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4. Passerini chemistries for synthesis of polymer pro-drug and polymersome drug delivery nanoparticles

Author

Travanut, Alessandra, Smith, Sean, Howdle, Steven M., Grabowska, Anna M., Kellam, Barrie, Meier, Michael A.R., and Alexander, Cameron

Subjects
Biomedical Engineering, General Materials Science, General Chemistry, General Medicine
Abstract

New materials chemistries are urgently needed to overcome the limitations of existing biomedical materials in terms of preparation, functionality and versatility, and also in regards to their compatibility with biological environments. Here, we show that Passerini reactions are especially suited for the preparation of drug delivery materials, as with relatively few steps, polymers can be synthesized with functionality installed enabling drug conjugation and encapsulation, self-assembly into micellar or vesicular architectures, and with facile attachment triggerable chemistries. The polymers can be made with a variety of building blocks and assemble into nanoparticles, which are rapidly internalized in triple negative breast cancer (TNBC) cells. In addition, the polymers transport drug molecules efficiently through 3D cell cultures, and when designed with chemistries allowing pH-mediated release, exhibit greater efficacy against TNBC cells compared to the parent drug.

Published
2022

5. Reduction-responsive polymers for drug delivery in cancer therapy—Is there anything new to discover?

Author

Alexander, Cameron, Conte, Claudia, and Travanut, Alessandra

Subjects
nanomedicine, 2013, Reduction-responsive polymers, micelles, tumour, redox- responsive nanoparticles, Steghens, Flourié, Arab, & Collombel, 2003), drug delivery system, cancer nanotechnology, glutathione, stimuli-responsive, disulfide
Abstract

© 2020 The Authors. WIREs Nanomedicine and Nanobiotechnology published by Wiley Periodicals LLC. Among various types of stimuli-responsive drug delivery systems, reduction-responsive polymers have attracted great interest. In general, these systems have high stability in systemic circulation, however, they can respond quickly to differences in the concentrations of reducing species in specific physiological sites associated with a pathology. This is a particularly relevant strategy to target diseases in which hypoxic regions are present, as polymers which are sensitive to in-situ expressed antioxidant species can, through a local response, release a therapeutic at high concentration in the targeted site, and thus, improve the selectivity and efficacy of the treatment. At the same time, such reduction-responsive materials can also decrease the toxicity and side effects of certain drugs. To date, polymers containing disulfide linkages are the most investigated of the class of reduction-responsive nanocarriers, however, other groups such as selenide and diselenide have also been used for the same purpose. In this review article, we discussed the rationale behind the development of reduction-responsive polymers as drug delivery systems and highlight examples of recent progress. We include the most popular design methods to generate reduction-responsive polymeric carriers and their applications in cancer therapy, and question what areas may still need to be explored in a field with already a very large number of research articles. Finally, we consider the main challenges associated with the clinical translation of these nanocarriers and the future perspectives in this area. This article is categorized under: Therapeutic Approaches and Drug Discovery > Nanomedicine for Oncologic Disease Nanotechnology Approaches to Biology > Nanoscale Systems in Biology Therapeutic Approaches and Drug Discovery > Emerging Technologies.

Published
2021

6. Synthesis of Passerini-3CR Polymers and Assembly into Cytocompatible Polymersomes

Author

Travanut, Alessandra, Oelmann, Stefan, Howdle, Steven M., Grabowska, Anna M., Clarke, Philip A., Ritchie, Alison A., Meier, Michael A.R., and Alexander, Cameron

Abstract

© 2020 The Authors. Published by Wiley-VCH GmbH The versatility of the Passerini three component reaction (Passerini-3CR) is herein exploited for the synthesis of an amphiphilic diblock copolymer, which self-assembles into polymersomes. Carboxy-functionalized poly(ethylene glycol) methyl ether is reacted with AB-type bifunctional monomers and tert-butyl isocyanide in a single process via Passerini-3CR. The resultant diblock copolymer (P1) is obtained in good yield and molar mass dispersity and is well tolerated in model cell lines. The Passerini-3CR versatility and reproducibility are shown by the synthesis of P2, P3, and P4 copolymers. The ability of the Passerini P1 polymersomes to incorporate hydrophilic molecules is verified by loading doxorubicin hydrochloride in P1DOX polymersomes. The flexibility of the synthesis is further demonstrated by simple post-functionalization with a dye, Cyanine-5 (Cy5). The obtained P1-Cy5 polymersomes rapidly internalize in 2D cell monolayers and penetrate deep into 3D spheroids of MDA-MB-231 triple-negative breast cancer cells. P1-Cy5 polymersomes injected systemically in healthy mice are well tolerated and no visible adverse effects are seen under the conditions tested. These data demonstrate that new, biodegradable, biocompatible polymersomes having properties suitable for future use in drug delivery can be easily synthesized by the Passerini-3CR.

Published
2021

7. Synthesis of micellar-like terpolymer nanoparticles with reductively-cleavable cross-links and evaluation of efficacy in 2D and 3D models of triple negative breast cancer

Author

Gulfam, Muhammad, Travanut, Alessandra, Abelha, Thais Fedatto, Pearce, Amanda K., Grabowska, Anna M., Clarke, Philip A., Collins, Hilary M., Heery, David M., Gershkovich, Pavel, and Alexander, Cameron

Subjects
Pharmaceutical Science
Abstract

© 2020 Elsevier B.V. Triple negative or basal-like breast cancer (TNBC) is characterised by aggressive progression, lack of standard therapies and poorer overall survival rates for patients. The bad prognosis, high rate of relapse and resistance against anticancer drugs have been associated with a highly abnormal loss of redox control in TNBC cells. Here, we developed docetaxel (DTX)-loaded micellar-like nanoparticles (MLNPs), designed to address the aberrant TNBC biology through the placement of redox responsive cross-links designed into a terpolymer. The MLNPs were derived from poly(ethyleneglycol)-b-poly(lactide)-co-poly(N3-α-ε-caprolactone) with a disulfide linker pendant from the caprolactone regions in order to cross-link adjacent chains. The terpolymer contained both polylactide and polycaprolactone to provide a balance of accessibility to reductive agents necessary to ensure stability in transit, but rapid micellar breakdown and concomitant drug release, when in breast cancer cells with increased levels of reducing agents. The empty MLNPs did not show any cytotoxicity in vitro in 2D monolayers of MDA-MB-231 (triple negative breast cancer), MCF7 (breast cancer) and MCF10A (normal breast epithelial cell line), whereas DTX-loaded reducible crosslinked MLNPs exhibited higher cytotoxicity against TNBC and breast cancer cells which present high intracellular levels of glutathione. Crosslinked and non-crosslinked MLNPs showed high and concentration-dependent cellular uptake in monolayers and tumour spheroids, including when assessed in co-cultures of TNBC cells and cancer-associated fibroblasts. DTX loaded crosslinked MLNPs showed the highest efficacy against 3D spheroids of TNBC, in addition the MLNPs also induced higher levels of apoptosis, as assessed by annexin V/PI assays and increased caspase 3/7 activity in MDA-MB-231 cells in comparison to cells treated with DTX-loaded un-crosslinked MLNP (used as a control) and free DTX. Taken together these data demonstrate that the terpolymer micellar-like nanoparticles with reducible crosslinks have high efficacy in both 2D and 3D in vitro cancer models by targeting the aberrant biology, i.e. loss of redox control of this type of tumour, thus may be promising and effective carrier systems for future clinical applications in TNBC.

Published
2020

11. Reduction‐responsive polymers for drug delivery in cancer therapy—Is there anything new to discover?

Author

Monteiro, Patrícia F., Travanut, Alessandra, Conte, Claudia, and Alexander, Cameron

Abstract

Among various types of stimuli‐responsive drug delivery systems, reduction‐responsive polymers have attracted great interest. In general, these systems have high stability in systemic circulation, however, they can respond quickly to differences in the concentrations of reducing species in specific physiological sites associated with a pathology. This is a particularly relevant strategy to target diseases in which hypoxic regions are present, as polymers which are sensitive to in‐situ expressed antioxidant species can, through a local response, release a therapeutic at high concentration in the targeted site, and thus, improve the selectivity and efficacy of the treatment. At the same time, such reduction‐responsive materials can also decrease the toxicity and side effects of certain drugs. To date, polymers containing disulfide linkages are the most investigated of the class of reduction‐responsive nanocarriers, however, other groups such as selenide and diselenide have also been used for the same purpose. In this review article, we discussed the rationale behind the development of reduction‐responsive polymers as drug delivery systems and highlight examples of recent progress. We include the most popular design methods to generate reduction‐responsive polymeric carriers and their applications in cancer therapy, and question what areas may still need to be explored in a field with already a very large number of research articles. Finally, we consider the main challenges associated with the clinical translation of these nanocarriers and the future perspectives in this area. This article is categorized under:Therapeutic Approaches and Drug Discovery > Nanomedicine for Oncologic DiseaseNanotechnology Approaches to Biology > Nanoscale Systems in BiologyTherapeutic Approaches and Drug Discovery > Emerging Technologies [ABSTRACT FROM AUTHOR]

Published
2021
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15. Dual bioresponsive antibiotic and quorum sensing inhibitor combination nanoparticles for treatment of Pseudomonas aeruginosabiofilms in vitroand ex vivoElectronic supplementary information (ESI) available. See DOI: 10.1039/c9bm00773c

Author

SinghThese authors contributed equally to this work., Nishant, Romero, Manuel, Travanut, Alessandra, Monteiro, Patricia F., Jordana-LluchCurrent affiliation: Antibiotic Resistance, Elena, Gr, Pathogenicity of Bacterial Infections, Hardie, Kim R., Williams, Paul, Alexander, Morgan R., and Alexander, Cameron

Abstract

Many debilitating infections result from persistent microbial biofilms that do not respond to conventional antibiotic regimens. A potential method to treat such chronic infections is to combine agents which interfere with bacterial biofilm development together with an antibiotic in a single formulation. Here, we explore the use of a new bioresponsive polymer formulation derived from specifically modified alginate nanoparticles (NPs) in order to deliver ciprofloxacin (CIP) in combination with the quorum sensing inhibitor (QSI) 3-amino-7-chloro-2-nonylquinazolin-4(3H)-one (ACNQ) to mature Pseudomonas aeruginosabiofilms. The alginate NPs were engineered to incorporate a pH-responsive linker between the polysaccharide backbone and the QSI, and to encapsulate CIP viacharge–charge interactions of the positively-charged drug with the carboxyl residues of the alginate matrix. In this way, a dual-action release of antibiotic and QSI was designed for the low-pH regions of a biofilm, involving cleavage of the QSI-linker to the alginate matrix and reduced charge–charge interactions between CIP and the polysaccharide as the alginate carboxyl side-chains protonated. When tested in a biofilm model the concomitant release of CIP + QSI from the pH-responsive nanoparticles significantly reduced the viability of the biofilm compared with CIP treatment alone. In addition, the alginate NPs were shown to penetrate deeply into P. aeruginosabiofilms, which we attribute in part to the charges of the NPs and the release of the QSI agent. Finally, we tested the formulation in both a 2D keratinocyte and a 3D ex vivoskin infection model. The dual-action bio-responsive QSI and CIP release nanoparticles effectively cleared the infection in the latter, suggesting considerable promise for combination therapeutics which prevent biofilm formation as well as effectively killing mature P. aeruginosabiofilms.

Published
2019
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16. Biocompatible unimolecular micelles obtained via the Passerini reaction as versatile nanocarriers for potential medical applications

Author

Oelmann, Stefan, Travanut, Alessandra, Barther, Dennis, Romero, Manuel, Howdle, Steven M., Alexander, Cameron, Meier, Michael A.R., Oelmann, Stefan, Travanut, Alessandra, Barther, Dennis, Romero, Manuel, Howdle, Steven M., Alexander, Cameron, and Meier, Michael A.R.

Abstract

A Passerini three-component polymerization was performed for the synthesis of amphiphilic star-shaped block copolymers with hydrophobic cores and hydrophilic coronae. The degree of polymerization of the hydrophobic core was varied from 5 to 10 repeating units, and the side chain ends were conjugated by performing a Passerini-3CR with PEG-isocyanide and PEG-aldehyde (950 g/mol). The resulting amphiphilic star-shaped block copolymers contained thioether groups, which could be oxidized to sulfones in order to further tune the polarity of the polymer chains. The ability of the amphiphilic copolymers to act as unimolecular micellar encapsulants was tested with the water-insoluble dye Orange II, the water-soluble dye Para Red and the macrolide antibiotic azithromycin. The results showed that the new copolymers were able to retain drug cargo at pH levels corresponding to circulating blood and selectively release therapeutically effective doses of antibiotic as measured by bacterial cell kill. The polymers were also well-tolerated by differentiated THP-1 macrophages in the absence of encapsulated drugs.

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17. Versatile routes to functional RAFT chain transfer agents through the Passerini multicomponent reaction

Author

Pearce, Amanda K., Travanut, Alessandra, Couturaud, Benoit, Taresco, Vincenzo, Howdle, Steven M., Alexander, Morgan R., Alexander, Cameron, Pearce, Amanda K., Travanut, Alessandra, Couturaud, Benoit, Taresco, Vincenzo, Howdle, Steven M., Alexander, Morgan R., and Alexander, Cameron

Abstract

The widespread adoption of RAFT polymerization stems partly from the ease and utility of installing a functional chain transfer agent onto the ends of the generated polymer chains. In parallel, the Passerini multicomponent reaction offers great versatility in converting a wide range of easily accessible building blocks to functional materials. In this work, we have combined the two approaches such that a single, commonly available, RAFT agent is used in Passerini reactions to generate a variety of multifunctional RAFT chain transfer agents containing ester linkages. Reactions to generate the multifunctional RAFT agents took place under mild conditions and in good yields. The resulting Passerini-RAFT agents were able to exert control over radical polymerization to generate materials of well-defined molecular weights and dispersity. Furthermore, the presence in these polymer cores of ester and amide functionality through the Passerini chemistries, provided regions in the materials which are inherently biodegradable, facilitating any subsequent biomedical applications. The work overall thus demonstrates a versatile and facile synthetic route to multi functional RAFT chain transfer agents and biodegradable polymers.

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18. Passerini multicomponent reaction: a versatile synthesis of nanomedicines for triple negative breast cancer treatment

Author

Travanut, Alessandra and Travanut, Alessandra

Abstract

The Passerini three component reaction (Passerini-3CR) is a multicomponent isocyanide-based reaction, which combines in one-pot and in a straightforward way an aldehyde, an isocyanide and a carboxylic acid into an ester-amide product. The flexibility of the reaction combined with the accessible functionality and the inherent biodegradability of the polymer product therefore offers much potential for new materials applicable in drug delivery and medicinal chemistry. In particular, the high functional group content in the Passerini polymer backbone could be of value in cancer drug delivery systems, as many materials designed for oncology applications lack sufficient drug payload. In this thesis, the focus is on materials for Triple Negative Breast Cancer (TNBC) therapies, as TNBC is an aggressive subtype of breast cancer that has poor patient survival and lack of targeted therapies. Patients are currently treated with taxane or anthracycline-based chemotherapy regiments, which have positive clinical outcomes only in the 30-40% of patients in early stage and poor survival in metastatic patients. The work in this study aims to develop functional biodegradable and biocompatible drug delivery systems for the chemotherapy treatment of TNBC, by exploiting the versatility of the Passerini-3CR. In Chapter 2, amphiphilic diblock copolymers with mPEG 2 and 5 kDa were synthesized via Passerini-3CR and formulated into polymersomes. The vesicles had a colloidally-stabilising and anti-biofouling PEG shell, were found to be stable in blood-mimicking pH conditions and to have low critical aggregation concentrations. The cytocompatibility of Passerini copolymers was verified in TNBC cells and non-cancerous human mammary epithelial cells. The internalization of fluorescently labelled Passerini polymersomes was investigated in 2D and 3D in TNBC cells and was found to be concentration dependent and endocytosis mediated. Doxorubicin was loaded in the polymersomes via the remote transmembr

19. Biocompatible unimolecular micelles obtained via the Passerini reaction as versatile nanocarriers for potential medical applications

Author

Oelmann, Stefan, Travanut, Alessandra, Barther, Dennis, Romero, Manuel, Howdle, Steven M., Alexander, Cameron, Meier, Michael A.R., Oelmann, Stefan, Travanut, Alessandra, Barther, Dennis, Romero, Manuel, Howdle, Steven M., Alexander, Cameron, and Meier, Michael A.R.

Abstract

A Passerini three-component polymerization was performed for the synthesis of amphiphilic star-shaped block copolymers with hydrophobic cores and hydrophilic coronae. The degree of polymerization of the hydrophobic core was varied from 5 to 10 repeating units, and the side chain ends were conjugated by performing a Passerini-3CR with PEG-isocyanide and PEG-aldehyde (950 g/mol). The resulting amphiphilic star-shaped block copolymers contained thioether groups, which could be oxidized to sulfones in order to further tune the polarity of the polymer chains. The ability of the amphiphilic copolymers to act as unimolecular micellar encapsulants was tested with the water-insoluble dye Orange II, the water-soluble dye Para Red and the macrolide antibiotic azithromycin. The results showed that the new copolymers were able to retain drug cargo at pH levels corresponding to circulating blood and selectively release therapeutically effective doses of antibiotic as measured by bacterial cell kill. The polymers were also well-tolerated by differentiated THP-1 macrophages in the absence of encapsulated drugs.

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20. Versatile routes to functional RAFT chain transfer agents through the Passerini multicomponent reaction

Author

Pearce, Amanda K., Travanut, Alessandra, Couturaud, Benoit, Taresco, Vincenzo, Howdle, Steven M., Alexander, Morgan R., Alexander, Cameron, Pearce, Amanda K., Travanut, Alessandra, Couturaud, Benoit, Taresco, Vincenzo, Howdle, Steven M., Alexander, Morgan R., and Alexander, Cameron

Abstract

The widespread adoption of RAFT polymerization stems partly from the ease and utility of installing a functional chain transfer agent onto the ends of the generated polymer chains. In parallel, the Passerini multicomponent reaction offers great versatility in converting a wide range of easily accessible building blocks to functional materials. In this work, we have combined the two approaches such that a single, commonly available, RAFT agent is used in Passerini reactions to generate a variety of multifunctional RAFT chain transfer agents containing ester linkages. Reactions to generate the multifunctional RAFT agents took place under mild conditions and in good yields. The resulting Passerini-RAFT agents were able to exert control over radical polymerization to generate materials of well-defined molecular weights and dispersity. Furthermore, the presence in these polymer cores of ester and amide functionality through the Passerini chemistries, provided regions in the materials which are inherently biodegradable, facilitating any subsequent biomedical applications. The work overall thus demonstrates a versatile and facile synthetic route to multi functional RAFT chain transfer agents and biodegradable polymers.

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21. Biocompatible unimolecular micelles obtained via the Passerini reaction as versatile nanocarriers for potential medical applications

Author

Oelmann, Stefan, Travanut, Alessandra, Barther, Dennis, Romero, Manuel, Howdle, Steven M., Alexander, Cameron, Meier, Michael A.R., Oelmann, Stefan, Travanut, Alessandra, Barther, Dennis, Romero, Manuel, Howdle, Steven M., Alexander, Cameron, and Meier, Michael A.R.

Abstract

A Passerini three-component polymerization was performed for the synthesis of amphiphilic star-shaped block copolymers with hydrophobic cores and hydrophilic coronae. The degree of polymerization of the hydrophobic core was varied from 5 to 10 repeating units, and the side chain ends were conjugated by performing a Passerini-3CR with PEG-isocyanide and PEG-aldehyde (950 g/mol). The resulting amphiphilic star-shaped block copolymers contained thioether groups, which could be oxidized to sulfones in order to further tune the polarity of the polymer chains. The ability of the amphiphilic copolymers to act as unimolecular micellar encapsulants was tested with the water-insoluble dye Orange II, the water-soluble dye Para Red and the macrolide antibiotic azithromycin. The results showed that the new copolymers were able to retain drug cargo at pH levels corresponding to circulating blood and selectively release therapeutically effective doses of antibiotic as measured by bacterial cell kill. The polymers were also well-tolerated by differentiated THP-1 macrophages in the absence of encapsulated drugs.

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22. Versatile routes to functional RAFT chain transfer agents through the Passerini multicomponent reaction

Author

Pearce, Amanda K., Travanut, Alessandra, Couturaud, Benoit, Taresco, Vincenzo, Howdle, Steven M., Alexander, Morgan R., Alexander, Cameron, Pearce, Amanda K., Travanut, Alessandra, Couturaud, Benoit, Taresco, Vincenzo, Howdle, Steven M., Alexander, Morgan R., and Alexander, Cameron

Abstract

The widespread adoption of RAFT polymerization stems partly from the ease and utility of installing a functional chain transfer agent onto the ends of the generated polymer chains. In parallel, the Passerini multicomponent reaction offers great versatility in converting a wide range of easily accessible building blocks to functional materials. In this work, we have combined the two approaches such that a single, commonly available, RAFT agent is used in Passerini reactions to generate a variety of multifunctional RAFT chain transfer agents containing ester linkages. Reactions to generate the multifunctional RAFT agents took place under mild conditions and in good yields. The resulting Passerini-RAFT agents were able to exert control over radical polymerization to generate materials of well-defined molecular weights and dispersity. Furthermore, the presence in these polymer cores of ester and amide functionality through the Passerini chemistries, provided regions in the materials which are inherently biodegradable, facilitating any subsequent biomedical applications. The work overall thus demonstrates a versatile and facile synthetic route to multi functional RAFT chain transfer agents and biodegradable polymers.

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23. Biocompatible unimolecular micelles obtained via the Passerini reaction as versatile nanocarriers for potential medical applications

Author

Oelmann, Stefan, Travanut, Alessandra, Barther, Dennis, Romero, Manuel, Howdle, Steven M., Alexander, Cameron, Meier, Michael A.R., Oelmann, Stefan, Travanut, Alessandra, Barther, Dennis, Romero, Manuel, Howdle, Steven M., Alexander, Cameron, and Meier, Michael A.R.

Abstract

A Passerini three-component polymerization was performed for the synthesis of amphiphilic star-shaped block copolymers with hydrophobic cores and hydrophilic coronae. The degree of polymerization of the hydrophobic core was varied from 5 to 10 repeating units, and the side chain ends were conjugated by performing a Passerini-3CR with PEG-isocyanide and PEG-aldehyde (950 g/mol). The resulting amphiphilic star-shaped block copolymers contained thioether groups, which could be oxidized to sulfones in order to further tune the polarity of the polymer chains. The ability of the amphiphilic copolymers to act as unimolecular micellar encapsulants was tested with the water-insoluble dye Orange II, the water-soluble dye Para Red and the macrolide antibiotic azithromycin. The results showed that the new copolymers were able to retain drug cargo at pH levels corresponding to circulating blood and selectively release therapeutically effective doses of antibiotic as measured by bacterial cell kill. The polymers were also well-tolerated by differentiated THP-1 macrophages in the absence of encapsulated drugs.

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24. Versatile routes to functional RAFT chain transfer agents through the Passerini multicomponent reaction

Author

Pearce, Amanda K., Travanut, Alessandra, Couturaud, Benoit, Taresco, Vincenzo, Howdle, Steven M., Alexander, Morgan R., Alexander, Cameron, Pearce, Amanda K., Travanut, Alessandra, Couturaud, Benoit, Taresco, Vincenzo, Howdle, Steven M., Alexander, Morgan R., and Alexander, Cameron

Abstract

The widespread adoption of RAFT polymerization stems partly from the ease and utility of installing a functional chain transfer agent onto the ends of the generated polymer chains. In parallel, the Passerini multicomponent reaction offers great versatility in converting a wide range of easily accessible building blocks to functional materials. In this work, we have combined the two approaches such that a single, commonly available, RAFT agent is used in Passerini reactions to generate a variety of multifunctional RAFT chain transfer agents containing ester linkages. Reactions to generate the multifunctional RAFT agents took place under mild conditions and in good yields. The resulting Passerini-RAFT agents were able to exert control over radical polymerization to generate materials of well-defined molecular weights and dispersity. Furthermore, the presence in these polymer cores of ester and amide functionality through the Passerini chemistries, provided regions in the materials which are inherently biodegradable, facilitating any subsequent biomedical applications. The work overall thus demonstrates a versatile and facile synthetic route to multi functional RAFT chain transfer agents and biodegradable polymers.

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25. Passerini chemistries for synthesis of polymer pro-drug and polymersome drug delivery nanoparticles.

Author

Travanut A, Monteiro PF, Smith S, Howdle SM, Grabowska AM, Kellam B, Meier MAR, and Alexander C

Subjects
Drug Delivery Systems, Humans, Polymers therapeutic use, Nanoparticles, Prodrugs therapeutic use, Triple Negative Breast Neoplasms drug therapy
Abstract

New materials chemistries are urgently needed to overcome the limitations of existing biomedical materials in terms of preparation, functionality and versatility, and also in regards to their compatibility with biological environments. Here, we show that Passerini reactions are especially suited for the preparation of drug delivery materials, as with relatively few steps, polymers can be synthesized with functionality installed enabling drug conjugation and encapsulation, self-assembly into micellar or vesicular architectures, and with facile attachment triggerable chemistries. The polymers can be made with a variety of building blocks and assemble into nanoparticles, which are rapidly internalized in triple negative breast cancer (TNBC) cells. In addition, the polymers transport drug molecules efficiently through 3D cell cultures, and when designed with chemistries allowing pH-mediated release, exhibit greater efficacy against TNBC cells compared to the parent drug.

Published
2022
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26. Synthesis of Passerini-3CR Polymers and Assembly into Cytocompatible Polymersomes.

Author

Travanut A, Monteiro PF, Oelmann S, Howdle SM, Grabowska AM, Clarke PA, Ritchie AA, Meier MAR, and Alexander C

Subjects
Animals, Doxorubicin pharmacology, Hydrophobic and Hydrophilic Interactions, Mice, Reproducibility of Results, Drug Delivery Systems, Polymers
Abstract

The versatility of the Passerini three component reaction (Passerini-3CR) is herein exploited for the synthesis of an amphiphilic diblock copolymer, which self-assembles into polymersomes. Carboxy-functionalized poly(ethylene glycol) methyl ether is reacted with AB-type bifunctional monomers and tert-butyl isocyanide in a single process via Passerini-3CR. The resultant diblock copolymer (P1) is obtained in good yield and molar mass dispersity and is well tolerated in model cell lines. The Passerini-3CR versatility and reproducibility are shown by the synthesis of P2, P3, and P4 copolymers. The ability of the Passerini P1 polymersomes to incorporate hydrophilic molecules is verified by loading doxorubicin hydrochloride in P1DOX polymersomes. The flexibility of the synthesis is further demonstrated by simple post-functionalization with a dye, Cyanine-5 (Cy5). The obtained P1-Cy5 polymersomes rapidly internalize in 2D cell monolayers and penetrate deep into 3D spheroids of MDA-MB-231 triple-negative breast cancer cells. P1-Cy5 polymersomes injected systemically in healthy mice are well tolerated and no visible adverse effects are seen under the conditions tested. These data demonstrate that new, biodegradable, biocompatible polymersomes having properties suitable for future use in drug delivery can be easily synthesized by the Passerini-3CR., (© 2020 The Authors. Published by Wiley-VCH GmbH.)

Published
2021
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27. Reduction-responsive polymers for drug delivery in cancer therapy-Is there anything new to discover?

Author

Monteiro PF, Travanut A, Conte C, and Alexander C

Subjects
Drug Delivery Systems, Humans, Nanomedicine, Polymers therapeutic use, Drug Carriers therapeutic use, Nanoparticles, Neoplasms drug therapy
Abstract

Among various types of stimuli-responsive drug delivery systems, reduction-responsive polymers have attracted great interest. In general, these systems have high stability in systemic circulation, however, they can respond quickly to differences in the concentrations of reducing species in specific physiological sites associated with a pathology. This is a particularly relevant strategy to target diseases in which hypoxic regions are present, as polymers which are sensitive to in-situ expressed antioxidant species can, through a local response, release a therapeutic at high concentration in the targeted site, and thus, improve the selectivity and efficacy of the treatment. At the same time, such reduction-responsive materials can also decrease the toxicity and side effects of certain drugs. To date, polymers containing disulfide linkages are the most investigated of the class of reduction-responsive nanocarriers, however, other groups such as selenide and diselenide have also been used for the same purpose. In this review article, we discussed the rationale behind the development of reduction-responsive polymers as drug delivery systems and highlight examples of recent progress. We include the most popular design methods to generate reduction-responsive polymeric carriers and their applications in cancer therapy, and question what areas may still need to be explored in a field with already a very large number of research articles. Finally, we consider the main challenges associated with the clinical translation of these nanocarriers and the future perspectives in this area. This article is categorized under: Therapeutic Approaches and Drug Discovery > Nanomedicine for Oncologic Disease Nanotechnology Approaches to Biology > Nanoscale Systems in Biology Therapeutic Approaches and Drug Discovery > Emerging Technologies., (© 2020 The Authors. WIREs Nanomedicine and Nanobiotechnology published by Wiley Periodicals LLC.)

Published
2021
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