistribution of the CS NPs in mice showed a faster clearance in the distribution pattern along the mouse GIT, i.e., a shorter transit time of CS NPs compared to CS NPs-loaded RS/P microparticles. Additionally, CS NPs alone showed non-specific absorption into the blood-stream with associated kidney accumulation, while for the CS NPs-loaded RS/P microparticles no significant accumulation was observed in blood or major clearance organs. This suggests the specific degradability of RS/P by the colon microbiota appears to have been decisive in the higher protection of the CS NPs along the GIT until release in the colon, preventing unwanted absorption into the bloodstream and major organs following oral administration. Our findings represent a proof of concept for the use of RS/P microparticles as potential carriers for delivering drug-loaded nanoparticles to the colon and this work will contribute to the development of oral-systems for colorectal cancer therapy.

Poly(2-ethyl-2-oxazoline) bottlebrushes: How nanomaterial dimensions can influence biological interactions


Journal Article
Pizzi, David and Mahmoud, Ayaat M. and Klein, Tobias and Morrow, Joshua P. and Humphries, James and Houston, Zachary H. and Fletcher, Nicholas L. and Bell, Craig A. and Thurecht, Kristofer J. and Kempe, Kristian
Pizzi, D.; Mahmoud, A. M.; Klein, T.; Morrow, J. P.; Humphries, J.; Houston, Z. H.; Fletcher, N. L.; Bell, C. A.; Thurecht, K. J.; Kempe, K., Poly(2-ethyl-2-oxazoline) bottlebrushes: How nanomaterial dimensions can influence biological interactions. European Polymer Journal 2021, 151.
Publication year: 2021

Biocompatible polymers are crucial components of successful nano-sized carriers, which enable the delivery of otherwise largely ineffective therapeutics. Poly(2-ethyl-2-oxazoline) (PEtOx) is one polymer that has shown potential for this application due to its demonstrated low fouling nature and biocompatibility comparable to the current gold standard carrier, poly(ethylene glycol). PEtOx based bottlebrushes, in particular, are promising therapeutic carriers due to their anisotropic nature, which can be easily fine-tuned. Despite this potential, little is known about the interaction of PEtOx bottlebrushes with biological systems. The present study provides a detailed insight into the cellular interactions and biodistribution of PEtOx bottlebrushes in a mouse model. Three PEtOx bottlebrushes of varied side-chain and backbone lengths were designed to highlight the effect that the degree of polymerisation (DP) of each aspect may have on both cellular interaction and biodistribution. Herein we show that PEtOx bottlebrushes display no adverse effects to either cells or mice over 48 h at doses that would be relevant to drug delivery applications. Furthermore, increasing either the backbone or side-chain length of PEtOx bottlebrushes leads to a reduction in cellular association in vitro and an increase in blood circulation times in vivo. The fact that small changes to the dimensions of the PEtOx bottlebrushes have a marked effect on biodistribution and blood circulation times may prove to be a highly beneficial insight for the design of next-generation PEtOx bottlebrushes nanocarriers with tailor-made profiles dependent on the application required.

Evaluation of the in vivo fate of ultrapure alginate in a BALB/c mouse model


Journal Article
A, A. and Fletcher, N. L. and Houston, Z. H. and Thurecht, K. J. and Grondahl, L.
1. A, A.; Fletcher, N. L.; Houston, Z. H.; Thurecht, K. J.; Grondahl, L., Evaluation of the in vivo fate of ultrapure alginate in a BALB/c mouse model. Carbohydr Polym 2021, 262, 117947.
Publication year: 2021

The linear anionic polysaccharide alginate (ALG) has been comprehensively studied for biomedical applications, yet thus far the in vivo fate of this polymer has not been explored in detail. The current study therefore evaluates the biodistribution of ultrapure ALG (M/G ratio >/= 0.67 with a measured Mw of 530 kg/mol and polydispersity index; PDI of 1.49) over a 14-day period in BALB/c mice. The biodistribution pattern over 2-days after sample administration using PET imaging with (64)Cu-labelled ALG showed liver and spleen uptake. This was confirmed by the 14-day biodistribution profile of cyanine 5-labelled ALG from in vivo and ex vivo fluorescence imaging. Using MacGreen mice confirmed the uptake of the ALG by macrophages in the spleen at the 2-day time point. This extended biodistribution study confirmed the clearance of only a portion of the administered ALG biopolymer, but also uptake by macrophage populations in the spleen over a 14-day period.

Clinical translation of theranostic nanomedicines for the treatment of recurrent glioblastoma

Invited Presentations
Zachary H. Houston
Publication year: 2021

(Invited Talk) ACRF Image X Institute, The University of Sydney – 29th of June, 2021

In the not too distant future, a novel personalised medicine using nanomedicines will enter the clinical study in patients with glioblastoma. In this presentation I will discuss the steps we have made in nanomaterial development, personalised antibody targeting, comparative oncology, and clinically translatable molecular imaging using quantitative and simultaneous PET-MRI to determine the optimal therapeutic window for patients with recurrent glioblastoma (Publication Link). I will also discuss how we have used this advancement to study new therapeutic options for the treatment of brain cancers with nanomedicines.

Clinical translation of novel targeted alpha radiometals for cancer treatment

Invited Presentations
Zachary H. Houston
Publication year: 2021

(Invited Talk) Progress & Research in Medical Physics (PRIMPS32): Queensland Branch of the Australasian College of Physical Scientists & Engineers in Medicine Annual Meeting – 6th of May, 2021

An overview was given on the new ACRF Facility for Targeted Radiometals in Cancer (AFTRiC) and research opportunities in the area of preclinical alpha radiometals research at the Centre for Advanced Imaging, UQ.

Understanding the Uptake of Nanomedicines at Different Stages of Brain Cancer Using a Modular Nanocarrier Platform and Precision Bispecific Antibodies


Journal Article
Houston, Zachary H. and Bunt, Jens and Chen, Kok-Siong and Puttick, Simon and Howard, Christopher B. and Fletcher, Nicholas L. and Fuchs, Adrian V. and Cui, Jiwei and Ju, Yi and Cowin, Gary and Song, Xin and Boyd, Andrew W. and Mahler, Stephen M. and Richards, Linda J. and Caruso, Frank and Thurecht, Kristofer J.
ACS Central Science, 2020
Publication year: 2020

Increasing accumulation and retention of nanomedicines within tumor tissue is a significant challenge, particularly in the case of brain tumors where access to the tumor through the vasculature is restricted by the blood–brain barrier (BBB). This makes the application of nanomedicines in neuro-oncology often considered unfeasible, with efficacy limited to regions of significant disease progression and compromised BBB. However, little is understood about how the evolving tumor–brain physiology during disease progression affects the permeability and retention of designer nanomedicines. We report here the development of a modular nanomedicine platform that, when used in conjunction with a unique model of how tumorigenesis affects BBB integrity, allows investigation of how nanomaterial properties affect uptake and retention in brain tissue. By combining different in vivo longitudinal imaging techniques (including positron emission tomography and magnetic resonance imaging), we have evaluated the retention of nanomedicines with predefined physicochemical properties (size and surface functionality) and established a relationship between structure and tissue accumulation as a function of a new parameter that measures BBB leakiness; this offers significant advancements in our ability to relate tumor accumulation of nanomedicines to more physiologically relevant parameters. Our data show that accumulation of nanomedicines in brain tumor tissue is better correlated with the leakiness of the BBB than actual tumor volume. This was evaluated by establishing brain tumors using a spontaneous and endogenously derived glioblastoma model providing a unique opportunity to assess these parameters individually and compare the results across multiple mice. We also quantitatively demonstrate that smaller nanomedicines (20 nm) can indeed cross the BBB and accumulate in tumors at earlier stages of the disease than larger analogues, therefore opening the possibility of developing patient-specific nanoparticle treatment interventions in earlier stages of the disease. Importantly, these results provide a more predictive approach for designing efficacious personalized nanomedicines based on a particular patient’s condition.

Translation of precision nanotheranostics through comparative oncology

Invited Presentations
Zachary H. Houston
Publication year: 2020

(Invited Talk) RADICAL 2020, Brisbane, QLD, Australia – 8th of February 2020.

An overview of the precision nanotheranostic platform we have developed with a hyperbranched polymeric core and precision custom targeting system and its subsequent applications in preclinical and clinical studies is discussed. In particular how we are using comparative oncology with companion animals to expedite the timeline for new treatments for brain and other cancers.

Theranostics for gliomas: Personalised nanomedicines

Invited Presentations
Zachary H. Houston
Publication year: 2020

(Invited Talk) Brisbane Cancer Conference – 27th of November 2020.

In this talk an overview of the clinical translation of personalised nanomedicines for the treatment of recurrent glioblastoma will be discussed.

The role of optical molecular imaging in the multimodal toolkit for determining the theranostic efficacy of nanomedicines

Invited Presentations
Zachary H. Houston
Publication year: 2020

(Invited Talk) Perkin Elmer Webinar Series. 30th of June, 2020

An overview was given on the use of molecular imaging to understand the fundamental properties of nanomedicines for their application in drug delivery. In particular how optical imaging is used effectively with other imaging modalities such as PET, CT, and MRI to answer questions that aid in the development of smarter nanomedicines. In this talk a range of projects from the Thurecht Group were discussed.

Targeted beta therapy of prostate cancer with (177)Lu-labelled Miltuximab(R) antibody against glypican-1 (GPC-1)


Journal Article
Yeh, M. C. and Tse, B. W. C. and Fletcher, N. L. and Houston, Z. H. and Lund, M. and Volpert, M. and Stewart, C. and Sokolowski, K. A. and Jeet, V. and Thurecht, K. J. and Campbell, D. H. and Walsh, B. J. and Nelson, C. C. and Russell, P. J.
EJNMMI Res 10, 46 (2020).
Publication year: 2020

Purpose

Chimeric antibody Miltuximab®, a human IgG1 engineered from the parent antibody MIL-38, is in clinical development for solid tumour therapy. Miltuximab® targets glypican-1 (GPC-1), a cell surface protein involved in tumour growth, which is overexpressed in solid tumours, including prostate cancer (PCa). This study investigated the potential of 89Zr-labelled Miltuximab® as an imaging agent, and 177Lu-labelled Miltuximab® as a targeted beta therapy, in a mouse xenograft model of human prostate cancer.

Methods

Male BALB/c nude mice were inoculated subcutaneously with GPC-1-positive DU-145 PCa cells. In imaging and biodistribution studies, mice bearing palpable tumours received (a) 2.62 MBq [89Zr]Zr-DFO-Miltuximab® followed by PET-CT imaging, or (b) 6 MBq [177Lu]Lu-DOTA-Miltuximab® by Cerenkov imaging, and ex vivo assessment of biodistribution. In an initial tumour efficacy study, mice bearing DU-145 tumours were administered intravenously with 6 MBq [177Lu]Lu-DOTA-Miltuximab® or control DOTA-Miltuximab® then euthanised after 27 days. In a subsequent survival efficacy study, tumour-bearing mice were given 3 or 10 MBq of [177Lu]Lu-DOTA-Miltuximab®, or control, and followed up to 120 days.

Results

Antibody accumulation in DU-145 xenografts was detected by PET-CT imaging using [89Zr]Zr-DFO-Miltuximab® and confirmed by Cerenkov luminescence imaging post injection of [177Lu]Lu-DOTA-Miltuximab®. Antibody accumulation was higher (% IA/g) in tumours than other organs across multiple time points. A single injection with 6 MBq of [177Lu]Lu-DOTA-Miltuximab® significantly inhibited tumour growth as compared with DOTA-Miltuximab® (control). In the survival study, mice treated with 10 MBq [177Lu]Lu-DOTA-Miltuximab® had significantly prolonged survival (mean 85 days) versus control (45 days), an effect associated with increased cancer cell apoptosis. Tissue histopathology assessment showed no abnormalities associated with [177Lu]Lu-DOTA-Miltuximab®, in line with other observations of tolerability, including body weight stability.

Conclusion

These findings demonstrate the potential utility of Miltuximab® as a PET imaging agent ([89Zr]Zr-DFO-Miltuximab®) and a beta therapy ([177Lu]Lu-DOTA-Miltuximab®) in patients with PCa or other GPC-1 expressing tumours.

Targeted and modular architectural polymers employing bioorthogonal chemistry for quantitative therapeutic delivery

Journal Article
Ediriweera, Gayathri R. and Simpson, Joshua D. and Fuchs, Adrian V. and Venkatachalam, Taracad K. and Van De Walle, Matthias and Howard, Christopher B. and Mahler, Stephen M. and Blinco, James P. and Fletcher, Nicholas L. and Houston, Zachary H. and Bell, Craig A. and Thurecht, Kristofer J.
DOI: 10.1039/d0sc00078g
Publication year: 2020

There remain several key challenges to existing therapeutic systems for cancer therapy, such as quantitatively determining the true, tissue-specific drug release profile in vivo, as well as reducing side-effects for an increased standard of care. Hence, it is crucial to engineer new materials that allow for a better understanding of the in vivo pharmacokinetic/pharmacodynamic behaviours of therapeutics. We have expanded on recent “click-to-release” bioorthogonal pro-drug activation of antibody-drug conjugates (ADCs) to develop a modular and controlled theranostic system for quantitatively assessing site-specific drug activation and deposition from a nanocarrier molecule, by employing defined chemistries. The exploitation of quantitative imaging using positron emission tomography (PET) together with pre-targeted bioorthogonal chemistries in our system provided an effective means to assess in real-time the exact amount of active drug administered at precise sites in the animal; our methodology introduces flexibility in both the targeting and therapeutic components that is specific to nanomedicines and offers unique advantages over other technologies. In this approach, the in vivo click reaction facilitates pro-drug activation as well as provides a quantitative means to investigate the dynamic behaviour of the therapeutic agent.

Investigation of the Therapeutic Potential of a Synergistic Delivery System through Dual Controlled Release of Camptothecin–Doxorubicin

Journal Article
Zhao, Yongmei and Fletcher, Nicholas L. and Gemmell, Anna and Houston, Zachary H. and Howard, Christopher B. and Blakey, Idriss and Liu, Tianqing and Thurecht, Kristofer J.
Advanced Therapeutics, 2020, doi:10.1002/adtp.201900202
Publication year: 2020

 

An ideal nanotherapeutic should enhance therapeutic efficacy of the drug while reducing side effects. This work reports development of a nanotherapeutic utilizing hyperbranched polymers as a platform for conjugating doxorubicin (DOX) and camptothecin (CPT) as potential synergistic therapies. The carrier also includes cyanine‐5 (Cy5) as an imaging tracer to monitor distribution and efficacy of the therapeutic, and a bispecific antibody (BsAb) as a cell targeting agent to increase accumulation and specificity for tumor tissue. The synergism of this drug combination is investigated by utilizing both redox‐ and hydrolytic release mechanisms of CPT and DOX, respectively. Drug release and cellular uptake studies confirm the proposed delivery mechanisms and subsequent intracellular trafficking of the drugs. In this particular case, a superadditive effect is observed in vitro for the two drugs when delivered by nanocarrier. This is enhanced when the carrier is targeted to epidermal growth factor receptor (EGFR) that is upregulated in the tumors. Moreover, tumor regression studies show that the synergistic therapeutic effect of combination nanocarriers has greater inhibition of xenograft tumor growth compared to treatments that deliver DOX or CPT alone, suggesting that codelivery of dual therapeutics using modular hyperbranched polymer carriers offers unique potential to regulate tumor growth.

Hyperbranched Poly(2-oxazoline)s and Poly(ethylene glycol): A Structure–Activity Comparison of Biodistribution


Journal Article
James Humphries, David Pizzi, Stefan E. Sonderegger, Nicholas L. Fletcher, Zachary H. Houston, Craig A. Bell, Kristian Kempe*, and Kristofer J. Thurecht*
Publication year: 2020

In light of research reporting abnormal pharmacokinetic behavior for therapeutics and formulations containing poly(ethylene glycol) (PEG), a renewed emphasis has been placed on exploring alternative surrogate materials and tailoring specific materials to distinct nanomedicine applications. Poly(2-oxazolines) (POx) have shown great promise in this regard; however, a comparison of POx and PEG interactions with components of the immune system is needed to inform on their distinct suitability. Herein, the interaction of isolated immune cells following injection of hyperbranched polymers comprised of PEG or hydrophilic POx macromonomers was determined via flow cytometry. All materials showed similar association with all of the splenic immune cells analyzed. Interestingly, splenic CD68hi and CD11bhi macrophages showed similar levels of polymer association, despite CD11bhi being a smaller population, suggesting CD68 is linked to increased recognition and phagocytosis of these nanomaterials. This is of interest given that CD68 is a scavenger receptor and directly facilitates the clearance of cellular debris and promotion of phagocytosis, as opposed to CD11b, which is associated with the mediating inflammation via the production of cytokines as well as complement-mediated uptake of foreign particles. In the liver, PEG and poly(2-methyl oxazoline) hyperbranched polymers showed no discernible differences in their cellular association, while hyperbranched poly(2-ethyl oxazoline) showed increased association with dendrocytes and CD68hi macrophages, suggesting that this material exhibited a greater propensity to interact with components of the immune system. This work highlights the importance of how subtle changes in chemical structure can influence the immune response.

Direct Comparison of Polyethylene Glycol and Phosphoryl Choline Drug-loaded Nanoparticles In Vitro and In Vivo


Journal Article
Noy, Janina-Miriam and Chen, Fan and Akhter, Dewan T. and Houston, Zachary H. and Fletcher, Nicholas L. and Thurecht, Kristofer J. and Stenzel, Martina H.
Biomacromolecules, 2020
Publication year: 2020

Phosphorylcholine is known to repel the absorption of proteins onto surfaces, which can prevent the formation of a protein corona on the surface of nanoparticles. This can influence the fate of nanoparticles used for drug delivery. This material could therefore serve as an alternative to poly(ethylene glycol) (PEG). Herein, the synthesis of different particles prepared by polymerization induced self-assembly (PISA) coated with either poly(ethylene glycol) (PEG) or zwitterionic 2-methacryloyloxyethyl phosphorylcholine (MPC) and PENAO were reported. The anti-cancer drug PENAO (4-(N-(S-penicillaminylacetyl)amino) phenylarsenonous acid) was conjugated to the shell-forming block. Interactions of the different coated nanoparticles – that represent comparable sizes and size distributions (76 – 85 nm, PDI = 0.0067 – 0.0094) – with 2D and 3D cultured cells were studied and their cytotoxicity, cellular uptake, spheroid penetration and cell localization profile was analyzed. While only a minimal difference between the nanoparticles for the conducted in vitro experiments were seen (with PEG-co-PENAO coated micelles showing slightly higher cytotoxicity, better spheroid penetration and cell localization ability), the study was amplified when in vivo biodistribution studies were conducted. After 1 hour postinjection, the majority of the MPC-co-PENAO coated nanoparticles were found to accumulate in the liver, making this particle system unfeasible for future studies.

Controlling the Biological Fate of Micellar Nanoparticles: Balancing Stealth and Targeting


Journal Article
Sivaram, A. J. and Wardiana, A. and Alcantara, S. and Sonderegger, S. E. and Fletcher, N. L. and Houston, Z. H. and Howard, C. B. and Mahler, S. M. and Alexander, C. and Kent, S. J. and Bell, C. A. and Thurecht, K. J.
1. Sivaram, A. J.; Wardiana, A.; Alcantara, S.; Sonderegger, S. E.; Fletcher, N. L.; Houston, Z. H.; Howard, C. B.; Mahler, S. M.; Alexander, C.; Kent, S. J.; Bell, C. A.; Thurecht, K. J., Controlling the Biological Fate of Micellar Nanoparticles: Balancing Stealth and Targeting. ACS Nano 2020, 14 (10), 13739-13753.
Publication year: 2020

Integrating nanomaterials with biological entities has led to the development of diagnostic tools and biotechnology-derived therapeutic products. However, to optimize the design of these hybrid bionanomaterials, it is essential to understand how controlling the biological interactions will influence desired outcomes. Ultimately, this knowledge will allow more rapid translation from the bench to the clinic. In this paper, we developed a micellar system that was assembled using modular antibody-polymer amphiphilic materials. The amphiphilic nature was established using either poly(ethylene glycol) (PEG) or a single-chain variable fragment (scFv) from an antibody as the hydrophile and a thermoresponsive polymer (poly(oligoethylene glycol) methyl ether methacrylate) as the hydrophobe. By varying the ratios of these components, a series of nanoparticles with different antibody content was self-assembled, where the surface presentation of targeting ligand was carefully controlled. In vitro and in vivo analysis of these systems identified a mismatch between the optimal targeting ligand density to achieve maximum cell association in vitro compared to tumor accumulation in vivo. For this system, we determined an optimum antibody density for both longer circulation and enhanced targeting to tumors that balanced stealthiness of the particle (to evade immune recognition as determined in both mouse models and in whole human blood) with enhanced accumulation achieved through receptor binding on tumor cells in solid tumors. This approach provides fundamental insights into how different antibody densities affect the interaction of designed nanoparticles with both target cells and immune cells, thereby offering a method to probe the intricate interplay between increased targeting efficiency and the subsequent immune response to nanoparticles.

Canine PET/CT imaging with 64Cu-nanomedicines

Conference Proceedings
Daniel, Sarah and Houston, Zachary and Fletcher, Nicholas and Bell, Craig and Atcheson, Nicole and Al-Najjar, Aiman and Howard, Christopher and Mahler, Stephen and Straw, Rod and Thurecht, Kristofer
The Journal of Nuclear Medicine{booktitle}, 2020
Publication year: 2020

Introduction: Men diagnosed with metastatic prostate cancer are faced with a poor prognosis due to the low specificity of currently available treatment options. Conventional chemotherapy, whilst efficaciously able to target multiple sites of disease, is administered systemically and leads to dose-limiting toxicity in normal healthy cells.[1] Studies in mice with the use of polyethylene glycol [PEG] based hyper-branched polymers [HBP] as a carrier vehicle for doxorubicin have shown significant promise in a new targeted drug delivery approach, delivering a payload of chemotherapy directly to the prostate cancer cells.[1,2] However, transgenic mice models may be a poor predictor of the human experience owing to the differing metabolic pathways and non-spontaneous nature of tumour cells, obviating the need to assess these materials in translational large animal models.[3] The utility of comparative oncology and PET/CT offers the opportunity to study the pathways of novel drug delivery and target specific receptors in spontaneously occurring prostate cancers, leading to a new generation of “personalised medicine”.

Methods: All PET/CT examinations were performed on a SIEMENS Biograph Horizon PET/CT scanner. General anaesthesia was used for all imaging procedures, and heart rate, blood pressure, and SpO2 were carefully observed and recorded. A canine patient with biopsy-confirmed adenocarcinoma of the prostate gland, suspected local invasion, and distant metastasis underwent a [68Ga]PSMA-11 PET/CT scan with an injected activity of 91MBq. Imaging of the whole body commenced at 60 minutes post-injection. 24 hours after initial imaging was performed a secondary scan commenced, an injection of 132MBq of [64Cu]HBP-PSMA was administered, followed by immediate 60-minute list-mode dynamic PET/CT over the region of the liver/spleen to assess organ clearance. Whole-body images were then obtained at 1, 24 and 48 hours post-injection. The canine patient then underwent a secondary biopsy to determine a suitable target receptor for further imaging studies. Upon biopsy confirmation, a [64Cu]HBP-EGFR PET/CT was performed, whereby 128MBq of activity was injected with whole-body imaging commencing 24 and 48 hours post-injection.

Results: Both the [68Ga]PSMA-11 and [64Cu]HBP-PSMA were unable to detect the presence of prostate carcinoma despite the heterogeneous appearance of the prostate gland on the low dose CT scan performed in conjunction with the PET. The subsequent biopsy of the prostate gland revealed that the tumour was Prostate-Specific Membrane Antigen negative. Further analysis revealed an overexpression of Epidermal Growth Factor Receptor, which is frequently associated with aggressive forms of prostate cancer.[4] PET/CT imaging using the more specific target [64Cu]HBP-EGFR was able to positively identify 2 lesions within the prostate gland with an SUVmax of 4.11 and 3.76, compared to the SUVmean observed in the liver of 1.19 at 24 hours post-injection. The findings in the whole-body PET/CT confirmed pharmacokinetics/distribution patterns similar to those observed in mice studies. No nodal or distant metastases were identified using [64Cu]HBP-EGFR. Conclusion: PET/CT has proven to be an effective tool in guiding the use of specific targets for drug delivery to spontaneously occurring disease. The result of this work validates results shown in previous mice studies. Comparative oncology enables researches to further understand the mechanisms of human disease and fast-track drug development. The utility of HBP as a transport mechanism for chemotherapy drugs using PET/CT to determine personalised targets is currently being investigated in canine models.

Ultrasound-responsive nanobubbles for enhanced intravitreal drug migration: An ex vivo evaluation


Journal Article
Thakur, S. S. and Chen, Y. S. and Houston, Z. H. and Fletcher, N. and Barnett, N. L. and Thurecht, K. J. and Rupenthal, I. D. and Parekh, H. S.
Eur J Pharm Biopharm, 2019
Publication year: 2019

 

The intravitreal route faces many challenges in rapidly and effectively reaching posterior eye pathology, with administered therapeutics experiencing non-specific distribution around and premature clearance from ocular tissues. Nanobubbles and ultrasound may improve outcomes of intravitreally administered drugs by influencing the directionality of drug-containing particle migration. In this study, we assessed the impact of trans-scleral or corneal ultrasound application on the distribution of intravitreally-injected nanobubbles. Rhodamine-tagged gas entrapped nanobubble formulations were prepared and injected into ex vivo bovine and porcine eyes and subjected to ultrasound (1 MHz, 0–2.5 W/cm, 50–100% duty, 60 s). Bovine eyes were partially dissected to visualize the vitreous humor and particle migration was evaluated via optical fluorescence spectroscopy. Directional migration in porcine eyes was evaluated using a snap freezing protocol complemented by quantification of regional fluorescence. The impact on nanobubble migration following pars-plana injection and sequential ultrasound cycle application from scleral or corneal-surface positions was also assessed. Administration of ultrasound significantly enhanced the directional migration of nanobubbles in both ex vivo models, with multiple corneal ultrasound cycles promoting greater migration of dye-filled nanobubbles to posterior regions of the vitreous. Moreover, particles moved in a directional manner away from the ultrasound wave source demonstrating an ability to effectively control the rate and path of nanobubble migration. These findings establish an encouraging new and safe modality enabling rapid distribution of intravitreally-injected therapeutics where expeditious therapeutic intervention is warranted.

The future of personalized cancer treatment

Abstract Reviewed Presentations
Zachary H Houston
Publication year: 2019

Pint of Science, Newstead Brewing Co., Newstead, QLD – 20th of May, 2019.

Pint of Science is an international organization aimed at creating a comfortable and relaxed environment for scientists to discuss their work to the general public. The following is a brief excerpt from the 2019 program about my talk:

Join me to hear about the future of cancer treatment using personalised and smarter solutions called nanomedicines, and see how we are improving the outlook for patients with tumours, while also helping our canine friends.

Supramolecular Fluorine Magnetic Resonance Spectroscopy Probe Polymer Based on Passerini Bifunctional Monomer


Journal Article
Couturaud, Benoit and Houston, Zachary H. and Cowin, Gary J. and Prokeš, Ivan and Foster, Jeffrey C. and Thurecht, Kristofer J. and O’Reilly, Rachel K.
ACS Macro Letters, 2019, 8, 11, 1479-1483.
Publication year: 2019

 

A water-soluble fluorine magnetic resonance spectroscopy host-guest probe, P(HPA-co-AdamCFA), was successfully constructed from the facile synthesis of a bifunctional monomer via a quantitative Passerini reaction. Supramolecular complexation with (2-hydroxypropyl)-β-cyclodextrin promoted a change in the chemical environment, leading to modulation of both the relaxation properties as well as chemical shift of the fluorine moieties. This change was used to probe the supramolecular interaction by F MRI spectroscopy and give insight into fluorine probe formulation. This work provides a fundamental basis for an F MR imaging tracer capable of assessing host-guest inclusion and a potential model to follow the fate of a drug delivery system in vivo.

Site-specific delivery of a topoisomerase inhibitor for enhanced tumour treatment with a synergistic targeted polymer nanotheranostic

Abstract Reviewed Presentations
Yongmei Zhao, Nicholas L. Fletcher, Anna Gemmell, Zachary H. Houston, Idriss Blakey, Tianqing Liu, Kristofer J. Thurecht
Publication year: 2019

37th Australasian Polymer Symposium – Novotel Twin Waters, Twin Waters, QLD, Australia. 10th – 13th of November, 2019.

Chemotherapetics such as doxorubicin (DOX) are of interest to work as synergistic pairs with enzyme inhibitors (camptothecin, CPT) to increase the efficacy of treatment. We have prepared a hyperbranched polymer dual-theranostic system with site-specific synergistic delivery of two drugs on a single construct. The nanotheranostic also contained Cy5 as an imaging tracer and was targeted using a bisbepcific antibody with affinity for breast cancer.  The carrier exhibited release of both molecules in two-time scales by exploiting both redox and hydrolytic mechanisms for CPT and DOX, respectively. The release of the drug and cellular uptake were validated in vitro, and intracellular trafficking was also investigated with confocal microscopy. Both the targeting towards epidermal growth factor receptor (EGFR) and the synergistic release of drugs lead to an enhanced therapeutic response with no observable adverse effects on the mouse health.  The results show promising potential for this system as a synergistic treatment for breast cancer.

Polymer theranostics as vehicles for biologically inspired design of nanomedicines in preclinical and comparative oncology

Invited Presentations
Zachary H Houston
Publication year: 2019

(Invited Talk) Workshop on Radiobiology, Omics and Microdosimetry of Systemic and Targeted Radiotherapies – Oak Ridge National Labs, Oak Ridge, TN, USA. 24th of July, 2019.

In the Thurecht group, we are interested in the biologically inspired design of finely tuned nanomaterials for the diagnosis and treatment of various cancers and diseased tissues.  By applying modern imagining modalities of fluorescence, PET, CT, MRI, and photoacoustics we have developed a range of nanomedicines with modular targeting, site-selective drug delivery, and probes that image biological processes in addition to giving biodistribution and accumulation information.  We are now translating these preclinical results up the pipeline from rodents to companion animals and applying comparative oncology methodologies to translate these cutting-edge theranostics into the clinical space.

Overcoming challenges of in vivo targeting (CBNS Signature Project Update)

Abstract Reviewed Presentations
Zachary H Houston
Publication year: 2019

Centre of Excellence for Convergent Bio-Nano Science and Technology 5th Annual Workshop, Healesville, VIC, Australia, 27th – 29th of November, 2019.

As postdoctoral leader on the signature project for the CBNS, I deliver the annual presentation of the project’s progress at the Annual Research Workshop.

Oral Delivery of Multicompartment Nanomedicines for Colorectal Cancer Therapeutics: Combining Loco‐Regional Delivery with Cell‐Target Specificity


Journal Article
Akhter, D. T. and Simpson, J. D. and Advanced …, Fletcher - N. L.
Advanced Therapeutics, 3: 1900171, 2019
Publication year: 2019

 

Nanomaterials for targeted delivery of chemotherapeutics have received significant attention owing to their potential to enhance the accumulation of therapeutics in diseased tissue. However, in diseases with poor vascularization, such as colorectal cancer (CRC), intravenously injected materials have reduced access to the site of interest. To overcome this challenge, oral administration of targeted nanomedicines is highly desirable. Here, a multicomponent drug delivery system incorporating a degradable alginate microcapsule, formulated to encapsulate micelles targeted to the CD44 receptor is presented. Functional micelles are generated by coupling hyaluronic acid (to target CD44 receptor) to block copolymers of poly(ethylene glycol) monomethyl ether methacrylate and poly(methyl methacrylate). When encapsulated into alginate microcapsules, these micelles form the basis of a novel oral delivery system that offers protection from degradative compartments of the gastrointestinal tract (GIT) and regio-specific release. The microcapsules demonstrate desirable site-specific degradation properties in an orthotopic CRC xenograft mouse model, yielding enhanced accumulation of micelles within CD44+ colorectal tumors. The results illustrate that such materials successfully navigate the GIT, regio-specifically release targeted micelles at the tumor site, and consequently accomplish enhanced accumulation within tumor tissue. Such multi-component nanomaterials offer a promising means for addressing challenges in treating CRC and difficult to treat diseases.

Molecular imaging as a tool for informing bioavailability

Invited Presentations
Zachary H. Houston
Publication year: 2019

(Invited Lecture) NZ Controlled Release Society Workshop on Improving Bioavailabliity – University of Otago, Dunedin, New Zealand. 21st of November, 2019.

In this workshop we will work as a collective group (and sometimes in breakout teams) to generate a list of questions that need to be addressed in order to establish a method for diagnosing and monitoring response to treatment of a brain tumour. During the process of developing this method, we will learn about the major imaging techniques available and the types of information that can be obtained from the imaging techniques.  We will also apply this knowledge to work as a team to develop experiments to determine the therapeutic efficacy of the treatment.

Modulating Targeting of Poly(ethylene glycol) Particles to Tumor Cells Using Bispecific Antibodies


Journal Article
Cui, J. and Ju, Y. and Houston, Z. H. and Glass, J. J. and Fletcher, N. L. and Alcantara, S. and Dai, Q. and Howard, C. B. and Mahler, S. M. and Wheatley, A. K. and De Rose, R. and Brannon, P. T. and Paterson, B. M. and Donnelly, P. S. and Thurecht, K. J. and Caruso, F. and Kent, S. J.
Adv Healthc Mater., 2019, 8, 1801607.
Publication year: 2019

 

Low-fouling or “stealth” particles composed of poly(ethylene glycol) (PEG) display a striking ability to evade phagocytic cell uptake. However, functionalizing them for specific targeting is challenging. To address this challenge, stealth PEG particles prepared by a mesoporous silica templating method are functionalized with bispecific antibodies (BsAbs) to obtain PEG-BsAb particles via a one-step binding strategy for cell and tumor targeting. The dual specificity of the BsAbs-one arm binds to the PEG particles while the other targets a cell antigen (epidermal growth factor receptor, EGFR)-is exploited to modulate the number of targeting ligands per particle. Increasing the BsAb incubation concentration increases the amount of BsAb tethered to the PEG particles and enhances targeting and internalization into breast cancer cells overexpressing EGFR. The degree of BsAb functionalization does not significantly reduce the stealth properties of the PEG particles ex vivo, as assessed by their interactions with primary human blood granulocytes and monocytes. Although increasing the BsAb amount on PEG particles does not lead to the expected improvement in tumor accumulation in vivo, BsAb functionalization facilitates tumor cell uptake of PEG particles. This work highlights strategies to balance evading nonspecific clearance pathways, while improving tumor targeting and accumulation.

Innovative Therapeutic Strategies for Effective Treatment of Brain Metastases


Journal Article
Lim, M. and Puttick, S. and Houston, Z. H. and Thurecht, K. J. and Kalita-de Croft, P. and Mahler, S. and Rose, S. E. and Jeffree, R. L. and Mazzieri, R. and Dolcetti, R. and Lakhani, S. R. and Saunus, J. M.
Int J Mol Sci, 2019, 20(6), 1280.
Publication year: 2019

 

Brain metastases are the most prevalent of intracranial malignancies. They are associated with a very poor prognosis and near 100% mortality. This has been the case for decades, largely because we lack effective therapeutics to augment surgery and radiotherapy. Notwithstanding improvements in the precision and efficacy of these life-prolonging treatments, with no reliable options for adjunct systemic therapy, brain recurrences are virtually inevitable. The factors limiting intracranial efficacy of existing agents are both physiological and molecular in nature. For example, heterogeneous permeability, abnormal perfusion and high interstitial pressure oppose the conventional convective delivery of circulating drugs, thus new delivery strategies are needed to achieve uniform drug uptake at therapeutic concentrations. Brain metastases are also highly adapted to their microenvironment, with complex cross-talk between the tumor, the stroma and the neural compartments driving speciation and drug resistance. New strategies must account for resistance mechanisms that are frequently engaged in this milieu, such as HER3 and other receptor tyrosine kinases that become induced and activated in the brain microenvironment. Here, we discuss molecular and physiological factors that contribute to the recalcitrance of these tumors, and review emerging therapeutic strategies, including agents targeting the PI3K axis, immunotherapies, nanomedicines and MRI-guided focused ultrasound for externally controlling drug delivery.

Importance of Polymer Length in Fructose-Based Polymeric Micelles for an Enhanced Biological Activity


Journal Article
Lu, Mingxia and Chen, Fan and Cao, Cheng and Garvey, Christopher J. and Fletcher, Nicholas L. and Houston, Zachary H. and Lu, Hongxu and Lord, Megan S. and Thurecht, Kristofer J. and Stenzel, Martina H.
Macromolecules, 2019, 52, 2, 477-486.
Publication year: 2019

 

The efficiency of nanoparticle-based drug delivery systems to accumulate in targeted tumor sites is low owing primarily to the various biological mechanisms that promote premature clearance, such as renal filtration or the mononuclear phagocyte system (MPS). Such obstacles to enhanced tumor accumulation of nanomedicines remain formidable challenges to drug carrier design. It is thought that nanoparticles decorated with bioactive groups such as glycopolymers, compared to individual monovalent carbohydrate ligands, can assist in the enhanced delivery of payloads to tumors due to their multivalent effect. While glycopolymers are widely applied, limited attention has been dedicated to understanding how the presentation of glycopolymers on the surface of micelle may affect the biological activity. We utilized biodegradable and biocompatible polylactide–fructose block copolymers to investigate the effect of chain length of the hydrophilic fructose block on the biological activity. Three different fructose chain length polymers were prepared and self-assembled into spherical micelles. We discovered that their bioactivity is sugar-length-dependent, where a minimum sugar length is required to enhance cellular uptake and bind to receptors on the cell surface. According to SAXS (small angle X-ray scattering) data, micelles were formed in three layers with a polylactide core, followed by a mixed layer which may contains both PLA and fructose and finally an outer layer of fructose. The level of hydration was observed to be dependent on the length of the polymer with longer polymers leading to more hydrated glycopolymer layers. As a result, the high water content promoted enhanced flexibility of the fructose segments coinciding with effective receptor binding. This led to enhanced cell uptake by MDA-MB-231 and MCF-7 cells, which overexpress GLUT5 receptors, which ultimately resulted in higher accumulation in multicellular spheroid (3D) models. Moreover, the longer fructose chain length micelles exhibited reduced clearance by MPS in an in vivo study.

Biologically driven nanomedicine design and optimization informed by optical imaging

Invited Presentations
Zachary H Houston
Publication year: 2019

(Invited Talk) The Perkin Elmer Sydney Symposium on Cell Biology, Immunology, Cancer and Drug Discovery – University of New South Wales, Kensington, NSW, Australia. 6th of August, 2019.

An overview was given on the use of molecular imaging to understand the fundamental properties of nanomedicines for their application in drug delivery. A range of projects from the Thurecht Group were discussed.

Biologically driven nanomedicine design and optimization informed by optical imaging

Invited Presentations
Zachary H Houston
Publication year: 2019

(Invited Talk) The Perkin Elmer Melbourne Symposium on Cell Biology, Immunology, Cancer and Drug Discovery – The Florey Institute, Parkville, VIC, Australia. 5th of August, 2019

An overview was given on the use of molecular imaging to understand the fundamental properties of nanomedicines for their application in drug delivery. A range of projects from the Thurecht Group were discussed.

Applied comparative oncology of nanomedicines to diagnose and treat canine prostate cancer

Abstract Reviewed Presentations
Zachary H. Houston, Nicholas L. Fletcher, Craig Bell, Sarah Daniel, Nicole Atcheson, Aiman Al-Najar, Christopher B. Howard, Stephen M. Mahler, Rod Straw, Kristofer J. Thurecht
Publication year: 2019

10th International Nanomedicine Conference – Sydney, New South Wales, Australia. 25th of June, 2019.

Successful realisation of nanomedicines in clinical application is limited and can be considerably attributed to the biological heterogeneity between animals used in preclinical testing, and the patients assessed in clinical trials. In the modern era of a search for personalised treatment nanomedicines provide the perfect architecture to build an individualised treatment plan, but translation of these new constructs requires a robust and flexible treatment methodology that can be validated not only in mice but in animal models more similar to humans. Here we report on the first ever comparative oncology approach to the diagnosis and treatment of a canine patient with spontaneously occurring prostate cancer (Figure 1) with targeted nanomedicines. The canine patient was diagnosed with prostate cancer and the standard clinical tracer targeted towards prostate-specific membrane antigen (PSMA) 68Ga-PSMA was used to confirm this diagnosis using PET-CT. A nanomedicine prepared for the same target was also injected at a later time. Neither the 68Ga-PSMA or nanomedicine were able to positively identify the tumour, and after biopsy it was found that the tumour was in fact PSMA negative. The canine was treated with a nanomedicine loaded with a chemotherapeutic and after analysis of a biopsy of the tumour tissue taken prior to treatment, a more specific target (EGFR) was found to be overexpressed in the cancer. After imaging a second time with the nanomedicine targeted to this receptor, positive identification of the tumour was made. MRI also revealed a change in the composition of the tumour tissue, indicating a positive effect by the therapeutic nanomedicine and further validating the application of these constructs for use in future personalised medicine approaches to cancer treatment in humans.

Using advanced animal models to validate nanomedicine interactions with hard-to-treat tumours

Abstract Reviewed Presentations
Zachary H. Houston
Publication year: 2018

ARC Joint Symposium – Advanced Bioengineered Systems, Brisbane, Australia, 20th of November, 2018.

A discussion of the various animal models that are used for the investigation of nanomedicines and their relative strengths and weaknesses towards developing more robust therapeutic delivery systems was given.

Translating across animal models toward personalized nanomedicinesCentre of Excellence for Convergent Bio-Nano Science and Technology 4th Annual Workshop, Terrigal, NSW, Australia, 28th – 30th of November, 2018.

Abstract Reviewed Presentations
Zachary H Houston
Publication year: 2018

Centre of Excellence for Convergent Bio-Nano Science and Technology 4th Annual Workshop, Terrigal, NSW, Australia, 28th – 30th of November, 2018.

An overview of the challenges in developing personalised nanomedicines and was given at this year’s CBNS Annual Research Workshop. In particular the topic of choosing the best animal model for the research question as well as translating information from one model to another to progress work towards clinical application.

Modified Organosilica Core-Shell Nanoparticles for Stable pH Sensing in Biological Solutions


Journal Article
Robinson, K. J. and Huynh, G. T. and Kouskousis, B. P. and Fletcher, N. L. and Houston, Z. H. and Thurecht, K. J. and Corrie, S. R.
ACS Sens{booktitle}, 2018
Publication year: 2018

 

Continuous monitoring using nanoparticle-based sensors has been successfully employed in complex biological systems, yet the sensors still suffer from poor long-term stability partially because of the scaffold materials chosen to date. Organosilica core–shell nanoparticles containing a mixture of covalently incorporated pH-sensitive (shell) and pH-insensitive (core) fluorophores is presented as a continuous pH sensor for application in biological media. In contrast to previous studies focusing on similar materials, we sought to investigate the sensor characteristics (dynamic range, sensitivity, response time, stability) as a function of material properties. The ratio of the fluorescence intensities at specific wavelengths was found to be highly sensitive to pH over a physiologically relevant range (4.5–8) with a response time of <100 ms, significantly faster than that of previously reported response times using silica-based particles. Particles produced stable, pH-specific signals when stored at room temperature for more than 80 days. Finally, we demonstrated that the nanosensors successfully monitored the pH of a bacterial culture over 15 h and that pH changes in the skin of mouse cadavers could also be observed via in vivo fluorescence imaging following subcutaneous injection. The understanding gained from linking sensor characteristics and material properties will inform the next generation of optical nanosensors for continuous-monitoring applications.

Influence of Charge on Hemocompatibility and Immunoreactivity of Polymeric Nanoparticles


Journal Article
Chen, Liyu and Glass, Joshua J. and De Rose, Robert and Sperling, Claudia and Kent, Stephen J. and Houston, Zachary H. and Fletcher, Nicholas L. and Rolfe, Barbara E. and Thurecht, Kristofer J.
ACS Applied Bio Materials{booktitle}, 2018
Publication year: 2018

 

The benefits of nanomedicine may be restricted by hemocompatibility and immunoreactivity problems arising from administration of exogenous materials into the bloodstream. To understand how surface charge influences the interaction of polymeric nanoparticles with blood components, we synthesized three well-defined, chargevaried hyperbranched polymers (HBPs) of similar size and analyzed both hemocompatibility and immunoreactivity of these methacrylate-based HBPs ex vivo using primary human blood cell assays and image analyses following intravenous injection into mice. The results show that, regardless of charge, endotoxin-free HBPs had minimal effects on coagulation, platelet, complement, or T cell activation. However, high concentrations (100 μg mL) of cationic HBPs led to significant dendritic cell activation, suggesting the potential application of these nanoparticles as vaccine adjuvants to aid efficient antigen presentation. Biodistribution studies showed that intravenously administered charge-neutral HBPs had a longer retention time in the circulation than cationic or anionic HBPs; whereas these neutral HBPs were eventually cleared in the urine, charged HBPs mainly accumulated in liver and spleen. Overall, these results demonstrate that, regardless of surface charge, HBPs display a high level of hemocompatibility. In contrast, immunoreactivity and biodistribution are significantly influenced by charge. Manipulation of surface charge may thus be a useful method by which nanomaterials such as HBPs can be tailored to different clinical applications.

In vivo therapeutic evaluation of polymeric nanomedicines: effect of different targeting peptides on therapeutic efficacy against breast cancer


Journal Article
Zhao, Y. and Fletcher, N. L. and Liu, T. and Gemmell, A. C. and Houston, Z. H. and Blakey, I. and Thurecht, K. J.
Nanotheranostics{booktitle}, 2018
Publication year: 2018

 

Targeted nanomedicines offer many advantages over macromolecular therapeutics that rely only on passive accumulation within the tumour environment. The aim of this work was to investigate the anticancer efficiency of polymeric nanomedicines that were conjugated with peptide aptamers that show high affinity for receptors on many cancer cells. In order to assess the ability for the nanomedicine to treat cancer and investigate how structure affected the behavior of the nanomedicine, three imaging modalities were utilized, including optical imaging, multispectral optoacoustic tomography (MSOT) and confocal microscopy. An 8-mer (A8) or 13-mer (A13) peptide aptamer that have been shown to exhibit high affinity for heat shock protein 70 (HSP70) was covalently-bound to hyperbranched polymer (HBP) nanoparticles with the purpose of both cellular targeting, as well as the potential to impart some level of chemo-sensitization to the cells. Furthermore, doxorubicin was bound to the polymeric carrier as the anticancer drug, and Cyanine-5.5 (Cy5.5) was incorporated into the polymer as a monomeric fluorophore to aid in monitoring the behavior of the nanomedicine. Enhanced tumour regression was observed in nude mice bearing MDA-MB-468 xenografts when the nanocarriers were targeted using the peptide ligands, compared to control groups treated with free DOX or HBP without aptamer. The accumulated DOX level in solid tumours was 5.5 times higher in mice treated with the targeted therapeutic, than mice treated with free DOX, and 2.6 times higher than the untargeted nanomedicine that relied only on passive accumulation. The results suggest that aptamer-targeted therapeutics have great potential for improving accumulation of nanomedicines in tumours for therapy.

Hyperbranched Polymers as Nanocarriers


Book Chapter
Houston, Zachary H. and Bell, Craig A. and Thurecht, Kristofer J.
Encyclopedia of Polymer Science and Technology{booktitle}, 2018
Publication year: 2018

 

Hyperbranched polymers (HBPs) have shown widespread academic and commercial success in the preparation of films and novel materials, and now are emerging into the biomedical research space as nanocarriers for use in drug delivery and diagnostics. HBPs exhibit ideal sizes for delivery in vivo, have well‐established chemistries for their synthesis, as well as offering multiple methods of incorporation of a variety of targeting, therapeutic, and diagnostic moieties. By choice of material and functionality, their biostability or biodegradability can be fine‐tuned for multistaged or time‐delayed release of therapeutics. With significant advances in the development of nanomedicines, in particular chemistries surrounding biomolecule conjugation and the evolution of imaging techniques, the multimodal capabilities of HBPs combined with facile and controlled synthetic engineering of HBPs have resulted in properties that are ideal for their application as nanocarriers. While HBP nanocarriers offer limitless synthetic opportunity, to address the many biological challenges that are now well‐established in nanotherapeutics, new approaches to how HBPs are designed are required. This overview aims to address the points that must be considered in the biologically driven nanomaterial design of HBP nanocarriers.

Designed multifunctional polymeric nanomedicines: long-term biodistribution and tumour accumulation of aptamer-targeted nanomaterials


Journal Article
Fletcher, N. L. and Houston, Z. H. and Simpson, J. D. and Veedu, R. N. and Thurecht, K. J.
Chem Commun (Camb){booktitle}, 2018
Publication year: 2018

 

We report a novel multifunctional hyperbranched polymer based on polyethylene glycol (PEG) as a nanomedicine platform that facilitates longitudinal and quantitative 89Zr-PET imaging, enhancing knowledge of nanomaterial biodistribution and pharmacokinetics/pharmacodynamics both in vivo and ex vivo. Anti-VEGF-A DNA aptamer functionalization increased tumour accumulation by >2-fold in a breast cancer model.

Creating a stronger link between nanomedicine development and the clinic for the treatment of gliomas

Abstract Reviewed Presentations
Zachary H Houston
Publication year: 2018

11th Annual Scientific Meeting for Cooperative Trials Group for Neuro-Oncology (COGNO), Brisbane, Australia, 7th-9th of October, 2018.

As part of a clinically focussed conference, I gave a brief talk on the work towards the development of nanomedicines to treat glioblastoma.  This talk did not have an abstract, but the work is similar to another talk given previously. The abstract for this is copied below:

Nanomaterials come in a plethora of designs, shapes, chemical formulations, sizes, and ionic forms and can be readily tuned to surpass many of the biological barriers within the body, but have had limited success in surpassing the final frontier of barriers: the blood-brain barrier (BBB). While their size is a significant advantage of nanoparticles for their delivery to solid tumour masses, it is also their Achilles’ heel for crossing the BBB. A major area of interest for nanoparticle therapeutics is the delivery to glioblastoma (GBM), as it is the most aggressive form of brain cancer. Herein we report the use of simultaneous PET-MRI to develop a toolkit for monitoring tumour progression and its effect on BBB integrity of a spontaneous transgenic glioma model1,2, for the purpose of establishing when the BBB is compromised enough for nanoparticles to cross. A series of T1, T2, and dynamic contrast enhanced MRI images along with simultaneous PET of 18FDOPA were used to devise a set of in vivo imaging markers that could establish tumour volume and a measure of BBB integrity. PET was again used to analyse the ability of a 64Cu labelled bispecific antibody targeted hyperbranched polymer (HBP) 3 cross the BBB at different stages of GBM progression. As expected, larger tumour volumes and a higher degree of leaky vasculature correlate with increased BBB permeability by the HBP. This measure can be applied in the future to different sized nanoparticles and other materials to enable better development of BBB-penetrating nanocarriers.

Confinement of Therapeutic Enzymes in Selectively Permeable Polymer Vesicles by Polymerization-Induced Self-Assembly (PISA) Reduces Antibody Binding and Proteolytic Susceptibility


Journal Article
Blackman, L. D. and Varlas, S. and Arno, M. C. and Houston, Z. H. and Fletcher, N. L. and Thurecht, K. J. and Hasan, M. and Gibson, M. I. and O’Reilly, R. K.
ACS Cent Sci{booktitle}, 2018
Publication year: 2018

 

Covalent PEGylation of biologics has been widely employed to reduce immunogenicity, while improving stability and half-life in vivo. This approach requires covalent protein modification, creating a new entity. An alternative approach is stabilization by encapsulation into polymersomes; however this typically requires multiple steps, and the segregation requires the vesicles to be permeable to retain function. Herein, we demonstrate the one-pot synthesis of therapeutic enzyme-loaded vesicles with size-selective permeability using polymerization-induced self-assembly (PISA) enabling the encapsulated enzyme to function from within a confined domain. This strategy increased the proteolytic stability and reduced antibody recognition compared to the free protein or a PEGylated conjugate, thereby reducing potential dose frequency and the risk of immune response. Finally, the efficacy of encapsulated L-asparaginase (clinically used for leukemia treatment) against a cancer line was demonstrated, and its biodistribution and circulation behavior in vivo was compared to the free enzyme, highlighting this methodology as an attractive alternative to the covalent PEGylation of enzymes.

Biologically driven theranostic nanoparticle design using molecular imaging

Invited Presentations
Zachary H Houston
Publication year: 2018

(Invited Talk) Australian Society of Medical Imaging and Radiation Therapy (ASMIRT) QLD Branch Meeting, QLD, Australia, 29th of May, 2018.

An overview of the various projects in the Thurecht Group to an audience of radiologists and medical imaging specialists as part of their annual branch meeting.

A systematic evaluation of the therapeutic potential of nanomedicines for glioblastoma

Invited Presentations
Zachary H Houston
Publication year: 2018

(Invited Talk) Singapore Bioimaging Consortium & UQ Centre for Advanced Imaging 4th Annual Symposium, Singapore, 1st-3rd of August, 2018.

A formal abstract was not written for this presentation, but the work is of the same topic as another invited talk, for which the abstract is pasted below:

Nanomaterials come in a plethora of designs, shapes, chemical formulations, sizes, and ionic forms and can be readily tuned to surpass many of the biological barriers within the body, but have had limited success in surpassing the final frontier of barriers: the blood-brain barrier (BBB). While their size is a significant advantage of nanoparticles for their delivery to solid tumour masses, it is also their Achilles’ heel for crossing the BBB. A major area of interest for nanoparticle therapeutics is the delivery to glioblastoma (GBM), as it is the most aggressive form of brain cancer. Herein we report the use of simultaneous PET-MRI to develop a toolkit for monitoring tumour progression and its effect on BBB integrity of a spontaneous transgenic glioma model1,2, for the purpose of establishing when the BBB is compromised enough for nanoparticles to cross. A series of T1, T2, and dynamic contrast enhanced MRI images along with simultaneous PET of 18FDOPA were used to devise a set of in vivo imaging markers that could establish tumour volume and a measure of BBB integrity. PET was again used to analyse the ability of a 64Cu labelled bispecific antibody targeted hyperbranched polymer (HBP) 3 cross the BBB at different stages of GBM progression. As expected, larger tumour volumes and a higher degree of leaky vasculature correlate with increased BBB permeability by the HBP. This measure can be applied in the future to different sized nanoparticles and other materials to enable better development of BBB-penetrating nanocarriers.

Using Peptide Aptamer Targeted Polymers as a Model Nanomedicine for Investigating Drug Distribution in Cancer Nanotheranostics


Journal Article
Zhao, Y. and Houston, Z. H. and Simpson, J. D. and Chen, L. and Fletcher, N. L. and Fuchs, A. V. and Blakey, I. and Thurecht, K. J.
Mol Pharm{booktitle}, 2017
Publication year: 2017

 

Theranostics is a strategy that combines multiple functions such as targeting, stimulus-responsive drug release, and diagnostic imaging into a single platform, often with the aim of developing personalized medicine.1,2 Based on this concept, several well-established hyperbranched polymeric theranostic nanoparticles were synthesized and characterized as model nanomedicines to investigate how their properties affect the distribution of loaded drugs at both the cell and whole animal levels. An 8-mer peptide aptamer was covalently bound to the periphery of the nanoparticles to achieve both targeting and potential chemosensitization functionality against heat shock protein 70 (Hsp70). Doxorubicin was also bound to the polymeric carrier as a model chemotherapeutic drug through a degradable hydrazone bond, enabling pH-controlled release under the mildly acid conditions that are found in the intracellular compartments of tumor cells. In order to track the nanoparticles, cyanine-5 (Cy5) was incorporated into the polymer as an optical imaging agent. In vitro cellular uptake was assessed for the hyperbranched polymer containing both doxorubicin (DOX) and Hsp70 targeted peptide aptamer in live MDA-MB-468 cells, and was found to be greater than that of either the untargeted, DOX-loaded polymer or polymer alone due to the specific affinity of the peptide aptamer for the breast cancer cells. This was also validated in vivo with the targeted polymers showing much higher accumulation within the tumor 48 h postinjection than the untargeted analogue. More detailed assessment of the nanomedicine distribution was achieved by directly following the polymeric carrier and the doxorubicin at both the in vitro cellular level via compartmental analysis of confocal images of live cells and in whole tumors ex vivo using confocal imaging to visualize the distribution of the drug in tumor tissue as a function of distance from blood vessels. Our results indicate that this polymeric carrier shows promise as a cancer theranostic, demonstrating active targeting to tumor cells with the capability for simultaneous drug release.

Understanding tumour microenvironment distribution and real-time therapeutic efficiency of nanomedicines using MSOT

Invited Presentations
Zachary H Houston
Publication year: 2017

(Invited Talk) MSOT Symposium at 10th World Molecular Imaging Conference, Philadelphia, Pennsylvania, USA. 12th of September, 2017.

An overview of how molecular imaging is used to develop nanomedicines in the Thurecht Group was given, as well as current projects and future outlooks towards the use of photoacoustics in this pursuit.

Preclinical assessment of nanomedicines for the diagnosis and treatment of gliomas using PET-MRI

Posters
Zachary H. Houston, Kristofer J. Thurecht
Publication year: 2017

(Poster) 10th World Molecular Imaging Conference, Philadelphia, Pennsylvania, USA. 16th of September, 2017.

Background:  Multidrug resistance in chemotherapy is a considerable challenge to overcome in the treatment of metastatic cancers. Monitoring this resistance with a non-invasive imaging technique would allow clinicians to readily alter the treatment plan to allow for a higher survival rate and potentially preventing metastasis due to chemotherapeutic resistance.  Magnetic Resonance Imaging (MRI) possesses the spatial resolution necessary to assess the presence of a solid tumour mass, but lacks the specificity to assess the biochemical behaviour of the tumour.  One such biomarker, glutathione, is a tripeptide that has been well-documented to be released in higher concentrations in pre-metastatic and drug resistant tumours1.  While 1H MRI allows for assessment of tissue types, 19F-MRI offers a unique diagnostic platform with minimal endogenous background signal in vivo and increased sensitivity. A nanoprobe capable of imaging a biological process, particularly in response to treatment, is therefore a valuable tool to monitor the progression and efficacy of chemotherapy on a biochemical level.

Hypothesis:  Assessment of glutathione levels in multidrug resistant cancer cell lines can be non-invasively assessed using a chemically responsive probe by taking advantage of the specificity of contrast enhanced 19F-MRI.

Aims:  The initial aim of this project was to prepare and assess the viability of a 19F switchable probe utilising the paramagnetic relaxation enhancement effect (PRE) by gadolinium (Gd3+) on the 19F nuclei.   The second aim was to analyse the responsiveness of a previously reported hyperbranched polymeric nanocarrier2, modified with an biologically responsive linker, to changing concentrations of glutathione in both standard solutions and in different cellular environments.

Results & Summary:  Two 19F enriched polymers were prepared with fixed DOTA chelators at different structural positions to assess the optimal proximity and composition for the greatest PRE response.   Both T1 and T2 relaxation times, as well as 1H- and 19F-MR images confirmed that the adjacent pairing of the 19F source and Gd3+ yielded the best switchable response.  A 19F enriched nanprobe bound with a tumour-microenvironment responsive DOTA[Gd3+] switch is therefore expected to exhibit a concentration dependent 19F T2-weighted MR image, allowing for the analysis of the biological response to a treatment and assessment of the progression of the disease.  The reported nanoprobe and method holds the potential to add significant diagnostic information in the assessment and treatment of metastatic cancer by utilising existing imaging modalities.

References:

  1. Calvert, P., Yao, K.-S., Hamilton, T. C. & O’Dwyer, P. J. Clinical studies of reversal of drug resistance based on glutathione. Chemico-biological interactions 111, 213–224 (1998).
  2. Rolfe, B. et al. Multimodal polymer nanoparticles with combined 19F magnetic resonance and optical detection for tunable, targeted, multimodal imaging in vivo. Journal of the American Chemical Society 136, 2413

Overcoming challenges of in vivo targeting

Abstract Reviewed Presentations
Zachary H Houston
Publication year: 2017

Centre of Excellence for Convergent Bio-Nano Science and Technology 3rd Annual Workshop, Twin Waters, QLD, Australia, 25th – 27th of October, 2017.

As postdoctoral leader on the signature project for the CBNS, I deliver the annual presentation of the project’s progress at the Annual Research Workshop.

Nanoparticles and the blood-brain barrier: a multimodal toolkit for the development of nano-theranostics for the treatment of glioblastoma

Invited Presentations
Zachary H Houston
Publication year: 2017

(Invited Talk) International Nanomedicine Conference – Coogee, New South Wales, Australia. 3rd of July, 2017.

Nanomaterials come in a plethora of designs, shapes, chemical formulations, sizes, and ionic forms and can be readily tuned to surpass many of the biological barriers within the body, but have had limited success in surpassing the final frontier of barriers: the blood-brain barrier (BBB). While their size is a significant advantage of nanoparticles for their delivery to solid tumour masses, it is also their Achilles’ heel for crossing the BBB. A major area of interest for nanoparticle therapeutics is the delivery to glioblastoma (GBM), as it is the most aggressive form of brain cancer. Herein we report the use of simultaneous PET-MRI to develop a toolkit for monitoring tumour progression and its effect on BBB integrity of a spontaneous transgenic glioma model1,2, for the purpose of establishing when the BBB is compromised enough for nanoparticles to cross. A series of T1, T2, and dynamic contrast enhanced MRI images along with simultaneous PET of 18FDOPA were used to devise a set of in vivo imaging markers that could establish tumour volume and a measure of BBB integrity. PET was again used to analyse the ability of a 64Cu labelled bispecific antibody targeted hyperbranched polymer (HBP) 3 cross the BBB at different stages of GBM progression. As expected, larger tumour volumes and a higher degree of leaky vasculature correlate with increased BBB permeability by the HBP. This measure can be applied in the future to different sized nanoparticles and other materials to enable better development of BBB-penetrating nanocarriers.

Nanoparticles and the blood-brain barrier: a multimodal toolkit for the development of nano-theranostics for the treatment of glioblastoma

Abstract Reviewed Presentations
Zachary H. Houston, Jens Bunt, Linda J. Richards, Kristofer J. Thurecht
Publication year: 2017

The Centre for Advanced Imaging 4th Annual Symposium, 29th of September, 2017.

Nanomaterials come in a plethora of designs, shapes, chemical formulations, sizes, and ionic forms and can be readily tuned to surpass many of the biological barriers within the body, but have had limited success in surpassing the final frontier of barriers: the blood-brain barrier (BBB).  While their size is a significant advantage of nanoparticles for their delivery to solid tumour masses, it is also their Achilles’ heel for crossing the BBB.  A major area of interest for nanoparticle therapeutics is the delivery to glioblastoma (GBM), as it is the most aggressive form of brain cancer.  Herein we report the use of simultaneous PET-MRI to develop a toolkit for monitoring tumour progression and its effect on BBB integrity of a spontaneous transgenic glioma model1,2, for the purpose of establishing when the BBB is compromised enough for nanoparticles to cross.  A series of T1, T2, and dynamic contrast enhanced MRI images along with simultaneous PET of 18FDOPA were used to devise a set of in vivo imaging markers that could establish tumour volume and a measure of BBB integrity.  PET was again used to analyse the ability of a 64Cu labelled bispecific antibody targeted hyperbranched polymer (HBP) 3 cross the BBB at different stages of GBM progression.  As expected, larger tumour volumes and a higher degree of leaky vasculature correlate with increased BBB permeability by the HBP.  This measure can be applied in the future to different sized nanoparticles and other materials to enable better development of BBB-penetrating nanocarriers.

References
(1)        Stringer, B. W.; Bunt, J.; Day, B. W.; Barry, G.; Jamieson, P. R.; Ensbey, K. S.; Bruce, Z. C.; Goasdoué, K.; Vidal, H.; Charmsaz, S.; Smith, F. M.; Cooper, L. T.; Piper, M.; Boyd, A. W.; Richards, L. J. Oncotarget 2016, 7, 29306–20.

(2)        Chow, L.; Endersby, R.; Zhu, X.; Rankin, S.; Qu, C.; Zhang, J.; Broniscer, A.; Ellison, D.; Baker, S. Cancer Cell 2011, 19, 305–316.

(3)        Howard, C. B.; Fletcher, N.; Houston, Z. H.; Fuchs, A. V.; Boase, N. R.; Simpson, J. D.; Raftery, L. J.; Ruder, T.; Jones, M. L.; de Bakker, C. J.; Mahler, S. M.; Thurecht, K. J. Adv Healthc Mater 2016.

Localised delivery of doxorubicin to prostate cancer cells through a PSMA-targeted hyperbranched polymer theranostic


Journal Article
Pearce, A. K. and Simpson, J. D. and Fletcher, N. L. and Houston, Z. H. and Fuchs, A. V. and Russell, P. J. and Whittaker, A. K. and Thurecht, K. J.
Biomaterials{booktitle}, 2017
Publication year: 2017

 

The therapeutic potential of hyperbranched polymers targeted to prostate cancer and loaded with doxorubicin was investigated. Polyethylene glycol hyperbranched polymers were synthesised via RAFT polymerisation to feature glutamate urea targeting ligands for PSMA on the periphery. The chemotherapeutic, doxorubicin, was attached to the hyperbranched polymers through hydrazone formation, which allowed controlled release of the drug from the polymers in vitro endosomal conditions, with 90% release of the drug over 36 h. The polymers were able to target to PSMA-expressing prostate cancer cells in vitro, and demonstrated comparable cytotoxicity to free doxorubicin. The ability of the hyperbranched polymers to specifically facilitate transport of loaded doxorubicin into the cells was confirmed using live cell confocal imaging, which demonstrated that the drug was able to travel with the polymer into cells by receptor mediated internalisation, and subsequently be released into the nucleus following hydrazone degradation. Finally, the ability of the complex to induce a therapeutic effect on prostate cancer cells was investigated through a long term tumour regression study, which confirmed that the DOX-loaded polymers were able to significantly reduce the volume of subcutaneous prostate tumours in vivo in comparison to free doxorubicin and a polymer control, with no adverse toxicity to the animals. This work therefore demonstrates the potential of a hyperbranched polymer system to be utilised for prostate cancer theranostics.

Gold Nanocluster-Mediated Cellular Death under Electromagnetic Radiation


Journal Article
Cifuentes-Rius, A. and Ivask, A. and Das, S. and Penya-Auladell, N. and Fabregas, L. and Fletcher, N. L. and Houston, Z. H. and Thurecht, K. J. and Voelcker, N. H.
ACS Appl Mater Interfaces{booktitle}, 2017
Publication year: 2017

Gold nanoclusters (Au NCs) have become a promising nanomaterial for cancer therapy because of their biocompatibility and fluorescent properties. In this study, the effect of ultrasmall protein-stabilized 2 nm Au NCs on six types of mammalian cells (fibroblasts, B-lymphocytes, glioblastoma, neuroblastoma, and two types of prostate cancer cells) under electromagnetic radiation is investigated. Cellular association of Au NCs in vitro is concentration-dependent, and Au NCs have low intrinsic toxicity. However, when Au NC-incubated cells are exposed to a 1 GHz electromagnetic field (microwave radiation), cell viability significantly decreases, thus demonstrating that Au NCs exhibit specific microwave-dependent cytotoxicity, likely resulting from localized heating. Upon i.v. injection in mice, Au NCs are still present at 24 h post administration. Considering the specific microwave-dependent cytotoxicity and low intrinsic toxicity, our work suggests the potential of Au NCs as effective and safe nanomedicines for cancer therapy.

A selective non-invasive 19F-MRI probe for the assessment of multidrug resistance

Posters
Zachary H. Houston, Kok-Siong S. Chen, Jens Bunt, Linda J. Richards, Kristofer J. Thurecht
Publication year: 2017

(Poster) 10th World Molecular Imaging Conference, Philadelphia, Pennsylvania, USA. 12th of September, 2017.

Background:  Nanomedicines have been shown to have great potential for the diagnosis and treatment of a variety of cancers, but their utility towards brain cancers has been limited due to the difficulty in penetrating the blood-brain barrier (BBB). Testing of these nanomedicines requires preclinical studies, but typically rely on orthotopic glioma models which disrupt the BBB in the process and are not indicative of human glioma. In order to create a preclinical method to assess nanomedicines which can be translated for use in the treatment of human brain cancer, we have utilised a mouse model with endogenous glioma formation. 1   Current clinical diagnosis of glioma makes use of dynamic contrast enhanced (DCE) magnetic resonance imaging (MRI), with positron emission tomography (PET) becoming more commonly used for validation as well. In order to improve the efficacy of nanomedicines in the treatment of brain cancer, establishment of a clinically translatable, preclinical technique for the analysis and refinement of nanomedicines is of significant need.

Hypothesis:  By using PET-MR to measure tumor volume, BBB integrity and the crossing of nanomedicines, a relationship between tumor progression and particle size can be made for the benchmarking and improvement of nanomedicines for the diagnosis and treatment of glioma.

Aims:  To create a suitable molecular imaging protocol using PET-MRI to measure the progression of glioma and then assess whether or not a nanomedicine could cross the BBB at each stage, validating with both live imaging and post-mortem analysis.

Results & Summary:  A series of pre- and post-contrast enhanced MRI were used at various time points across the development of the glioma to measure the volume of the tumor and a DCE-MRI sequence was run to analyze the leakiness of the BBB. [18F]-fluoro-dopamine (18FDOPA), an established radiotracer for glioma detection, was co-injected at time points where the tumor was known to be visible with MRI to validate the presence and volume of the tumor. A precise region of interest (ROI) for the tumor was made from the contrast enhanced MR image utilizing a random walker algorithm, and was validated with a similar technique off the 18F-PET image. Leakiness of the BBB was assessed by measuring the uptake of Gadovist® at multiple time points for the tumour and fitting an equation to give a two-parameter measure for the maximum extent and rate of leakiness. A 64Cu labelled, antibody targeted nanomedicine was then injected at key time points, allowed to circulate for 18-24 hours, and the uptake into the tumor was measured. The nanomedicines were observed only to cross at time points in the late terminal stage of the cancer, but not at earlier stages.  The work presented herein serves as a proof-of-concept that can be used to test a variety of nanomedicines of different shape, size, and charge to allow the further development of BBB permeable nanomedicines.

References:
(1)       Chow, L.; Endersby, R.; Zhu, X.; Rankin, S.; Qu, C.; Zhang, J.; Broniscer, A.; Ellison, D.; Baker, S. Cancer Cell 2011, 19, 305–316.

A preclinical in vivo imaging model to monitor tumour progression and nanomedicine efficacy for glioma

Abstract Reviewed Presentations
Zachary H. Houston, Jens Bunt, Linda J. Richards, Kristofer J. Thurecht
Publication year: 2017

International Conference on BioNano Innovation, Brisbane, Australia, 27th of September, 2017.

Nanomaterials come in a plethora of designs, shapes, chemical formulations, sizes, and ionic forms and can be readily tuned to surpass many of the biological barriers within the body, but have had limited success in surpassing the final frontier of barriers: the blood-brain barrier (BBB). Herein we report the use of simultaneous PET-MRI to develop a toolkit for monitoring tumour progression and its effect on BBB integrity of a spontaneous transgenic glioma model1,2, for the purpose of establishing when the BBB is compromised enough for nanoparticles to cross.  A series of T1, T2, and dynamic contrast enhanced MRI images along with simultaneous PET of 18FDOPA were used to devise a set of in vivo imaging markers that could establish tumour volume and a measure of BBB integrity.  PET was again used to analyse the ability of a 64Cu labelled bispecific antibody targeted hyperbranched polymer (HBP) 3 cross the BBB at different stages of GBM progression.  As expected, larger tumour volumes and a higher degree of leaky vasculature correlate with increased BBB permeability by the HBP.  This measure can be applied in the future to different sized nanoparticles and other materials to enable better development of BBB-penetrating nanocarriers.

 

References
(1)        Stringer, B. W.; Bunt, J.; Day, B. W.; Barry, G.; Jamieson, P. R.; Ensbey, K. S.; Bruce, Z. C.; Goasdoué, K.; Vidal, H.; Charmsaz, S.; Smith, F. M.; Cooper, L. T.; Piper, M.; Boyd, A. W.; Richards, L. J. Oncotarget 2016, 7, 29306–20.

(2)        Chow, L.; Endersby, R.; Zhu, X.; Rankin, S.; Qu, C.; Zhang, J.; Broniscer, A.; Ellison, D.; Baker, S. Cancer Cell 2011, 19, 305–316.

(3)        Howard, C. B.; Fletcher, N.; Houston, Z. H.; Fuchs, A. V.; Boase, N. R.; Simpson, J. D.; Raftery, L. J.; Ruder, T.; Jones, M. L.; de Bakker, C. J.; Mahler, S. M.; Thurecht, K. J. Adv Healthc Mater 2016.

The tumour microenvironment and approaches to promote tumour delivery

Invited Presentations
Publication year: 2016

(Invited Lecture) Crossing Biological Barriers Workshop, Australian Controlled Release Society – Melbourne, Victoria, Australia.

A 40 minute lecture was given on the theory and application of delivering nanomaterials to a tumour and how they behave in the tumour microenvironment.

Overcoming Instability of Antibody-Nanomaterial Conjugates: Next Generation Targeted Nanomedicines Using Bispecific Antibodies


Journal Article
Howard, C. B. and Fletcher, N. and Houston, Z. H. and Fuchs, A. V. and Boase, N. R. and Simpson, J. D. and Raftery, L. J. and Ruder, T. and Jones, M. L. and de Bakker, C. J. and Mahler, S. M. and Thurecht, K. J.
Adv Healthc Mater{booktitle}, 2016
Publication year: 2016

 

Targeted nanomaterials promise improved therapeutic efficacy, however their application in nanomedicine is limited due to complexities associ-ated with protein conjugations to synthetic nanocarriers. A facile method to generate actively targeted nanomaterials is developed and exemplified using polyethylene glycol (PEG)-functional nanostructures coupled to a bispecific antibody (BsAb) with dual specificity for methoxy PEG (mPEG) epitopes and cancer targets such as epidermal growth factor receptor (EGFR). The EGFR-mPEG BsAb binds with high affinity to recombinant EGFR (KD: 1 × 10–9 M) and hyperbranched polymer (HBP) consisting of mPEG (KD: 10 × 10–9 M) and demonstrates higher avidity for HBP compared to linear mPEG. The binding of BsAb-HBP bioconjugate to EGFR on MDA-MB-468 cancer cells is investigated in vitro using a fluorescently labeled polymer, and in in vivo xenograft models by small animal optical imaging. The antibody-targeted nanostructures show improved accumulation in tumor cells compared to non-targeted nanomaterials. This demonstrates a facile approach for tuning targeting ligand density on nanomaterials, by modulating surface functionality. Antibody fragments are tethered to the nanomaterial through simple mixing prior to administration to animals, overcoming the extensive procedures encountered for developing targeted nanomedicines.

A versatile and facile active targeting method for in vivo tumour targeting

Abstract Reviewed Presentations
Zachary H. Houston, Nicholas L. Fletcher, Christopher B. Howard, Kristofer J. Thurecht
Publication year: 2016

International Nanomedicine Conference – Coogee, New South Wales, Australia.

Advances in materials synthesis have allowed for a multitude of well-defined biocompatible and stealthy nanoparticles of varying shape and size. For the treatment and diagnosis of cancer, these particles are often developed to exploit the enhanced permeability and retention (EPR) effect, but have limited in vivo efficacy due to their poor retention in tumour tissue. Addition of active targeting ligands with strong binding potentials to membrane receptors uniquely present on malignant cells have shown significant promise towards increasing the retention of nanoparticles in vivo. Many targeting vectors have been explored with some of the most promising types being antibodies; however, conjugation of these antibodies to the nanoparticles (NPs) using traditional chemistries is challenging and conditions can easily change per system. An ideal targeting system would be applicable to multiple types of NPs using a singular conjugation methodology. Recently, we have reported on the preparation of a bispecific antibody (BsAb) that has strong binding to VEGF receptors commonly overexpressed on cancer cells, and at its distal end an antibody specific towards methyl-terminated poly(ethyelene) glycol (PEG).1 Herein we report the utility of this targeting method (Figure 1) toward the development of new diagnostic and therapeutic nanoparticles in murine models. Hyperbranched NPs constructed of methyl terminated PEG have been previously reported by us2 and were used to test the in vivo stability and efficacy of the targeting system.  The prepared BsAbs were conjugated to the fluorescently labelled NPs via a short incubation procedure and subsequently injected intravenously into tumour bearing mice.  The accumulation of the particle was observed over several time points and ex vivo analysis was performed to validate the biodistribution observed in vivo.  The BsAb targeted NPs were found to show higher accumulation in the tumour compared to the off-target control (EphA2), and provide a promising and versatile targeting methodology for the investigation and treatment of tumours.

 

References

  1. B. Howard, et al., Advanced Healthcare Materials, Accepted. (DOI: 10.1002/adhm.201600263R1)
  2. V. Fuchs, et al., Biomacromolecules, 2015, 16(10), 3235-3247.

A facile method for assessing tumour targeting efficiency with PET-CT

Abstract Reviewed Presentations
Zachary H. Houston, Nicholas L. Fletcher, Christopher B. Howard, Kristofer J. Thurecht
Publication year: 2016

The Centre for Advanced Imaging 3rd Annual Symposium, 19th of October, 2016.

Advances in materials synthesis have allowed for a multitude of well-defined biocompatible and stealthy nanoparticles of varying shape and size. For the treatment and diagnosis of cancer, these particles are often developed to exploit the enhanced permeability and retention (EPR) effect, but have limited in vivo efficacy due to their poor retention in tumour tissue. Addition of active targeting ligands with strong binding potentials to membrane receptors uniquely present on malignant cells have shown significant promise towards increasing the retention of nanoparticles in vivo. Many targeting vectors have been explored with some of the most promising types being antibodies; however, conjugation of these antibodies to the nanoparticles (NPs) using traditional chemistries is challenging and conditions can easily change per system. An ideal targeting system would be applicable to multiple types of NPs using a singular conjugation methodology. Recently, we have reported on the preparation of a bispecific antibody (BsAb) that has strong binding to VEGF receptors commonly overexpressed on cancer cells, and at its distal end an antibody specific towards methyl-terminated poly(ethyelene) glycol (PEG).1 Herein we report the utility of this targeting method (Figure 1) toward the development of new diagnostic and therapeutic nanoparticles in murine models. Hyperbranched NPs constructed of methyl terminated PEG have been previously reported by us2 and were used in this study to test the in vivo stability and efficacy of the targeting system in multiple tumour models.  The prepared BsAbs were conjugated to the radiolabelled NPs via a short incubation procedure and subsequently injected intravenously in two sets of Balb/c nude mice bearing either subcutaneous or xenograft tumours.  The biodistribution and tumour accumulation of the NPs were observed over several time points in vivo and ex vivo.  The BsAb targeted NPs were found to show higher accumulation in the tumour compared to the off-target control, and provide a promising and versatile targeting methodology for the investigation and treatment of tumours.

References:

  1. C.B. Howard, et al., Advanced Healthcare Materials, Accepted. (DOI: 10.1002/adhm.201600263R1)
  2. A.V. Fuchs, et al., Biomacromolecules, 2015, 16(10), 3235-3247.

Stimuli responsive switch modulated by 19F- and 1H-MRI gadolinium contrast

Abstract Reviewed Presentations
Zachary H. Houston, Kristofer J. Thurecht
Publication year: 2015

35th Australasian Polymer Symposium, Gold Coast, Queensland, Australia.

Fluorine-19 has become a nuclei of interest for MRI due to a 100% natural abundance, zero background in vivo, and a high nuclear magnetic resonance sensitivity. Its poor sensitivity in vivo, however; is a main hurdle for its effective use in clinical systems requiring highly fluorinated species to obtain a signal. Hyperbranched polymers provide a biocompatible and customisable platform for selectively localising polyfluorinated 19F-MRI agents and have been shown to be successful in a myriad of applications, both by us1 and others2. The use of gadolinium for contrast enhancement has also been shown to significantly shorten the T1 and T2 relaxation times of not only 1H but 19F nuclei as well.2–4 By combining these two techniques we report a gadolinium enhanced polyfluorinated stimuli responsive hyperbranched polymer capable of changing its 19F and 1H contrast upon action by external stimuli. To test this method a disulphide bond was utilized as it is well known to cleave in the presence of glutathione, an antioxidant upregulated in tumour cells. Upon release of the DOTA-Gd complex the 19F-MR signal intensity increases, thus creating an on/off switch that is dependent upon successful tumour cell internalization.

 

References:
1 Thurecht, K. J.; Blakey, I.; Peng, H.; Squires, O.; Hsu, S.; Alexander, C.; Whittaker, A. K. J. Am. Chem. Soc. 2010, 132, 5336–5337.
2 Li, Y.; Laurent, S.; Esser, L.; Elst, L. Vander; Muller, R. N.; Lowe, A. B.; Boyer, C.; Davis, T. P. Polym. Chem. 2014, 5, 2592.
3 De Vries, A.; Moonen, R.; Yildirim, M.; Langereis, S.; Lamerichs, R.; Pikkemaat, J. a; Baroni, S.; Terreno, E.; Nicolay, K.; Strijkers, G. J.; Grüll, H. Contrast Media Mol. Imaging 2014, 9, 83–91.
4 Ratner, a V; Quay, S.; Muller, H. H.; Simpson, B. B.; Hurd, R.; Young, S. W. 19F relaxation rate enhancement and frequency shift with Gd-DTPA. Investigative radiology, 1989, 24, 224–227.

Polymeric 19F-MRI switchable probes

Abstract Reviewed Presentations
Zachary H. Houston, Kristofer J. Thurecht
Publication year: 2015

Convergent Bio-Nano Science and Technology Workshop, Lorne, Victoria, Australia.

An abstract was not submitted for this presentation, but was on the same research project as presented at another conference this same year. The text for this abstract is below:

19F-MRI offers a unique diagnostic platform with minimal endogenous background signal in vivo and increased sensitivity.  Consequently, a targeted polyfluorinated contrast enhancement agent would be of significant benefit to clinicians for the diagnosis of a variety of diseases.  This report describes the synthesis of a hyperbranched 19F-MRI contrast enhanced polymer that was targeted towards a variety of carcinomas, and is “switched on” in cancerous tissue via a stimuli-responsive linker. A Gd3+ bound DOTA chelator connected via a cleavable disulfide linker was incorporated into the polymer.  While bound, the T2 of 19F remained too short to detect; but when cleaved by glutathione the 19F signal was observed, as the Gd3+ was no longer in close enough proximity to elicit a relaxation effect.  The T1 and T2s of both 1H and 19F were measured for the polymer in varying concentrations of glutathione to illustrate this concept, yielding promising results.

Development of a tumor microenvironment responsive 19F-MRI nanoprobe

Abstract Reviewed Presentations
Zachary H. Houston, Kristofer J. Thurecht
Publication year: 2015

14th Pacific Polymer Conference – Kauai, Hawaii, USA.

19F-MRI offers a unique diagnostic platform with minimal endogenous background signal in vivo and increased sensitivity.  Consequently, a targeted polyfluorinated contrast enhancement agent would be of significant benefit to clinicians for the diagnosis of a variety of diseases.  This report describes the synthesis of a hyperbranched 19F-MRI contrast enhanced polymer that was targeted towards a variety of carcinomas, and is “switched on” in cancerous tissue via a stimuli-responsive linker. A Gd3+ bound DOTA chelator connected via a cleavable disulfide linker was incorporated into the polymer.  While bound, the T2 of 19F remained too short to detect; but when cleaved by glutathione the 19F signal was observed, as the Gd3+ was no longer in close enough proximity to elicit a relaxation effect.  The T1 and T2s of both 1H and 19F were measured for the polymer in varying concentrations of glutathione to illustrate this concept, yielding promising results.

Design and development of a polyhedral borane drug delivery system for the small-molecule antimetabolite 5-fluorouracil||Design and development of a polyhedral borane drug delivery system for the small-molecule antimetabolite 5-fluorouracil


Thesis
Houston and Zachary, H.
{journal}{booktitle}, 2014
Publication year: 2014
Polyhedral boranes represent a unique class of molecules that have been exploited for a variety of applications. Their unique bonding provides a novel scaffold for polyfunctionalized and dendrimer-like drug delivery vehicles. In particular, the closed-cage icosahedral closo-B12H122- has been the interest of extensive study and a multitude of applications. The 12-vertexes on the closo-B12H22- structure and its established chemistry for functionalization have allowed the development of more complex and higher molecular weight multimeric species. These 12-fold substituted polyhedral boranes, known as closomers, have been studied with respect to their chemistry and properties and are now being exploited for their use in medicinal applications. With the previously reported high-yielding synthesis of the perhydroxylated species [closo-B12(OH)12]2-, a plethora of complexes have been prepared through the exploitation of the similar reactivity of the B-OH and C-OH bond. Through the use of ester, ether, carbonate, carbamate, and Huisgen [3+2] dipolar cycloaddition reactions, a well-established library of closomers has been prepared and has established the chemistry needed for the development of medically applicable systems. The use of these established methods has been expanded upon herein to create vertex-differentiated and 12-fold homofunctionlaized closomer compounds. Furthermore, as a requisite to building higher-order closomers, an extensive library of heterofunctionalized poly(ethylene glycol) compounds have been prepared. In the work reported herein, the homo- and heterofunctionalization of closomers is discussed leading to the synthesis of a 12-fold 5-fluorouracil loaded and glucosamine targeted closomer drug delivery system.

Efficient synthesis of diverse heterobifunctionalized clickable oligo(ethylene glycol) linkers: potential applications in bioconjugation and targeted drug delivery


Journal Article
Goswami, L. N. and Houston, Z. H. and Sarma, S. J. and Jalisatgi, S. S. and Hawthorne, M. F.
Org Biomol Chem{booktitle}, 2013
Publication year: 2013

 

Herein we describe the sequential synthesis of a variety of azide-alkyne click chemistry-compatible heterobifunctional oligo(ethylene glycol) (OEG) linkers for bioconjugation chemistry applications. Synthesis of these bioorthogonal linkers was accomplished through desymmetrization of OEGs by conversion of one of the hydroxyl groups to either an alkyne or azido functionality. The remaining distal hydroxyl group on the OEGs was activated by either a 4-nitrophenyl carbonate or a mesylate (-OMs) group. The -OMs functional group served as a useful precursor to form a variety of heterobifunctionalized OEG linkers containing different highly reactive end groups, e.g., iodo, -NH2, -SH and maleimido, that were orthogonal to the alkyne or azido functional group. Also, the alkyne- and azide-terminated OEGs are useful for generating larger discrete poly(ethylene glycol) (PEG) linkers (e.g., PEG 16 and PEG24) by employing a Cu(i)-catalyzed 1,3-dipolar cycloaddition click reaction. The utility of these clickable heterobifunctional OEGs in bioconjugation chemistry was demonstrated by attachment of the integrin (αvβ3) receptor targeting peptide, cyclo-(Arg-Gly-Asp-d-Phe-Lys) (cRGfKD) and to the fluorescent probe sulfo-rhodamine B. The synthetic methodology presented herein is suitable for the large scale production of several novel heterobifunctionalized OEGs from readily available and inexpensive starting materials.

Current Research at the International Institute of Nano & Molecular Medicine

Posters
Zachary H. Houston, Shatadru Chakravarty, M.F. Hawthorne
Publication year: 2013

(Poster) Nano Frontiers Symposium – Columbia, Missouri, USA.

An overview of the major research projects at the International Institute of Nano & Molecular Medicine was given.

Synthesis of vertex-differentiated icosahedral closo-boranes: polyfunctional scaffolds for targeted drug delivery


Journal Article
Goswami, L. N. and Houston, Z. H. and Sarma, S. J. and Li, H. and Jalisatgi, S. S. and Hawthorne, M. F.
J Org Chem{booktitle}, 2012
Publication year: 2012

 

We report methods for the synthesis of vertex-differentiated icosahedral closo-boranes. A single B-OH vertex of the icosahedral borane [closo-B 12(OH)12]2- was derivatized to prepare [closo-B12(OR)(OH)11]2- using optimized alkylation conditions and purification procedures. Several representative vertex-differentiated icosahedral closo-boranes were prepared utilizing carbonate ester and azide-alkyne click chemistries on the surface of the closo-B12 2- core.

A convenient route to diversely substituted icosahedral closomer nanoscaffolds


Journal Article
Jalisatgi, S. S. and Kulkarni, V. S. and Tang, B. and Houston, Z. H. and Lee, M. W., Jr. and Hawthorne, M. F.
J Am Chem Soc{booktitle}, 2011
Publication year: 2011

 

The design and synthesis of icosahedral polyhedral borane closomer motifs based upon carbonate and carbamate anchoring groups for biomedical applications are described. Dodecacarbamate closomers containing easily accessible groups of interest at their linker termini were synthesized via activation of the B-OH vertices as aryl carbonates and their subsequent reaction with primary amines. Novel dodecacarbonate closomers were successfully synthesized for the first time by reacting [closo-B 12(OH) 12] 2- with an excess of respective aryl chloroformates, utilizing relatively short reaction times, mild conditions and simple purification strategies, all of which had previously presented difficulties in closomer chemistry. This methodology for the 12-fold degenerate synthesis of carbonate and carbamate closomers will greatly facilitate further exploration of closomers as monodisperse nanomolecular delivery platforms.

Targeted Delivery of Multifunctional Nanomolecular Drug Systems

Posters
Zachary H. Houston
Publication year: 2010

(Poster) Nano Frontiers Symposium – Columbia, Missouri, USA.

An overview of targeted polyhedral borane scaffolds was shown.

Hydrolytic Stability of Carbamate and Carbonate Closomers for the Design of a Multifaceted Drug Delivery System

Thesis
Houston, Zachary H.
University of Missouri, 2010
Publication year: 2010

 

Twelve-fold substituted polyhedral boranes (closomers) are of therapeutic and diagnostic interest in the applications of targeted drug delivery. These compounds consist of a core molecule with 12 vertices and allow for a high degree of multifaceted substitution. Our group has previously reported on ester and ether based closomers1, but more recently have been working with the more synthetically useful carbonate and carbamate based closomers. The solution based properties of these structures their relative stability towards acid and base hydrolysis were investigated for the purpose of determining the best structural design for drug delivery applications. Some of the these molecules have limited solubility in aqueous media, and thus a system for analyzing these compounds with accurate pH monitoring using a glass electrode was established using IUPAC standards.2 The devised system is applicable to any organic-aqueous solvent mixture, and can be applied with any standard glass electrode that is primarily utilized for aqueous conditions. The system corrects for any solvent effects due to the presence of the organic component by the utilization of the Debye-Huckel Extended Law. Preliminary studies show that the carbonate and carbamate bond at the polyhedral borane cage are hydrolytically stable in the pH 2-12 range. The stability of these core structures allows for a potentially much more tunable release system in drug delivery applications, and solidifies the use of carbamate based systems for selective release of the pharmaceutical payload.

Use of hydrogen plasma for storing hydrogen in nanophase diamond powder

Conference Proceedings
Houston, Z. and Ghosh, T. K. and of the Nuclear, Prelas - M. A.
{journal}Transactions of the American Nuclear Society, {year}
Publication year: 2005

Innovation in diagnosis and treatment of brain metastases using multifunctional nanomedicines


Conference Proceedings
Saunus, J. M. and Lim, M. and Puttick, S. and Croft, Kalita-de P. and Houston, Z. H. and Jones, M. L. and Latter, M. J. and Campbell, L. C. and Thomas, P. and Jeffree, R. L. and Rose, S. E. and Mahler and Thurecht, K. J. and Scott, A. M. and Lakhani, S. R.
{journal}American Association for Cancer Research, {year}
Publication year: 1950

 

Systemic therapies have limited efficacy against brain metastases, largely because passive delivery of naked compounds via the bloodstream does not achieve sufficiently high or evenly dispersed intratumoural concentrations. Heterogeneous tissue architecture, abnormal perfusion, hypoxic zones and high interstitial fluid pressure are key factors limiting drug delivery, compounded by patchy blood-tumour-barrier permeability. Also, brain metastases are usually detected late, once patients become symptomatic. We are investigating whether engineered biopharmaceuticals might improve diagnostic sensitivity for earlier detection, as well as therapeutic efficacy and side-effect profiles of existing agents through active tumour targeting, delayed clearance and microenvironment-mediated activation. This study is proceeding with parallel preclinical and clinical tracks.

Preclinical aims: (1) Develop and characterise monoclonal antibody (mAb) fragments (scFvs) that target the brain metastasis markers HER2 and HER3; (2) Functionalise polyethylene glycol (PEG)-based nanocarriers with the scFvs, along with imaging agents to facilitate in vivo and ex vivo analysis of tissue distribution; (3) Functionalise HER2/3-targeted carriers with doxorubicin via an acid-labile hydrazone bond for release in hypoxic environments, or the endosome compartment after internalization. Results to date. His-tagged HER2- and HER3-targeted scFvs based on ligand-binding sequences of clinically-approved mAbs were expressed and purified from Expi293 suspension cultures. Binding affinities are an order of magnitude stronger than parent mAbs (KD 2-8x10E-11M), determined using surface plasmon resonance analysis. The scFvs are cytostatic and moderately cytotoxic in vitro, with IC50s in order of 0.4-1.0μM. HER2 and HER3 scFvs exhibited dose-dependent, additive growth inhibition when used in combination, and induced internalisation of their receptor ligands within 4 hours in SKBr3 cells. Conclusions.The scFvs are strong carrier-tethering candidates in terms of both extracellular and intracellular payload release. Carrier synthesis is currently underway and preliminary in vivo data will be presented.

Clinical aims: (1) Develop and characterise 89Zirconium-labelled HER2-targeted PET tracers based on parent mAb and scFv; (2) Compare uptake and retention of the tracers in breast cancer patients with brain metastases; (3) Computationally relate tumour uptake to the administered dose, perfusion, tumour size and HER2 expression; (4) Determine the uptake range within and between patients, and the minimum size for reliable detection. Results to date. The mAb tracer has been synthesised, characterised and labelling processes scaled for clinical production. It is stable in physiologic conditions, retains HER2-binding activity and has a favourable biodistribution profile in NOD-SCID mice bearing BT474 xenografts. Conclusions. Australian regulatory approvals are in place and recruitment for the mAb imaging trial (“BoNSAI”) has begun. Preliminary data will be presented.

Evaluation of the in vivo fate of ultrapure alginate in mice model


Conference Proceedings
A, Anitha and Nicholas, Fletcher and Zachary, Houston and Kristofer, Thurecht and Lisbeth, Grondahl
{journal}Frontiers in Bioengineering and Biotechnology, {year}
Publication year: 1950

 

Evaluation of the in vivo fate of ultrapure alginate in mice model Introduction: Alginate is an anionic co-polymer composed of (1, 4)-linked β-D-mannuronate (M) and α-L-guluronate (G) residues and is sourced from nature (eg. seaweed)[1]. This polymer has been comprehensively studied for use in various biomedical applications because of its reported biocompatibility, non-toxicity and mild gelation property[2],[3]. Mammals lack the enzyme alginase which is required for the biodegradation of the polymer chains of alginate[4]; however, thus far only one study has investigated the bio-distribution profile of radiolabeled chemically modified alginate (propylene glycol alginate-tyrosinamide)[2]. This study showed that the in vivo fate of modified alginate following systemic administration is dependent on the molecular weight and the higher molecular weight (> 48000 g/mol) alginate fragments remained in circulation with no significant accumulation in organs until 48 hours[3]. The lack of a bio-distribution study on pure alginate and of studies involving prolonged time points on the biodistribution profile of alginate-based polymers in general is a clear knowledge gap in the literature, as this information is crucial for alginate to be used in biomedical applications. Thus the present study which investigates the bio-distribution of cyanine 5-amine conjugated ultrapure alginate is highly topical. Materials and Methods: High purity alginate from FMC BioPolymer was conjugated with cyanine 5-amine using carbodiimide chemistry at a loading of 14 mg cyanine 5-amine/g alginate-dye conjugate. This polymer was administered to Balb/c mice through the tail vein, and imaged using a dual fluorescent X-ray imaging system (Bruker MsFx pro) at 1 hour, 2 hour, 1 day, and 2 days post sample administration under isoflurane anesthesia. At each time point, subsets of animals were euthanized and the organs (spleen, liver, heart, lungs, brain and kidney) were harvested for ex vivo imaging and flow cytometry analysis. Cyanine 5-amine was used as a control. Results and Discussion: From the imaging results at 1st hour, a rapid clearance of some of the alginate through the kidneys (e.g. smaller molecular weight alginate fragments) and liver (e.g. molecular weight alginate fragments) could be observed. Conclusion: The results of this in vivo biodistribution study will form the foundation for future research in the translation of alginate-based materials into different applications such as drug delivery, tissue engineering and wound healing. One of the authors A. Anitha is grateful to The University of Queensland, Australia for providing a postdoctoral research fellowship for carrying out this research work.

References:

[1] Lee KY; Mooney DJ (2012) ProgPolym Sci 37, 106.

[2] Al-Shamkhani A; Duncan R (1995) J Bioactive Compatible Polym 10, 4.

[3] Kolambkar YM et al (2011) Biomaterials 32, 65. [4] Kuo CK; Ma PX (2011) Biomaterials 22, 511.

Development of polymeric MRI agents as theranostics

Conference Proceedings
Thurecht, Kristofer and Fuchs, Adrian V and Bapat, Abhijeet and Houston, Zachary
{journal}255th ACS National Meeting, {year}
Publication year: 1950

 

Development of sensitive molecular imaging agents is one of the major challenges for advancing targeted imaging using MRI. The development of imaging agents that can be directly imaged using MRI holds particular interest since these have the potential to increase sensitivity while being able to directly probe a reaction or process that occurs in vivo. In general, directly observable MR probes are very sensitive to their local environment and as such, can be manipulated as switchable agents in response to a number of endogenous or exogenous stimuli.

In this presentation we report on the development of sensitive hyperbranched polymeric 19F MRI contrast agents that combine controllable functionality, ability for cell-targeting in vivo and low cytotoxicity. More importantly, owing to the strong dependence of the 19F MR properties on the local environment, such systems are amenable to the development of responsive probes that give real-time assessment of biological function. We demonstrate this effect with some examples of systems that show a change in signal intensity based on its location in the body. Finally, the application of 19F MRI as a means to potentially quantify drug delivery in vivo is discussed, with an example that highlights the potential of this technique, but also the challenges that remain.

Development of polymer theranostics to probe the behaviour of nanomaterials in biology

Conference Proceedings
Thurecht, Kristofer and Zhao, Yongmei and Fletcher, Nicholas and Houston, Zachary
{journal}255th ACS National Meeting, {year}
Publication year: 1950

 

Polymer and nanoparticle-based devices have evolved to significantly enhance therapeutic efficacy. However, in order to be truly effective, these polymeric devices must maintain their physical and chemical integrity under physiological conditions this can only be achieved by developing a strong understanding of the fundamental properties of the nanomaterial-delivery system, in addition to identifying and successfully delivering new therapies. Central to the development of these future therapeutic platforms, is the field of theranostics. This is the premise that future medical devices need to be capable of delivering a therapeutic dose to the correct site within the body, but must also possess mechanisms for online diagnosis, monitoring of disease progression and visualisation of drug delivery, release and efficacy of treatment. Such materials require significant advancements in chemistry, materials science and engineering such that the nanomedicine is complementary with the biological milieu.

While there are countless examples of polymer or nanoparticle systems that show efficacy in animal models, the ability to rationally-optimise the materials is hindered by the inability to directly assess the behaviour of the materials in vivo. For example, improvements in administration for most biologically-targeted polymeric nanomaterial systems are achieved by monitoring efficacy in animals rather than monitoring the fundamental behaviour of the nanomaterial itself (e.g. measuring efficacy, rather than quantifying how a change in material properties results in a biological response). In this presentation, we describe recent efforts to develop self-reporting nanomedicines for a truly closed-loop approach to medicine, where nanomaterial behaviour is monitored in real-time using molecular imaging as a function of therapy. These materials are based on architectural polymers that form a scaffold allowing combination of imaging and therapeutic modalities. Molecular imaging provides a route to validate how structure and property affects function in animals.

Design-led 3D visualization of nanomedicines in virtual reality


Conference Proceedings
Lilja, Andrew R. and Strong, Campbell W. and Bailey, Benjamin J. and Thurecht, Kristofer J. and Houston, Zachary H. and Fletcher, Nicholas L. and McGhee, John B.
{journal}Design-led 3D visualization of nanomedicines in virtual reality, {year}
Publication year: 1950

 

Nanomedicines are a promising addition to the arsenal of new cancer therapies. During development, scientists must precisely track their distribution in the body, a task that can be severely limited by traditional 2D displays. With its stereoscopic capacity and real-time interactivity, virtual reality (VR) provides an encouraging platform to accurately visualize dynamic 3D volumetric data. In this research, we develop a prototype application to track nanomedicines in VR. This platform has the potential to enhance data assessment, comprehension and communication in preclinical research which may ultimately influence the paradigm of future clinical protocols.