PREPARATION AND CHARACTERIZATION OF AN ELECTROSPUN GELATIN/DENDRIMER HYBRID NANOFIBER DRESSING

Smith-Freshwater, Alicia P.

14 August 2009

A novel dendritic wound dressing was designed and characterized for its potential to treat chronic wounds. Comprised of gelatin, dendrimer, synthetic polymer and antibiotics, the dressing was electrospun to mimic the natural extracellular matrix (ECM). Gelatin is biocompatible, biodegradable, non-toxic, and easily available. The antibiotic, doxycycline, has the ability to inhibit matrix metalloproteinases. Matrix metalloproteinases, which occur in excess in chronic wounds, degrade the reconstituted ECM. Starburst™ polyamidoamine (PAMAM) dendrimer G3.5, which provides a versatile and structurally controlled architecture to construct nanomedicine, was covalently bonded to the gelatin backbone and electrospun into nanofibers with gelatin, doxycycline and stabilizing polymers. The proposed gelatin/dendrimer hybrid provides a bacterial free environment and mimics the ECM to promote wound healing. The development of this new polymeric matrix is an important step in advancing the use of bioactive nanofibers with targeted and controlled drug delivery as a wound dressing.

PAMAM dendrimer

electrospinning

gelatin wound dressing

Engineering

Ancoramento de nitrosilo complexo de rutênio em dendrímeros PAMAM e estudo de suas propriedades químicas e biológicas / Anchoring ruthenium nitrosyl complex on PAMAM dendrimer and chemical and biological properties

Roveda Júnior, Antonio Carlos

14 July 2011

O ancoramento do complexo trans-[RuIII(NH3)4(SO4)ina]Cl em dendrímeros PAMAM de geração 0 e 2 (G0 e G2) foi realizada por meio de uma ligação peptídica, e esses produtos foram submetidos à reação com NO(g) gerando os respectivos nitrosilo complexos G0/RuNO e G2/RuNO. A caracterização desses compostos por infravermelho, UV-vis, voltametria cíclica, RMN de 1H e 13C, e análise elementar indica que os nitrosilo complexos foram imobilizados na superfície dos PAMAM G0 e G2. Os espectros de infravermelho para G0/RuNO e G2/RuNO apresentaram apenas um estiramento &nu;NO+, respectivamente em 1933 e 1937 cm-1, e para o produto RuNO (não ligado ao dendrímero) em 1933 cm-1. O espectro eletrônico para esses três compostos apresentou bandas nas regiões de 230, 270 e 330 nm, e por meio de voltametria cíclica observou-se o processo eletroquímico relativo a NO+/NO0 com ENO+/NO0 vs ECS igual a -0,173 V para G0/RuNO, -0,178 V G2/RuNO e -0,175 V para RuNO. O espectro de 1H RMN do complexo RuNO apresentou dois dubletos com deslocamentos químicos centrados em 8,73 e 8,35 ppm, referentes aos hidrogênios aromáticos respectivamente nas posições orto e meta do ligante ina coordenado ao metal. Para G0/RuNO e G2/RuNO esses sinais foram observados em 8,73 e 8,36 ppm, e os sinais referentes aos dendrímeros nesses produtos foram verificados entre 2,7 e 4,0 ppm. O espectro de RMN 13C para o complexo RuNO apresentou quatro sinais, e para G0/RuNO e G2/RuNO, respectivamente, dez e doze sinais, conforme esperado para esses compostos. Apesar dos resultados supracitados indicarem que o ancoramento ocorreu de forma satisfatória, os dados de análise elementar apresentaram desvios significativos entre o valor teórico e o experimental, principalmente para G2/RuNO. Em adição, foram realizados ensaios em células do baço de camundongos para verificar a toxicidade dos nitrosilo complexos às células saudáveis, e os resultados indicaram baixa citotoxicidade (<15%) para RuNO, G0/RuNO e G2/RuNO. Também foram realizados experimentos sobre a atividade in vitro desses compostos contra os parasitos Trypanosoma cruzi e Leishmania major. Os melhores resultados, ainda que preliminares, foram obtidos com a maior concentração, 200&micro;M (em relação à Ru), em que observou-se atividade tripanocida (média) em torno de 88% para G2/RuNO, 82% para G0/RuNO e 72% para RuNO, enquanto que para o Bz (referência) esse valor foi de 96%. Já a atividade leishmanicida (concentração de 200&micro;M) desses compostos ficou entre 60 a 70% (65% para G2RuNO, 69% para G0/RuNO e 60% para RuNO). / The anchoring of the complex trans-[RuIII(NH3)4(SO4)ina]Cl on PAMAM dendrimers of generation 0 and 2 (G0 and G2) was performed by a peptide bond, and the products were submitted to reaction with NO (g) generating the related nitrosyl complexes G0/RuNO and G2/RuNO. The characterization of these compounds by IR, UV-vis, cyclic voltammetry, 1H and 13C NMR, and elemental analysis indicated that the nitrosyl complexes were immobilized on the surface of PAMAM G0 and G2. Infrared spectra for G0/RuNO and G2/RuNO showed only one &nu;NO+ band in 1933 and 1937 cm-1 respectively, and for RuNO (complex not bounded to the dendrimer) at 1933 cm-1. Electronic spectra for these three compounds showed bands in the regions of 230, 270 and 330 nm, and by cyclic voltammetry it was possible to observe the electrochemical process relative to NO+/NO0 with ENO+/NO0 equal to -0.173 V vs SCE for G0/RuNO , -0.178 V for G2/RuNO and -0.175 V for RuNO. The 1H NMR spectra for RuNO complex showed two doublets with chemical shifts centered at 8.73 and 8.35 ppm, respectively referring to the aromatic hydrogens in the ortho and meta positions of the ina ligand coordinated to the metal. The same signals obtained for G0/RuNO and G2/RuNO were observed in 8.73 and 8.36 ppm, and signals related to dendrimers between 2.7 and 4.0 ppm. The 13C NMR spectrum for RuNO exhibited four signals, and for G0/RuNO and G2/RuNO, respectively, ten and twelve signals, as expected for these compounds. Despite the results above, which indicate that anchoring occurred satisfactorily, the elemental analysis showed significant deviations between the theoretical and experimental values, especially for G2/RuNO. In adition, in vitro assays were performed on mice spleen cells to determine the toxicity of the nitrosyl complex to healthy cells, and the results showed low cytotoxicity (<15%) for RuNO, G0/RuNO and G2/RuNO. In vitro experiments were also carried out to determine the activity of these compounds against the parasite Trypanosoma cruzi and Leishmania major. The best results (preliminary) were obtained with the highest concentration 200&micro;M (relative to Ru), which was observed trypanocidal activity (average) around 88% for G2/RuNO, 82% for G0/RuNO and 72% for RuNO, while for Bz (reference) it was around 96%. The leishmanicidal activity (concentration of 200&micro;M) of these compounds was in the range of 60 to 70% (65% for G2RuNO, 69% for G0/RuNO and 60% for RuNO).

Dendrímero PAMAM

Nitric oxide

Óxido nítrico

PAMAM dendrimer

Rutênio

Ruthenium

Antichagásicos e leishmanicidas potenciais: estudo das condições de síntese de pró-fármacos dendriméricos de 3-hidroxiflavona / Potential antichagasic and leishmanicide compounds: study of synthesis conditions of 3-hydroxyflavone dendrimer prodrugs

Santos, Soraya da Silva

24 October 2016

INTRODUÇÃO: A doença de Chagas e a leishmaniose são doenças tropicais supernegligenciadas, que afetam regiões de extrema pobreza. Os fármacos disponíveis para estas duas doenças são escassos, de eficácia limitada, de alta toxicidade e suscitam casos de resistência. OBJETIVO: Considerando-se a necessidade de desenvolvimento de novos agentes antichagásicos e leishmanicidas, a importância da latenciação no aprimoramento de fármacos/compostos bioativos e a versatilidade de transportadores dendriméricos, o objetivo deste trabalho foi a síntese de pró-fármacos dendriméricos de primeira geração de 3-hidroxiflavona, composto que apresenta potencial atividade tripanomicida e leishmanicida. Desta forma, pretendeu-se obter liberação controlada, melhora da permeabilidade, toxicidade reduzida e aumento da eficácia deste agente bioativo. MATERIAL E MÉTODOS: Para a obtenção desses dendrímeros empregaram-se as abordagens divergente e convergente, compostas por várias etapas de síntese com reações de proteção, desproteção e acoplamentos. RESULTADOS E DISCUSSÃO: A abordagem convergente apresentou problemas sintéticos, devido à instabilidade dos derivados contendo 3-hidroxiflavona nas diferentes condições reacionais e de purificação testadas. No entanto, há indícios da síntese dos pró-fármacos dendriméricos de 3-hidroxiflavona, mas esses compostos apresentam-se impuros. Devido a essa instabilidade e a dificuldade de purificação na abordagem convergente, optou-se pela síntese divergente, no qual o composto bioativo é acoplado na etapa final. Os estudos sintéticos mostraram a obtenção dos intermediários puros formados pelos focos centrais propano- e hexano-diamina acoplados ao ácido málico protegido. CONCLUSÃO: Há indicativos da obtenção de pró-fármacos dendriméricos de 3-hidroxiflavona, ainda que impuros. As maiores dificuldades encontradas foram a purificação e a estabilidade dos compostos obtidos. / INTRODUCTION: Chagas\' disease and leishmaniasis are super neglected tropical diseases that affect primarily areas of extreme poverty. The drugs available for these diseases are scarce and of limited effectiveness, toxic and rouse resistance. OBJECTIVE: Considering that the development of new antichagasic and leishmanicide agents are urgently needed, the importance of prodrug design to the improvement of drugs and bioactive compounds and the versatility of dendrimers as drug carriers, the objective of this work was the synthesis of dendrimer prodrug of 3-hydroxyflavone, which shows potential antichagasic and leishmanicide activities. Thus, we intended to obtain controlled release, improvement of the permeability, reduction of the toxicity and increase of efficacy of this bioactive agent. MATERIAL AND METHODS: Convergent and divergent approaches have been used to synthesize those compounds. Synthetic steps consist of protection, deprotection and coupling reactions. RESULTS AND DISCUSSION: The convergent approach presented problems due to the instability of the 3-hydroxyflavone derivatives, in different reaction and purification conditions. However, there is evidence of the synthesis of dendrimer prodrugs, though still impure. Due to instability and purification difficulty of intermediate, we performed the divergent synthesis. We obtained the pure intermediates composed by cores propanediamine and hexanediamine coupled to the protected malic acid as spacer group. CONCLUSION: Synthetic studies suggested the synthesis of dendrimer prodrugs, although impure. The greatest difficulties were the purification and the instability of compounds.

Dendrimer

Dendrímeros

Flavonoid

Flavonóides

Latenciação

Pró-fármacos

Prodrug

Prodrug design

Targeted dendrimeric prodrugs for 5-Aminolaevulinic acid photodynamic therapy

Tewari, Kunal Mahesh

January 2016

Photodynamic therapy (PDT) is an emerging therapy for the treatment of cancer and various other human disorders. 5-Aminolaevulinic acid (ALA) is a simple natural product that is of great interest for PDT because it can be converted within cells via the haem biosynthetic pathway to the photosensitiser, protoporphyrin IX (PpIX). ALA-PDT has become a first line clinical approach for the treatment of cancerous and precancerous skin lesions (e.g Bowen’s disease, basal skin carcinomas, and actinic keratosis) that would otherwise require significant conventional surgery. However, ALA being a zwitterion suffers from poor lipid solubility and at the same time has stability issues at physiological or alkaline pH. The work herein describes some novel strategies to enhance the delivery of ALA to specific cell types using targeted ALA dendrimeric prodrugs. Specifically, it describes the synthesis of molecules consisting of branched units with 3 or more copies of ALA attached to a central core structure (e.g. gallic acid) using copper-catalysed azide-alkyne click chemistry (CuAAC). Selective delivery of the dendrimeric ALA cargo was achieved by attachment of a homing peptide to an independently addressable functional group on the prodrug core. As proof of concept of this approach, systems were prepared containing a peptide that allows selective targeting of the epidermal growth factor receptor (EGFR) which is overexpressed in a variety of tumours. Targeted ALA delivery and PpIX production was studied with these prodrugs in EGFR-expressing breast adenocarcinoma cells (MDA-MB-231 cells) and a peptide-targeted derivative with 9 ALA units was found to have enhanced PDT efficacy compared to an equimolar dose of ALA. Other targeting units that have been attached to these dendrimeric ALA prodrugs include biomolecules such as vitamin E, thymidine (a nucleoside) and a glucose derivative. Additionally, strain-promoted azide-alkyne cycloadditions (SPAAC) of the same EGFR-targeting peptide with some classical photosensitisers were also investigated and biological studies in EGFR-overexpressing cell lines were carried out. Lastly, a group of cell penetrating peptide-ALA conjugates have been synthesised via CuAAC as a novel approach for targeted ALA delivery.

615.8

Self-Assembly of Dendrimers and Cucurbit[n]uril Complexes

Wang, Wei

14 December 2008

This dissertation investigates the preparation and electrochemical studies on a series of novel redox active hybrid dendrimers. The author also describes cucurbit[8]uril (CB8) mediated dendrimer self-assembly and their size selection by applying external electrochemical stimulus. In addition to this, a series of redox active, carboxylic acid terminated dendrimers were deposited onto indium tin oxide (ITO) surfaces. The surface interactions between the dendrimers and the metal oxides were characterized by electrochemical, spectroscopic, and atomic force microscopic methods. Additionally, the author describes molecular recognition behavior studies between several redox active guests and cucurbit[7]uril (CB7) in non-aqueous media. Furthermore, the author also describes the preparation and electronic communication studies on a series of bisferrocenylamino triazine derivatives. Three chapters of this dissertation deal with dendrimer applications in several different topics. A general introduction to dendrimers is given in Chapter I, including a short history, dendrimer structural features, synthetic methodologies, and also including their general applications on several different topics. Chapter II describes the preparation and characterization of a series of novel redox active hybrid dendrimers. These dendrimers consist of a ferrocenylamino nucleus and two series of popular dendrons (Fréchet and Newkome type). Interestingly, the microenvironment surrounding the redox residues is finely adjustable by varying the size of these two types of dendrons. Chapter III describes the molecular recognition studies with selected redox active guests and the macrocyclic host CB7 in non-aqueous media. The extremely strong host-guest interaction between CB7 and ferrocenylmethyl-trimethylammonium (FA) in aqueous media experiences a substantial thermodynamic stability loss when transferred to non-aqueous media. In stark contrast to this, the binding behavior between CB7 and the dicationic guest methyl viologen (MV) exhibits less sensitivity to environmental variation. Furthermore, the electrochemical studies were performed under non-aqueous media. In general, host CB7 encapsulation of these redox active guests in non-aqueous media induces different electrochemical behavior compared to that of aqueous media. For instance, the cyclic voltammetric response of CB7 encapsulated FA in DMSO exhibit substantial cathodic potential shift, which is opposite to the behavior in aqueous media. Chapter IV describes CB8 mediated dendrimer self-assembly. A new series of pi-donor containing Newkome type dendrimers were synthesized. These pi-donor containing dendrimers are found to form stable ternary charge transfer complexes with another series of pi-acceptor (viologen) containing dendrimers. Furthermore, one electron reduction of the viologen residue disrupts the charge transfer complexes and leads to the assembly of viologen radical cation dimmers. And, thus, may result in substantial size selection between these two types of dendrimer assemblies. Chapter V describes the exploration of a series of redox active dendrimers bearing multiple carboxylic acids as surface anchoring groups to attach onto the optical transparent semiconductor material ITO coated glass surfaces. The dendrimer derivatized ITO slides were further prepared as working electrodes, and the subsequent electrochemical studies revealed that these dendrimers strongly adsorb onto ITO surfaces. Especially, the ITO electrodes treated with the second generation dendrimer exhibit rather stable electrochemical behavior. The surface coverages of ITO electrodes treated with dendrimers were estimated by current integration. Atomic force microscopic studies provided insights on surface topographical variation before and after the dendrimer deposition. Infrared spectroscopic studies further revealed the chemical interactions between dendrimer carboxylic acid groups and the metal oxide surfaces. Chapter VI describes the preparation of a series of triazine based bisferrocenylamino derivatives. Variable 1H-NMR and 13C-NMR spectroscopic studies clearly indicate that these bisferrocenylamino triazine derivatives exhibit rotamerization phenomena. And, the rotamer coalescence temperatures are mediated by the third substituent group. The X-ray crystallographic analyses disclose the partial double bond character between the amino nitrogen and the triazine carbon, which reveal the structural proof behind the rotamerization phenomena. Furthermore, electrochemical experiments are performed under two sets of experimental conditions. No electronic communication is observed when using the traditional tetrabultylammonium hexafluorophosphate (TBAPF6) as supporting electrolyte. In stark contrast to this, electronic communication between the bisferrocenyl residues is observed when using tetrabultylammonium tetrakis(pentafluorophenyl)borate (TBAB(C6F5)4) as supporting electrolyte. Surprisingly, the electronic communication strength can be mediated by a third substituent group. Computational studies provide insights into the molecular geometry and electronic structure of the mixed valence species. By combining the supporting electrolyte dependant electronic communication behavior, near-IR spectroscopic studies and the computational results, we conclude that, the electronic communication between the bisferrocenyl residues in these investigated triazine derivatives occurs through space metal-metal interactions.

Hybrid Membranes for Light Gas Separations

Liu, Ting

2012 May 1900

Membrane separations provide a potentially attractive technology over conventional processes due to their advantages, such as low capital cost and energy consumption. The goal of this thesis is to design hybrid membranes that facilitate specific gas separations, especially olefin/paraffin separations. This thesis focuses on the designing dendrimer-based hybrid membranes on mesoporous alumina for reverse-selective separations, synthesizing Cu(I)-dendrimer hybrid membrane to facilitate olefin/paraffin separations, particularly ethylene/methane separation, and investigating the influence of solvent, stabilizing ligands on facilitated transport membrane. Reverse-selective gas separations have attracted considerable attention in removing the heavier/larger molecules from gas mixtures. In this study, dendrimer-based chemistry was proved to be an effective method by altering dendrimer structures and generations. G6-PIP, G4-AMP and G3-XDA are capable to fill the alumina mesopores and slight selectivity are observed. Facilitated transport membranes were made to increase the olefin/paraffin selectivity based on their chemical interaction with olefin molecules. Two approaches were explored, the first was to combine facilitator Cu(I) with dendrimer hybrid membrane to increase olefin permeance and olefin/paraffin selectivity simultaneously, and second was to facilitate transport membrane functionality by altering solvents and stabilizing ligands. Promising results were found by these two approaches, which were: 1) olefin/paraffin selectivity slightly increased by introducing facilitator Cu(I), 2) the interaction between Cu(I) and dendrimer functional groups are better known.

gas separations

FTM

dendrimer

Cu(I)

olefin/paraffin separations

Synthesis and characterization of covalently-linked dendrimer bioconjugates and the non-covalent self-assembly of streptavidin-based megamers

McLean, Megan Elizabeth

17 February 2005

This work details the attachment of dendrimers to proteins, peptides and single stranded DNA (ssDNA). Dendrimers based on melamine satisfy many of the synthetic demands in the field of bioconjugate chemistry including: monodispersity, synthetic flexibility and scalability. The solution-phase syntheses of both ssDNA-dendrimer and peptide-dendrimer bioconjugates is described, and thorough characterization by matrix-assisted laser desorption ionization/ time-of-flight (MALDI-TOF) mass spectrometry, UV-vis spectroscopy, fluorescence spectroscopy, and polyacrylamide gel electrophoresis is discussed. Non-covalent DNA-dendrimer complexes have been shown to facilitate antisense gene delivery, but are vulnerable to dissociation and subsequent enzymatic degradation within the cell. In an effort to prepare biocompatible antisense agents capable of effectively shielding ssDNA from intracellular nuclease digestion, disulfide-linked ssDNA-dendrimers were prepared and rigorously characterized to rule out the possibility of an electrostatic-based interaction. Hybridization assays were performed to determine if the covalently-attached dendrimer affected the ability of the attached ssDNA strand to anneal with a complementary sequence to form double-stranded DNA (dsDNA)-dendrimers. Results indicate that ssDNA-dendrimer conjugates readily anneal to complementary ssDNA strands either in solution or attached to gold surfaces. Nuclease digestions of conjugates in solution suggested that enzymatic manipulation of dsDNA-dendrimers is possible, offering promise for DNA-based computation and other fields of DNA-nanotechnology. Much larger bioconjugates consisting of dendrimers, proteins and peptides were prepared with the goal of obtaining molecular weights sufficient for enhanced permeability and retention (EPR) in tumors. While the dendrimer provides the advantages of a purely synthetic route for drug delivery, the protein portion of the bioconjugate provides a monodisperse, macromolecular scaffold for the non-covalent self-assembly of the dendrimers. The strategy presented herein is based on the strong interaction between biotin and the 60 kD tetrameric protein streptavidin. Each monomer of streptavidin is capable of binding 1 biotin molecule, thus when biotin functionalized peptide-dendrimers are added to streptavidin they bind to form a cluster of dendrimers, or a megamer. The biotinylated peptides that link the dendrimers to the streptavidin core provide a way to actively target specific cell types for drug delivery. Megamer formation through the addition of tetrameric streptavidin was successful as indicated by MALDI-TOF, UV-vis titration and gel electrophoresis assays.

bioconjugate

dendrimer

nanotechnology

drug delivery

macromolecule

gene therapy

Development of multifunctional siRNA delivery systems and their applications in modulating gene expression in a cardiac ischemia-reperfusion model

Liu, Jie

08 June 2015

RNA interference (RNAi) is a conservative post-transcriptional gene silencing mechanism that can be mediated by small interfering RNAs (siRNAs). Given the effectiveness and specificity of RNAi, the administration of siRNA molecules is a promising approach to cure diseases caused by abnormal gene expression. However, as siRNA is susceptible to degradation by nucleases and it can hardly penetrate cell membranes due to its polyanionic nature, a successful translation of the RNAi mechanism for therapeutic purposes is contingent on the development of safe and efficient delivery systems. This dissertation described the development of novel siRNA delivery systems on the basis of polymeric and dendrimeric materials and also demonstrated the application of one optimized delivery system to deliver therapeutic siRNAs in a cardiovascular disease model in vivo. We studied a linear peptide polymer made from cell penetrating peptide monomers and investigated the contribution of the polymeric structure, degradability, and ligand conjugation to the siRNA loading capacity, biocompatibility, and transfection efficiency of polymeric materials. With the obtained knowledge and experience, we invented a neutral crosslinked delivery system aiming to solve the inherent drawbacks of traditional cationic delivery systems that are based on electrostatic interactions. The new concept utilized buffering amines to temporarily bind siRNA and a crosslinking reaction to immobilize the formed particles, and targeting ligands modified on the neutral dendrimer surface further enhanced the interactions between the delivery vehicles and target cells. The obtained delivery system allowed stability, safety, controllability, and targeting ability for siRNA delivery, and the method developed here could be transformed to other polymeric or dendrimeric cationic materials to make them safer and more efficient. To exploit the therapeutic potential of siRNA delivery, we developed a tadpole-shaped dendrimeric material to deliver siRNA against an Angiotensin II receptor in a rat ischemia-reperfusion model. Our results showed that the nonaarginine-conjugated tadpole dendrimer was capable of delivering siRNA effectively to cardiac cells both in vitro and in vivo, and the successful down-regulation of the Angiotensin II receptor preserved the cardiac functions and reduced the infarct size post-myocardial infarction. This dissertation paves a way for transforming multifunctional non-viral siRNA delivery systems into potent therapeutic strategies for the management of cardiovascular diseases.

Delivery system

siRNA

Cell penetrating peptide

Dendrimer

Myocardial infarction

Advanced polymeric scaffolds for functional materials in biomedical applications

Öberg Hed, Kim

January 2014

Advancements in the biomedical field are driven by the design of novel materials with controlled physical and bio-interactive properties. To develop such materials, researchers rely on the use of highly efficient reactions for the assembly of advanced polymeric scaffolds that meet the demands of a functional biomaterial. In this thesis two main strategies for such materials have been explored; these include the use of off-stoichiometric thiol-ene networks and dendritic polymer scaffolds. In the first case, the highly efficient UV-induced thiol-ene coupling (TEC) reaction was used to create crosslinked polymeric networks with a predetermined and tunable excess of thiol or ene functionality. These materials rely on the use of readily available commercial monomers. By adopting standard molding techniques and simple TEC surface modifications, patterned surfaces with tunable hydrophobicity could be obtained. Moreover, these materials are shown to have great potential for rapid prototyping of microfluidic devices. In the second case, dendritic polymer scaffolds were evaluated for their ability to increase surface interactions and produce functional 3D networks. More specifically, a self-assembled dendritic monolayer approach was explored for producing highly functional dendronized surfaces with specific interactions towards pathogenic E. coli bacteria. Furthermore, a library of heterofunctional dendritic scaffolds, with a controllable and exact number of dual-purpose azide and ene functional groups, has been synthesized. These scaffolds were explored for the production of cell interactive hydrogels and primers for bone adhesive implants. Dendritic hydrogels decorated with a selection of bio-relevant moieties and with Young’s moduli in the same range as several body tissues could be produced by facile UV-induced TEC crosslinking. These gels showed low cytotoxic response and relatively rapid rates of degradation when cultured with normal human dermal fibroblast cells. When used as primers for bone adhesive patches, heterofunctional dendrimers with high azide-group content led to a significant increase in the adhesion between a UV-cured hydrophobic matrix and the wet bone surface (compared to patches without primers). / <p>QC 20140116</p>

Dendrimer

hydrogel

PEG

dendritic monolayers

thiol-ene networks

off-stochiometric

Multi-component peptide-based carriers for gene delivery

Shu Yang

Unknown Date

The feasibility of most gene therapy strategies depends on the efficient delivery of DNA to target cells and tissues. Current gene delivery carriers can be divided into two classes: viral and non-viral delivery systems. Although the viral carriers are highly efficient due to their invasive nature, safety concerns may restrict their application in clinical settings. Synthetic non-viral carriers attract increasing attention because they are less toxic and allow readily modification. Non-viral carrier mediated gene delivery involves several processes. They must condense DNA into small particles, allow membrane penetration and protect DNA from extracellular and intracellular degradative enzymes. In the present study, a small library of carriers containing various combinations of cell penetrating peptide TAT, SV40 large T protein nuclear localisation signal (NLS) and cationic dendrimer of 7 lysine residues (DEN) was synthesised and tested for their ability to deliver DNA to mammalian cells. We evaluated the contribution of each component as well as the combination of the components on DNA condensation, uptake and gene expression. It was found that all carriers condensed DNA and protected DNA from DNase degradation. We showed that the TAT peptide was essential, but not sufficient, for uptake of exogenous DNA. The addition of either NLS or DEN significantly enhanced uptake. The most efficient carrier contained all three components (DEN-NLS-TAT). The carriers were able to deliver DNA in the presence of serum and were non-toxic to cells at up to 30 μM. However, for those peptides that facilitated DNA uptake, the complexes were targeted to intracellular compartments that required a fusogenic agent, such as chloroquine, before gene expression was observed. Modifications were introduced to the initial carrier library in order to circumvent the chloroquine dependence. The addition of cell penetrating peptide penetratin, virus derived fusogenic peptide or lipoamino acid C12 enhanced either DNA uptake or endosomal release. However, none of the modified carriers were able to produce high level transgene expression in the absence of chloroquine. We also found that the carriers containing lipid components were able to deliver DNA to T-lymphocytes derived cells, which are usually resistant to transfection. However, the toxicity of the lipid-based carriers needs to be reduced before further application. We also evaluated the function of chloroquine as a gene expression enhancer. We demonstrated that chloroquine did not enhance expression solely by promoting endosomal release. This was supported by the fact that fusogenic peptide and endosomal disruptive reagents (bafilomycin A1 and monensin) did not improve gene expression. Other properties of chloroquine, such as DNA protection and transcription enhancement, may also contribute to gene expression. We characterised the uptake mechanism of DEN-NLS-TAT in HeLa cell lines. We found that the uptake of DEN-NLS-TAT/DNA complex in HeLa cell line was mainly via receptor-mediated endocytosis and caveolae endocytosis. Moreover, various intracellular processes, such as intact cytoskeleton and microtubule network, tyrosine and PI 3 kinase activity, and membrane cholesterol were also required for the uptake of the carrier/DNA complex. In conclusion, the results from the present study demonstrated that multi-component peptide-based carriers are versatile carriers for the delivery of plasmid DNA in human cells. The results have improved our understanding of the role of chloroquine as a widely used gene expression enhancer which may be useful in the future improvement of non-viral gene delivery carriers. A strategy to overcome the dependence on chloroquine for gene expression or reduce the toxicity of chloroquine will be necessary for further in vivo applications. The current carrier library may also be used to delivery other cargos such as siRNA or protein to human cells.

non-viral gene delivery carrier

cell penetrating peptide

dendrimer

chloroquine

endocytosis