Self-Assembling Peptides as Potential Carriers for the Delivery of the Hydrophobic Anticancer Agent Ellipticine

Fung, Shan-Yu

January 2008

Self-assembling peptides have emerged as new nanobiomaterials in the areas of nanoscience and biomedical engineering. In this category are self-assembling, ionic-complementary peptides, which contain a repeating charge distribution and alternating hydrophobic and hydrophilic residues in the amino acid sequence, leading to a unique combination of amphiphilicity and ionic complementarity. These peptides can self-assemble into stable nanostructures or macroscopic membranes that can withstand conditions of high temperature, extreme pH, many digesting enzymes and denaturation agents. Moreover, they exhibit good biocompatibility with various cultured mammalian cells, and do not have detectable immune responses when introduced into animals. These properties make them ideal materials for tissue scaffolding, regenerative medicine and drug delivery. This thesis focuses on the utilization of self-assembling peptides for hydrophobic anticancer drug delivery. The hydrophobic anticancer agent ellipticine was selected as a model drug. The studies include: (i) characterization of the photophysical properties of ellipticine in different environments; (ii) study of the formation of peptide-ellipticine complexes and the release kinetics; (iii) investigation of the cellular toxicity of the complexes and ellipticine uptake; (iv) study of the peptide sequence effect on the complex formation and in vitro delivery. Prior to applying ellipticine to the peptide-based delivery system, the fundamental studies on the effect of solution conditions, especially solvent polarity and hydrogen bonding, on the fluorescence of ellipticine were carried out. Ultraviolet (UV) absorption and fluorescence emission of ellipticine were found to be solvent/environment dependent. The absorption and emission maxima shifted to higher wavelengths (red shift) with increased solvent polarity. Large Stokes’ shifts were due to intramolecular charge transfer (ICT), which was enabled by large solvent polarity and hydrogen bonding of ellipticine with the solvents. The photophysical response of ellipticine to changes in solvent polarity and hydrogen bond formation could be used to infer the location of ellipticine in a heterogeneous medium, such as liposomes and cultured cells. EAK16-II, a model self-assembling peptide, was found to be able to stabilize ellipticine in aqueous solution. The equilibration time required to form peptide-ellipticine complex suspensions was found to be peptide concentration-dependent and related to the peptide critical aggregation concentration (CAC, ~0.1 mg/mL). With different combinations of EAK16-II and ellipticine concentrations, two molecular states (protonated or crystalline) of ellipticine could be obtained in the complexes. The release kinetics of ellipticine from the complex into egg phosphatidylcholine (EPC) vesicles (cell membrane mimics) was also affected by the peptide concentration used in the drug formulation. A higher peptide concentration resulted in a faster transfer rate, in relation to the size of the resulting complexes. Subsequent cellular studies on two cancer cell lines, A549 and MCF-7, showed that the complexes with protonated ellipticine were more effective against both cell lines, but their dilutions were not very stable. In addition, it was found that ellipticine uptake in both cell lines was very fast and through direct membrane permeation. Three peptides, EAK16-II, EAK16-IV and EFK16-II, either having a different charge distribution (EAK16-II vs. EAK16-IV) or hydrophobicity (EAK16-II vs. EFK16-II), were tested for the complexation and in vitro delivery of ellipticine. It was found that EAK16-II and EAK16-IV were able to stabilize protonated or crystalline ellipticine depending on the peptide concentration; EFK16-II, on the other hand, could stabilize neutral ellipticine molecules and ellipticine (micro)crystals. The viability results showed that the charge distribution of the peptides seemed not to affect the complex formation and its therapeutic efficacy in vitro; however, the increase in hydrophobicity of the peptides significantly altered the states of stabilized ellipticine and increased the stability of the complexes. This work provides essential information for peptide sequence design in the development of self-assembling peptide-based delivery of hydrophobic anticancer drugs.

self-assembling peptides

anticancer drug delivery

Chemical Engineering

Self-Assembling Peptides as Potential Carriers for the Delivery of the Hydrophobic Anticancer Agent Ellipticine

Fung, Shan-Yu

January 2008

Self-assembling peptides have emerged as new nanobiomaterials in the areas of nanoscience and biomedical engineering. In this category are self-assembling, ionic-complementary peptides, which contain a repeating charge distribution and alternating hydrophobic and hydrophilic residues in the amino acid sequence, leading to a unique combination of amphiphilicity and ionic complementarity. These peptides can self-assemble into stable nanostructures or macroscopic membranes that can withstand conditions of high temperature, extreme pH, many digesting enzymes and denaturation agents. Moreover, they exhibit good biocompatibility with various cultured mammalian cells, and do not have detectable immune responses when introduced into animals. These properties make them ideal materials for tissue scaffolding, regenerative medicine and drug delivery. This thesis focuses on the utilization of self-assembling peptides for hydrophobic anticancer drug delivery. The hydrophobic anticancer agent ellipticine was selected as a model drug. The studies include: (i) characterization of the photophysical properties of ellipticine in different environments; (ii) study of the formation of peptide-ellipticine complexes and the release kinetics; (iii) investigation of the cellular toxicity of the complexes and ellipticine uptake; (iv) study of the peptide sequence effect on the complex formation and in vitro delivery. Prior to applying ellipticine to the peptide-based delivery system, the fundamental studies on the effect of solution conditions, especially solvent polarity and hydrogen bonding, on the fluorescence of ellipticine were carried out. Ultraviolet (UV) absorption and fluorescence emission of ellipticine were found to be solvent/environment dependent. The absorption and emission maxima shifted to higher wavelengths (red shift) with increased solvent polarity. Large Stokes’ shifts were due to intramolecular charge transfer (ICT), which was enabled by large solvent polarity and hydrogen bonding of ellipticine with the solvents. The photophysical response of ellipticine to changes in solvent polarity and hydrogen bond formation could be used to infer the location of ellipticine in a heterogeneous medium, such as liposomes and cultured cells. EAK16-II, a model self-assembling peptide, was found to be able to stabilize ellipticine in aqueous solution. The equilibration time required to form peptide-ellipticine complex suspensions was found to be peptide concentration-dependent and related to the peptide critical aggregation concentration (CAC, ~0.1 mg/mL). With different combinations of EAK16-II and ellipticine concentrations, two molecular states (protonated or crystalline) of ellipticine could be obtained in the complexes. The release kinetics of ellipticine from the complex into egg phosphatidylcholine (EPC) vesicles (cell membrane mimics) was also affected by the peptide concentration used in the drug formulation. A higher peptide concentration resulted in a faster transfer rate, in relation to the size of the resulting complexes. Subsequent cellular studies on two cancer cell lines, A549 and MCF-7, showed that the complexes with protonated ellipticine were more effective against both cell lines, but their dilutions were not very stable. In addition, it was found that ellipticine uptake in both cell lines was very fast and through direct membrane permeation. Three peptides, EAK16-II, EAK16-IV and EFK16-II, either having a different charge distribution (EAK16-II vs. EAK16-IV) or hydrophobicity (EAK16-II vs. EFK16-II), were tested for the complexation and in vitro delivery of ellipticine. It was found that EAK16-II and EAK16-IV were able to stabilize protonated or crystalline ellipticine depending on the peptide concentration; EFK16-II, on the other hand, could stabilize neutral ellipticine molecules and ellipticine (micro)crystals. The viability results showed that the charge distribution of the peptides seemed not to affect the complex formation and its therapeutic efficacy in vitro; however, the increase in hydrophobicity of the peptides significantly altered the states of stabilized ellipticine and increased the stability of the complexes. This work provides essential information for peptide sequence design in the development of self-assembling peptide-based delivery of hydrophobic anticancer drugs.

self-assembling peptides

anticancer drug delivery

Chemical Engineering

Arginine-Rich Ionic Complementary Peptides and Their Drug Delivery Potential

Wan, Zizhen

12 August 2013

Ellipticine (EPT), a natural plant polyphenolic compound, has long been known for its significant anticancer and anti-HIV activities. Recent study on its photophysical properties has revealed that ellipticine has three molecular states: protonated, neutral and crystalline. Further in vitro cytotoxicity tests indicated that protonated ellipticine exhibited much higher anticancer activity than the other two states. To maximize drug therapeutic effect, a small library of ariginine-rich ionic complementary peptides derived from EAK, including EAR8-II, EAR8-a, ELR8-a, and EAR16-II, were investigated as a potential carrier to deliver prescribed protonated ellipticine for treatment of cancer. Fluorescence study demonstrated that all four peptides were able to solubilize and stabilize protonated ellipticine in aqueous solution at 5:1 mass ratio of peptide-to-ellipticine (0.5: 0.1 mg/mL) even upon 4000 times dilution. Physicochemical characteristics of peptides self-assemblies and peptide-ellipticine complexes such as particle size, surface charge, secondary structure and morphology were determined by dynamic light scattering (DLS), zeta potential, circular dichroism (CD) , atomic force microscopy (AFM) and transmission electron microscopy (TEM), respectively. Then the ellipticine maximum suspension was determined by ellipticine UV-absorption. With the help of the peptides and mechanical stirring overtime, up to 100% ellipticine could be uptaken and stabilized in the solution as protonated ellipticine. In vitro cytotoxicity tests indicated that the peptides were demonstrating significant biocompatibility without affecting the survival of two cancer cell lines, human lung carcinoma cell line A549 and breast cancer cell line MCF-7, whereas the complexes with protonated ellipticine were found to show great anticancer activity to the two cancer cell lines. The IC50 values were obtained for each of four different peptide-ellipticine complexes ranged from 0.36±0.12 to 18.90±0.46 μM. It is worth noting that the IC50 value of EAR16-ellipticine complex to MCF-7 was over 50 times higher than that one to A549, which presented that EAR16-ellipticine complex has a selective targeting activity to A549, with the lowest IC50 value of 0.36±0.12 μM among all four complexes. Such a result indicated that this library of novel arginine-rich ionic complementary peptides had a great potential to encapsulate prescribed protonated ellipticine and exhibited an excellent anticancer activity upon serial dilution in aqueous solution. Overall, the charge distribution and increased hydrophobicity of the short (8 amino acids length) peptides seemed not to affect the complex formation and its therapeutic efficacy in vitro; however, the increase in length of the peptides significantly altered the nanostructure of peptides and its complexation with ellipticine, increased the therapeutic efficacy of EAR16-EPT to A549. This work provides essential information for peptide sequence design in the development of self-assembling peptide-based delivery of hydrophobic anticancer drugs.

anticancer drug delivery

Syntheses and Characterization of Novel Materials for Efficacious Anticancer Drug Delivery and Selective Sensing of Bioanalytes

Moitra, Parikshit

January 2015

The thesis entitled “Syntheses and Characterization of Novel Materials for Efficacious Anticancer Drug Delivery and Selective Sensing of Bioanalytes” encompasses the syntheses and characterization of various novel materials those are primarily used for efficacious pH-targeted chemotherapy, selective sensing and quantification of ATP inside a single living cell and also for specific sensing of female sex pheromone of certain agriculturally important pests. In recent era of cancer research, pH guided anticancer drug delivery is an emerging field by which not only the drug-sensitive, but also the drug-resistant cancer cell lines can be targeted efficiently. Scientists have paid lot of attentions to this area of research to design biocompatible, pH-responsive drug delivery vehicles, where most of the literatures are end up with complex, elaborated synthetic procedures and use of expensive chemicals. There are only a few reports in the literature on small molecule based drug delivery vehicles, which is not well explored. Herein some of the biocompatible, pH-sensitive lipid and short peptide sequences are synthesized in easy and short synthetic procedures and successfully tested for their efficacious anticancer drug delivery properties by various biophysical and biological techniques. A pH and reduction dual bio-responsive short peptide sequences are also generated in simple steps for the same cause. The formation of different nanostructures from the self-assembly of these short peptides is probed from high level of theoretical calculations and ultimately a well known chemotherapeutic drug, doxorubicin, has been delivered efficiently both to the drug-sensitive and drug-resistant cancer cell lines. In a particular case, in vivo study has also been performed to establish the drug delivery efficacy of those serum-stable vehicles that led to proficient reduction of tumour volume as compared to the free drug. On the other hand, a few of the molecules are synthesized and characterized by various analytical means for the selective sensing and quantification of adenosine 5’-triphosphate (ATP) inside a single living cell. Unique surface functionalized templates are also fabricated over MEMS devices for specific sensing of female sex pheromone of Helicoverpa armigera and Bactocera oleae pest in an agricultural field to detect the early pest infestation. Toward this end, an extensive study on the design, syntheses and characterization of different novel materials is presented below.

Anticancer Drug Delivery

Sensing of Bioanalytes

Anticancer Drug Delivery

Tyrosine Kinase NGF Receptor

Palmitoyl Homocysteine

Gemini Lipid

Doxorubicin

Drug Resistant Cancer Cells

Tripeptide Sequence

Pest Management

Helicoverpa armigera

Scirphophaga Incertulas

Bactocera oleae

Organic Chemistry

The Role of Liposomal Hybrids and Gold Nanoparticles in the Efficacious Transport of Nucleic Acids and Small Molecular Drugs for Cancer Nanomedicine

Kumar, Krishan

January 2015

The thesis entitled “The Role of Liposomal Hybrids and Gold Nanoparticles in the Efficacious Transport of Nucleic Acids and Small Molecular Drugs for Cancer Nanomedicine” elucidates the preparation of various liposomal formulations of cationic monomeric and gemini lipids where hydrophobic domains were consisted of tocopherol, cholesterol and pseudoglyceryl backbone for the cellular transport of nucleic acids. The thesis continues while elucidating the role of various pH sensitive molecules and gold nanoparticles in liposomes to improve the delivery efficacy levels. This thesis also elucidates the role of gold nanoparticles stabilized with natural pH sensitive molecules for efficacious drug delivery applications. Additionally, the role of such pH sensitive gold nanoparticles in association with liposomes for the co-delivery of drug and gene has been discussed. The work has been divided into six chapters. Chapter 1A: Dimeric Lipids Derived from α-Tocopherol as Efficient Gene Transfection Agents. Mechanistic Insights into Lipoplex Internalization and Therapeutic Induction of Apoptotic Activity In this chapter, we present cationic dimeric (gemini) lipids for significant plasmid DNA (pDNA) delivery to different cell lines without any marked toxicity in the presence of serum. The six gemini lipids possess α-tocopherol as their hydrophobic backbone and differ from each other in terms of their spacer chain lengths. Each of these gemini lipids mixed with a helper lipid 1, 2-dioleoyl phosphatidyl ethanolamine (DOPE), was capable of forming stable aqueous suspensions. These co-liposomal systems were examined for their potential to transfect pEGFP-C3 plasmid DNA in to nine cell lines of different origins. The transfection efficacies noticed in terms of EGFP expression levels using flow cytometry were well corroborated using independent fluorescence microscopy studies. Significant EGFP expression levels were reported using the gemini co-liposomes which counted significantly better than one well known commercial formulation lipofectamine 2000 (L2K). Transfection efficacies were also analyzed in terms of the degree of intracellular delivery of labeled plasmid DNA (pDNA) using confocal microscopy which revealed an efficient internalization in the presence of serum. The cell viability assays performed using optimized formulations demonstrated no significant toxicity towards any of the cell lines used in the study. We also had a look at the lipoplex internalization pathway to profile the uptake characteristics. A caveolae/lipid raft route was attributed to their excellent gene transfection capabilities. The study was further advanced by using a therapeutic p53-EGFP-C3 plasmid and the apoptotic activity was observed using FACS and growth inhibition assay. Figure 1. The co-liposomes of tocopheryl gemini lipids and DOPE for efficient delivery of p53-EGFP-C3 plasmid DNA that induces significant apoptotic response. Chapter 1B: Efficacious Gene Silencing in Serum and Significant Apoptotic Activity Induction by Survivin Downregulation Mediated by Cationic Gemini Tocopheryl Lipids Non-viral gene delivery offers cationic liposomes as promising instruments for the delivery of double-stranded RNA (ds RNA) molecules for successful sequence-specific gene silencing (RNA interference). The efficient delivery of siRNA (small interfering RNA) to cells while avoiding the unexpected side effects is an important prerequisite for the exploitation of the power of this excellent tool. We discuss in this chapter about six tocopherol based cationic gemini lipids, which induce substantial gene knockdown without any obvious cytotoxicity. All the efficient co-liposomal formulations derived from each of these geminis and a helper lipid, dioleoyl phosphatidyl ethanolamine (DOPE) were well characterized using physical methods such as atomic force microscopy (AFM) and dynamic light scattering (DLS). Zeta potential measurements were conducted to estimate the surface charge of these formulations. Flow cytometric analysis showed that the optimized co-liposomal formulations could transfect anti-GFP siRNA efficiently in three different GFP expressing cell lines, viz. HEK 293T, HeLa and Caco-2 significantly better than a potent commercial standard Lipofectamine 2000 (L2K) both in the absence and presence of serum (FBS). Notably, the knockdown activity of co-liposomes of gemini lipids was not affected even in the presence of serum (10% and 50% FBS) while it dropped down for L2K significantly. Observations under a fluorescence microscope, RT-PCR and western blot analysis substantiated the flow cytometry results. The efficient cellular entry of labeled siRNA in GFP expressing cells as evidenced from confocal microscopy put forward these gemini lipids among the potent lipidic carriers for siRNA. The efficient transfection capabilities were also profiled in a more relevant fashion while performing siRNA transfections against survivin (an anti-apoptotic protein) which induced substantial apoptosis. Furthermore, the survivin downregulation improved the therapeutic efficacy levels of an anticancer drug, doxorubicin significantly. In short, the new tocopherol based gemini lipids appear to be highly promising for achieving siRNA mediated gene knockdown in various cell lines. Figure 2. The co-liposomes of tocopheryl gemini lipids and DOPE for efficient delivery of siRNA against survivin that induces significant apoptotic response. Chapter 2: Efficacious in Vitro EGFP Expression and Silencing in Serum by Cationic Pseudoglyceryl Gemini Lipids To elicit the desirable efficacy levels in cationic liposome mediated nucleic acid therapeutics has been part of extensive scientific efforts. This chapter describes three cationic gemini lipids and application of their co-liposomes with DOPE as potent pDNA (plasmid DNA) and siRNA (small interfering RNA) cytofectins for remarkably advanced efficacy levels in numerous cell lines in the presence of serum. The hydrophobic structural lineament of cationic gemini lipids is made up of pseudoglyceryl backbone linked to the hydrocarbon chains via oligo-oxyethylene units. The stable aqueous co-liposomal suspensions of gemini lipids showed an efficient binding to pDNA or siRNA and their significant intracellular delivery in various cell lines. The transfection capabilities of different co-liposomal formulations were profiled based on EGFP expression (pEGFP-C3 pDNA transfection) and EGFP knockdown (anti-GFP siRNA transfections) in EGFP expressing cell lines. The cellular EGFP expression levels and intracellular delivery of labeled nucleic acids were thoroughly studied using flow cytometry (FACS), fluorescence and confocal microscopy. The MTT based cell viability assay revealed no loss in cell viabilities for all of the transfection optimized lipoplexes of siRNA or pDNA. The transfection profile of gemini co-liposomes was noted to be significantly much better than a commercial lipofection reagent, Lipofectamine 2000 used for pDNA and siRNA applications in each of the cell lines studied. The co-liposomes and their transfection optimized lipoplexes were physiochemically characterized extensively by means of zeta potential, dynamic light scattering (DLS) and atomic force microscopy (AFM). In brief, these new gemini co-liposomal formulations seem to offer a great opportunity for successful nucleic acid (DNA and siRNA) delivery in a practical scenario. Figure 3. Efficacious EGFP expression (pDNA transfection) and EGFP silencing (anti GFP siRNA transfection) mediated by co-liposomes of pseudoglyceryl gemini lipids and DOPE. Chapter 3: Efficient Elicitation of Liposomal Nucleic acid delivery through the Eminence of Gold Nanoparticles Stabilized with pH Responsive Short Tripeptide Derived from Tyrosine Kinase NGF Receptors The prerequisite in the area of gene therapy today is to serve transfection efficient formulations nullifying the enduring key issues. To this end, we discuss in this chapter, the role of hybrid liposomal formulations derived from structurally distinct cationic lipids, a neutral lipid (DOPE) and pH responsive short tripeptide (KFG, Lys-Phe-Gly) capped gold nanoparticles (PAuNPs). The hybrid liposomes are presented to be efficient enough to transfect pDNA leading to remarkably high gene expression levels in various cell lines of different origins in the presence of serum (FBS). Hybrid liposomes could deliver pDNA more effectively than the native liposomes and commercial standard lipofectamine 2000 (L2K) across the entire range of N/P ratios studied under the influence of intracellular pH response and gold nanoparticles prominence. The gene transfection capabilities are profiled based on transfections performed using two different plasmids (pGL3, luciferase activity and p-EGFP-C3, green fluorescent protein expression). pDNA cellular internalization and subsequent gene expression levels are studied using flow cytometry, fluorescence microscopy and confocal microscopic studies. The extensive physiochemical characterization of hybrid liposomal formulation and their complexes with pDNA in comparison with respective native liposomes was performed using AFM, TEM, Zeta, DLS, gel retardation assay, U.V. and fluorescence emission measurements. The hybrid liposomes are shown to possess significantly higher fusion activity at lowered pH of intracellular compartments. These hybrid liposomes are fairly biocompatible across the concentration range used in transfection experiments. Precisely, introduction of these pH responsive tripeptide capped gold nanoparticles in to liposomal formulations straightforwardly must be more advantageous for a practical application in biomedical scenario to achieve therapeutic levels. Figure 4. The hybrid of liposomes and tri-peptide capped gold nanoparticles for significantly improved gene expression levels. Chapter 4: RNA Aptamer Decorated pH Sensitive Liposomes for Active Transport of Nucleic Acids in Specific Cancer Cells This chapter describes the target specific transport of pH sensitive liposomes loaded with a RNA aptamer for promising nucleic acid therapeutics. The pH sensitive liposomes are constructed from a cationic cholesteryl gemini lipid (CGL), neutral helper lipid (DOPE) and gemini analog of a pH sensitive lipid, palmitoyl homocysteine (GPHC). The liposomes are shown to be significantly fusogenic that deliver the cargoes upon lowerin the pH (6.0). The fusogenic behaviour of the liposomes was thoroughly studied by means of dynamic light scattering (DLS), zeta potential, lipid mixing, calcein dequenching and atomic force microscopy (AFM). The facile integration of cholesterol conjugated RNA aptamer in liposomes derived from cholesteryl gemini lipids was exploited for their delivery to specific cancer cells. The RNA aptamer specifically binds to epithelial cell adhesion molecule (EpCAM) with high affinity which is a cell surface marker in various solid cancers such as colorectal and breast carcinoma. These aptamer decorated pH sensitive liposomes could efficiently enter the EpCAM expressing COLO-205, Caco-2, MCF-7 and MDA-MB-231 cell lines while no such noticeable liposome transport was observed in EpCAM negative HEK 293T cells as evidenced by flow cytometry and confocal microscopy. Additionally, the liposomes are shown to be actively transported inside the cells, i.e., receptor mediated endocytosis. These liposomes could complex the nucleic acids (pDNA) in an efficient manner. The MTT based cell viability assay accounted no noticeable loss in cell viabilities for liposome treatments. Concisely, we have formulated RNA aptamer loaded pH sensitive liposomes that would certainly be promising tool in target based cancer nanomedicine. Figure 5. (A) Cellular internalization of DY-647 labeled aptamer loaded pH sensitive liposomes. (B) The liposomes were actively internalized through receptor mediated endocytosis. Each panel (A and B) represents (from left to right) bright field image, aptamer fluorescence, DAPI stained nuclei and merge of previous three impressions. Chapter 5: Natural Tri-peptide Capped Gold Nanoparticles for Efficacious Doxorubicin Delivery in Vitro and in Vivo Nanotechnology has gained ever increasing interest for the successful implementation of chemotherapy based treatment of cancer. This chapter describes the role of gold nanoparticles (AuNPs) capped with a natural pH responsive short tri-peptide (Lys-Phe–Gly or KFG) for significant intracellular delivery of an anti-cancer drug, doxorubicin (DOX). A significantly increased apoptotic response was noted for DOX treatments mediated by KFG-AuNPs in comparison with drug alone treatments in various cell lines (BT-474, HeLa, HEK 293T and U251) in vitro. Furthermore, KFG-AuNPs mediated DOX treatment significantly decreased cell proliferation and tumor growth in BT-474 cell xenograft model in nude mice. In addition, KFG-AuNPs showed efficacious drug delivery in DOX-resistant HeLa cells (HeLa-DOXR) in comparison with drug alone treatments. Figure 6. Representative images of excised tumors after doxorubicin treatment mediated by pH responsive tri-peptide capped gold nanoparticles (DOX-KFG-AuNPs) (C) in comparison with doxorubicin alone treatments (B) and untreated tumors (A). Extensive cell death as observed under Hematoxylin/eosin (H&E) (D) and TUNEL (E) staining of DOX-KFG-AuNPs treated tumor sections. Chapter 6: Significant Apoptotic Activity Induction by Efficacious Co-delivery of p53 Gene and Doxorubicin Mediated by the Combination of Co-liposomes of Cationic Gemini lipid and pH Responsive Tri-peptide Combining chemotherapy with gene therapy has appeared as an efficient tool to treat complex biological disorder like cancer. Herein, we show efficient co-delivery of DNA and an anti-cancer drug, doxorubicin (DOX) by means of gemini cationic liposome (GCL) based lipoplex nanoaggregates that are coated with DOX encapsulated pH responsive tripeptide nanovesicles. The lipoplex, tripeptide vesicles and their association was thoroughly studied using dynamic light scattering (DLS), zeta potential, atomic force microscopy (AFM). Flow cytometry, fluorescence and confocal microscopic analysis revealed that the GCL-tripeptide association could significantly co-deliver the p53 expression plasmid (p53-EGFP-C3) and DOX in HeLa and HEK 293T cells in the presence of serum. A synergistic increase in gene expression level and DOX internalization was observed in co-delivery which was even substantially higher than individual lipoplex transfection and DOX treatment. The apoptosis induced due to p53 expression and DOX was profiled with the help of annexin-V positivity analysis under flow cytometry and nuclear damage analysis by DAPI nuclei counterstaining under confocal microscopy which noted to be significantly higher in cells during co-delivery. The MTT based cell viability assay revealed a significantly increased loss in cell viability counts for co-delivery treatments. Such a system delivering synergistically increased significant efficacy levels in combinatorial drug and nucleic acid therapeutics would be certainly advantageous for practical biomedical applications. Figure 7. The co-delivery of pDNA and drug (doxorubicin) mediated by GCL-tripeptide association as observed under (A) confocal microscopy (pDNA; green and doxorubicin; red) and (B) flow cytometry.

Cancer Nanomedicine

Molecular Drugs

Lipoplex Internalization

α-Tocopherol

Apoptotic Activity

Gemini Tocopheryl Lipids

Pseudoglyceryl Gemini Lipids

Gold Nanoparticles

Gemini Cationic Lipids

Anticancer Drug Delivery

Cationic Gemini Lipid

RNA Aptamer

Doxorubicn

Cationic Pseudoglyceryl Gemini Lipids

Organic Chemistry

Therapeutic Applications of Biodegradable Chitosan Based Polyelectrolyte Nanocapsules

Thomas, Midhun Ben

January 2014

The past few years have witnessed significant work being directed towards drug delivery systems with layer-by layer (LbL) technique prominently featured as one of the most sought after approach. However, majority of the studies were focused on the fabrication of microcapsules which produced numerous drawbacks resulting in reduced applicability. This has spurred research into nanocapsules which has proved to overcome most of the drawbacks that plagued microcapsules by being able to evade the reticulo-endothelial system, exhibit enhanced permeability and retention in tumours etc. The capsules fabricated by the LbL technique requires a suitable combination of cationic and anionic polyelectrolytes which ensures that it is able to effectively protect the cargo it encapsulates as well as enhance its bio-applications. With numerous advantages such as biocompatibility and biodegradability to name a few, chitosan has proved to be an ideal cationic polyelectrolyte. Thus, this thesis focuses on the various therapeutic applications of LbL fabricated chitosan based nanocapsules. The first work focuses on the targeted delivery of the somatostatin analogue, Octreotide conjugated nanocapsules to over expressed somatostatin receptors. These LbL fabricated nanocapsules composed of chitosan and dextran sulfate (CD) encapsulate the anti cancer drug, doxorubicin and are found to attain site specificity as well as enhanced anti-proliferative activity. The results indicated that the nanocapsules were biocompatible and when conjugated with octreotide was found to have an enhanced internalization into SSTR expressing cells, thereby making it a viable strategy for the treatment of tumors that has an over expression of somatostatin receptors such as pancreatic carcinoma, breast carcinoma etc. The objective of the second work was to develop an efficient drug delivery system such as CD nanocapsules for encapsulation of Ciprofloxacin in order to combat infection by Salmonella, an intracellular and intra-phagosomal pathogen. In vitro and in vivo experiments showed that this delivery system can be used effectively to clear Salmonella infection. The increased retention of ciprofloxacin in tissues delivered by CD nanocapsules as compared to the conventional delivery proved that the same therapeutic effect was obtained with reduced dosage and frequency of Ciprofloxacin administration. The third work deals with the probiotic, Saccharomyces boulardii which is found to be effective against several gastrointestinal diseases but had limited clinical application due to its sensitivity to acidic environment. However, encapsulation of S. boulardii with chitosan and dextran sulfate ensured enhanced viability and selective permeability on exposure to acidic and alkaline conditions experienced during gastro intestinal transit. The final work involves the fabrication of novel pH responsive nanocapsules composed of chitosan-heparin which facilitate the intracellular delivery of a model anti-cancer drug, doxorubicin.

Pharmacokinetics

Drug Delivery System

Polyelectrolyte Nanocapsules

Chitosan Polyelectrolyte Nanocapsules

Nanocapsule Drug Delivery Systems

Chitosan Heparin Nanocapsules

Layer by Layer Nanocapsules

Anticancer Drug Delivery

Chitosan-Dextran Sulfate Nanocapsules

Biodgradable Chitosan Nanocapsules

Nanoencapsulation

Somatostatin Receptors

Biomaterials

Polyelectrolyte Capsules

Sarcoidosis

Doxorubicin

Materials Science