Characterizing the antitumor response in mice treated with antigen-loaded polyanhydride microparticles

Delivery of vaccine antigens with an appropriate adjuvant can trigger potential immune responses against cancer leading to reduced tumor growth and improved survival. In this study, various formulations of a bioerodible amphiphilic polyanhydride copolymer based on 1,8-bis(p-carboxyphenoxy)-3,6-dioxaoctane (CPTEG) and 1,6-bis(p-carboxyphenoxy) hexane (CPH) with inherent adjuvant properties were evaluated for antigen-loading properties, immunogenicity and antitumor activity. Mice were vaccinated with 50:50 CPTEG:CPH microparticles encapsulating a model tumor antigen, ovalbumin (OVA), in combination with the Toll-like receptor-9 agonist, CpG oligonucleotide 1826 (CpG ODN). Mice treated with OVA-encapsulated CPTEG:CPH particles elicited the highest CD8⁺ T cell responses on days 14 and 20 when compared to other treatment groups. This treatment group also displayed the most delayed tumor progression and the most extended survival times. Particles encapsulating OVA and CpG ODN generated the highest anti-OVA IgG₁ antibody responses in mice but these mice did not show significant tumor protection. These results suggest that antigen-loaded CPTEG:CPH microparticles can stimulate antigen-specific cellular responses and could therefore potentially be used to promote antitumor responses in cancer patients.     

Encapsulation into amphiphilic polyanhydride microparticles stabilizes Yersinia pestis antigens

The design of biodegradable polymeric delivery systems based on polyanhydrides that would provide for improved structural integrity of Yersinia pestis antigens was the main goal of this study. Accordingly, the full-length Y. pestis fusion protein (F1–V) or a recombinant Y. pestis fusion protein (F1_B2T1–V10) was encapsulated and released from microparticles based on 1,6-bis(p-carboxyphenoxy)hexane (CPH) and sebacic acid (SA) copolymers and 1,8-bis(p-carboxyphenoxy)-3,6-dioxaoctane (CPTEG) and CPH copolymers fabricated by cryogenic atomization. An enzyme-linked immunosorbent assay was used to measure changes in the antigenicity of the released proteins. The recombinant F1_B2T1–V10 was unstable upon release from the hydrophobic CPH:SA microparticles, but maintained its structure and antigenicity in the amphiphilic CPTEG:CPH system. The full-length F1–V was stably released by both CPH:SA and CPTEG:CPH microparticles. In order to determine the effect of the anhydride monomers on the protein structure, changes in the primary, secondary, and tertiary structure, as well as the antigenicity of both Y. pestis antigens, were measured after incubation in the presence of saturated solutions of SA, CPH, and CPTEG anhydride monomers. The results indicated that the amphiphilic environment provided by the CPTEG monomer was important to preserve the structure and antigenicity of both proteins. These studies offer an approach by which a thorough understanding of the mechanisms governing antigenic instability can be elucidated in order to optimize the in vivo performance of biodegradable delivery devices as protein carriers and/or vaccine adjuvants.     

Amphiphilic polyanhydrides for protein stabilization and release

The overall goal of this research is to design novel amphiphilic biodegradable systems based on polyanhydrides for the stabilization and sustained release of peptides and proteins. Accordingly, copolymers of the anhydrides, 1,6-bis(p-carboxyphenoxy)hexane (CPH) and 1,8-bis(p-carboxyphenoxy)-3,6-dioxaoctane (CPTEG), which are monomer-containing oligomeric ethylene glycol moieties, have been synthesized. Microspheres of different CPTEG:CPH compositions have been fabricated by two non-aqueous methods: solid/oil/oil double emulsion and cryogenic atomization. The ability of this amphiphilic polymeric system to stabilize model proteins (i.e., lysozyme and ovalbumin) was investigated. The structure of both the encapsulated as well as the released protein was monitored using gel electrophoresis, circular dichroism, and fluorescence spectroscopy. It was found that the CPTEG:CPH system preserves the structural hierarchy of the encapsulated proteins. Activity studies of the released protein indicate the CPTEG:CPH system retains the biological activity of the released protein. These results are promising for future in vivo studies, which involve the design of novel biodegradable polyanhydride carriers for the stabilization and sustained release of therapeutic peptides and proteins.     

Functionalization of polyanhydride microparticles with di-mannose influences uptake by and intracellular fate within dendritic cells

Innovative vaccine delivery platforms can facilitate the development of effective single-dose treatment regimens to control emerging and re-emerging infectious diseases. Polyanhydride microparticles are promising vaccine delivery vehicles due to their ability to stably maintain antigens, provide tailored release kinetics and function as adjuvants. A major obstacle for the use of microparticle-based vaccines, however, is their limited uptake by dendritic cells (DCs). In this study, we functionalized the microparticle surface with di-mannose in order to target C-type lectin receptors (CLRs) on DCs. Polyanhydride particles based on sebacic acid (SA), 1,6-bis(p-carboxyphenoxy)hexane (CPH) and 1,8-bis(p-carboxyphenoxy)-3,6-dioxaoctane (CPTEG) were evaluated. Co-incubation of di-mannose-functionalized microparticles up-regulated the expression of CLRs on DCs. More importantly, di-mannose functionalization increased the uptake, as measured by the percentage of cells internalizing particles. The uptake of CPH:SA microparticles increased ～20-fold, from 0.82% (non-functionalized) to 20.2%, and internalization of CPTEG:CPH microparticles increased ～7-fold from 1.35% (non-functionalized) to 9.3% upon di-mannose functionalization. Both di-mannose-functionalized and non-functionalized particles trafficked to lysosomes. Together, these studies demonstrate that employing rational vaccine design principles, such as the targeting of CLRs on antigen-presenting cells, can enhance delivery of encapsulated antigens and potentially induce a more robust adaptive immune response.     

Retention of structure,antigenicity, and biological function of pneumococcal surface protein A (PspA) released from polyanhydride nanoparticles

Pneumococcal surface protein A (PspA) is a choline-binding protein which is a virulence factor found on the surface of all Streptococcus pneumoniae strains. Vaccination with PspA has been shown to be protective against a lethal challenge with S. pneumoniae, making it a promising immunogen for use in vaccines. Herein the design of a PspA-based subunit vaccine using polyanhydride nanoparticles as a delivery platform is described. Nanoparticles based on sebacic acid (SA), 1,6-bis-(p-carboxyphenoxy)hexane (CPH) and 1,8-bis-(p-carboxyphenoxy)-3,6-dioxaoctane (CPTEG), specifically 50:50 CPTEG:CPH and 20:80 CPH:SA, were used to encapsulate and release PspA. The protein released from the nanoparticle formulations retained its primary and secondary structure as well as its antigenicity. The released PspA was also biologically functional based on its ability to bind to apolactoferrin and prevent its bactericidal activity against Escherichia coli. When the PspA nanoparticle formulations were administered subcutaneously to mice they elicited a high titer and high avidity anti-PspA antibody response. Together these studies provide a framework for the rational design of a vaccine against S. pneumoniae based on polyanhydride nanoparticles.     

Synthesis and characterization of novel polyanhydrides with tailored erosion mechanisms

We have designed a new synthesis route to create polyanhydrides based on monomers that contain hydrophilic entities within highly hydrophobic backbones. The method results in polyanhydrides that can be easily processed into drug-containing tablets. The synthesis, characterization, and erosion studies of polyanhydride copolymers based on 1,6-bis(p-carboxyphenoxy)hexane (CPH), which is highly hydrophobic, and 1,8-bis(p-carboxyphenoxy)-3,6-dioxaoctane (CPTEG), which has hydrophilic oligomeric ethylene glycol segments in the monomer unit, was performed using a combination of molecular spectroscopy, thermal analysis, gravimetry, and scanning electron microscopy. The studies demonstrate that by increasing the CPH content in the CPTEG:CPH copolymers, the erosion of the system can be tailored from bulk-eroding to surface-eroding mechanism. These systems have promise as protein carriers.     

Polyanhydride microparticles enhance dendritic cell antigen presentation and activation

The present study was designed to evaluate the adjuvant activity of polyanhydride microparticles prepared in the absence of additional stabilizers, excipients or immune modulators. Microparticles composed of varying ratios of either 1,6-bis(p-carboxyphenoxy)hexane (CPH) and sebacic acid or 1,8-bis(p-carboxyphenoxy)-3,6-dioxaoctane and CPH were added to in vitro cultures of bone marrow-derived dendritic cells (DCs). Microparticles were efficiently and rapidly phagocytosed by DCs in the absence of opsonization and without centrifugation or agitation. Within 2h, internalized particles were rapidly localized to an acidic, phagolysosomal compartment. By 48 h, only a minor reduction in microparticle size was observed in the phagolysosomal compartment, indicating minimal particle erosion consistent with being localized within an intracellular microenvironment favoring particle stability. Polyanhydride microparticles increased DC surface expression of major histocompatability complex class II, the co-stimulatory molecules CD86 and CD40, and the C-type lectin CIRE (murine DC-SIGN; CD209). In addition, microparticle stimulation of DCs also enhanced secretion of the cytokines IL-12p40 and IL-6, a phenomenon found to be dependent on polymer chemistry. DCs cultured with polyanhydride microparticles and ovalbumin induced polymer chemistry-dependent antigen-specific proliferation of both CD4(+) OT-II and CD8(+) OT-I T cells. These data indicate that polyanhydride particles can be tailored to take advantage of the potential plasticity of the immune response, resulting in the ability to induce immune protection against many types of pathogens.     

High-throughput analysis of protein stability in polyanhydride nanoparticles

Polyanhydrides are a class of surface eroding biomaterials with applications in vaccine and drug delivery. With the complexity and fragile nature of many protein molecules used in therapeutic treatments and vaccines, devices capable of protecting and preserving the functionality of these proteins are essential. In addition, the half-lives of many vaccine antigens and therapeutic proteins are often short, especially at elevated temperatures. In this work a high-throughput methodology has been developed to rapidly assess the effects of polymer chemistry and the various steps during protein delivery (i.e. encapsulation, storage and release) from polyanhydride nanoparticles on the stability of a model protein, bovine serum albumin. Additional factors including microenvironment pH were also investigated in this multi-parametric approach to evaluate protein stabilization. The findings indicate that the microenvironment pH caused by the acidic polymer degradation products was the most detrimental factor affecting protein stability. Nanoparticles based on 1,8-bis(p-carboxyphenoxy)-3,6-dioxaoctane and 1,6-bis(p-carboxyphenoxy)hexane maintained protein antigenicity over a range of temperatures for 1 month. These nanoparticles were also successful in preserving protein structure and emerged as viable candidates for use in future drug/protein delivery applications. The combinatorial approach developed in this work allowed for a 25-fold decrease in time and a 10-fold decrease in the amount of materials needed for the investigation of protein stability when compared to conventional methods.     

Design of an injectable system based on bioerodible polyanhydride microspheres for sustained drug delivery

The fabrication, morphological characterization, and drug release kinetics from microspheres of three bioerodible polyanhydrides, poly[1,6-bis(p-carboxyphenoxy)hexane] (poly(CPH)), poly(sebacic anhydride) (poly(SA)), and the copolymer poly(CPH-co-SA) 50:50 (CPH:SA 50:50) is reported. The fabrication technique yields microspheres with different morphologies for each of the three polymers studied, ranging from very smooth exterior surfaces for poly(CPH) to coarse surface roughness with large pores for poly(SA). Release profiles for the model drug, p-nitroaniline are also different for each polymer. The release profile from poly(CPH) has a large initial burst and shows little additional release after 2 days. The release from poly(SA) is nearly zero-order and lasts for about 8 days. The release profile from CPH:SA 50:50 shows a relatively small burst and then exhibits zero-order release for about I month. The different release profiles are attributed to both polymer erosion rates and drug distribution characteristics of the microspheres. Tailored release profiles of a burst followed by zero-order release are obtained by appropriately combining the microspheres. This technique enables independent modulation of both the burst and the zero-order release rate by varying the number of poly(CPH) and poly(SA) microspheres respectively. Additionally, the zero-order release can be extended from about a week to a month by including CPH:SA 50:50 microspheres.     

Tumour stroma‐derived lipocalin‐2 promotes breast cancer metastasis

Tumour cell‐secreted factors skew infiltrating immune cells towards a tumour‐supporting phenotype, expressing pro‐tumourigenic mediators. However, the influence of lipocalin‐2 (Lcn2) on the metastatic cascade in the tumour micro‐environment is still not clearly defined. Here, we explored the role of stroma‐derived, especially macrophage‐released, Lcn2 in breast cancer progression. Knockdown studies and neutralizing antibody approaches showed that Lcn2 contributes to the early events of metastasis in vitro. The release of Lcn2 from macrophages induced an epithelial–mesenchymal transition programme in MCF‐7 breast cancer cells and enhanced local migration as well as invasion into the extracellular matrix, using a three‐dimensioanl (3D) spheroid model. Moreover, a global Lcn2 deficiency attenuated breast cancer metastasis in both the MMTV–PyMT breast cancer model and a xenograft model inoculating MCF‐7 cells pretreated with supernatants from wild‐type and Lcn2‐knockdown macrophages. To dissect the role of stroma‐derived Lcn2, we employed an orthotopic mammary tumour mouse model. Implantation of wild‐type PyMT tumour cells into Lcn2‐deficient mice left primary mammary tumour formation unaltered, but specifically reduced tumour cell dissemination into the lung. We conclude that stroma‐secreted Lcn2 promotes metastasis in vitro and in vivo, thereby contributing to tumour progression. Our study highlights the tumourigenic potential of stroma‐released Lcn2 and suggests Lcn2 as a putative therapeutic target. Copyright © 2016 Pathological Society of Great Britain and Ireland. Published by John Wiley & Sons, Ltd.     

Chemistry-dependent adsorption of serum proteins onto polyanhydride microparticles differentially influences dendritic cell uptake and activation

The delivery of antigen-loaded microparticles to dendritic cells (DCs) may benefit from surface optimization of the microparticles themselves, thereby exploiting the material properties and introducing signals that mimic pathogens. Following in vivo administration microparticle surface characteristics are likely to be significantly modified as proteins are quickly adsorbed onto their surface. In this work we describe the chemistry-dependent serum protein adsorption patterns on polyanhydride particles and the implications for their molecular interactions with DCs. The enhanced expression of MHC II and CD40 on DCs after incubation with amphiphilic polyanhydride particles, and the increased secretion of IL-6, TNF-α, and IL-12p40 by hydrophobic polyanhydride particles exemplified the chemistry-dependent activation of DCs by sham-coated particles. The presence of proteins such as complement component 3 and IgG further enhanced the adjuvant properties of these vaccine carriers by inducing DC maturation (i.e. increased cell surface molecule expression and cytokine secretion) in a chemistry-dependent manner. Utilizing DCs derived from complement receptor 3-deficient mice (CR3(-/-) mice) identified a requirement for CR3 in the internalization of both sham- and serum-coated particles. These studies provide valuable insights into the rational design of targeted vaccine platforms aimed at inducing robust immune responses and improving vaccine efficacy.     

Novel polyelectrolyte complexes based on poly(methacrylic acid)-bis(2-aminopropyl)poly(ethylene glycol) for oral protein delivery

In the present investigation a simple and effective strategy was employed for the development of pH-sensitive self-assembling microparticles based on poly(methacrylic acid) (PMAA)-bis(2-aminopropyl)poly(ethylene glycol) (APEG), and their efficiency in oral protein delivery was evaluated. An inter-ionic gelation process was employed for the preparation of microparticles and particles were obtained spontaneously during the process without using any surfactants or stabilizers. Particle size analysis was carried out to measure average particle size and surface morphology was evaluated using scanning electron microscopy (SEM). Bovine serum albumin (BSA) was incorporated onto these microparticles to evaluate the loading and release properties of the matrix. PMAA-APEG microparticles displayed pH responsive release profile, as less than 10% of encapsulated BSA was released at pH 1.2 in 2 h and more than 80% of loaded protein was released within 3 h at pH 7.4. Carboxymethyl β-cyclodextrin (CMβCD)-insulin non-covalent inclusion complex was prepared to enhance the stability of insulin formulations and complex formation was analyzed by fluorescence spectroscopic studies. CMβCD-complexed insulin was encapsulated into PMAA-APEG microparticles by a diffusion filling method and biological activity of entrapped insulin was evaluated using an ELISA. Finally mucoadhesive studies of PMAA-APEG microparticles were carried out on freshly excised rat intestinal mucosa at neutral pH to establish the adhesive nature of the material.     

Proliferation, morphology, and protein expression by osteoblasts cultured on poly(anhydride-co-imides).

In vitro cell biocompatibility models are crucial in the study of any newly synthesized material. Our focus has been on the development of a new class of biocompatible, degradable, high-strength polymeric materials, the poly(anhydride-co-imides), for use in bone regeneration. This study examined osteoblast cell adherence, proliferation, viability, and phenotypic preservation on the surface of the poly(anhydride-co-imide) poly[pyromellitylimidoalanine (PMA-ala):1,6-bis(carboxyphenoxy) hexane (CPH)] over a period of time. Cell proliferation on PMA-ala:CPH degradable matrices over 21 days was examined. Throughout the 21-day period of study, osteoblast proliferation was similar on PMA-ala:CPH and on tissue culture polystyrene controls. Osteoblasts maintained their characteristic morphology as demonstrated by both scanning electron microscopy and immunofluorescence studies. Alkaline phosphatase activity for cells grown on PMA-ala:CPH was confirmed. Retention of the osteoblastic phenotype was demonstrated using immunofluorescence techniques and staining with antibodies against osteocalcin (an extracellular matrix protein of bone) and osteopontin (a marker of cell adhesion). Radioimmunoassay results provided evidence that levels of osteocalcin production by osteoblasts were similar when cells were cultured on PMA-ala:CPH and on tissue culture polystyrene controls. The present study provided evidence of normal osteoblast function on PMA-ala:CPH surfaces. PMA-ala:CPH may therefore be useful as a synthetic material for orthopedic applications.     

Lipocalin‐2 Promotes M1 Macrophages Polarization in a Mouse Cardiac Ischaemia–Reperfusion Injury Model

Ischaemia–reperfusion (IR) injury is a major issue in cardiac transplantation. Inflammatory processes play a major role in myocardial IR injury. Lipocalin‐2 (Lcn2), which is also known as neutrophil gelatinase‐associated lipocalin, has multiple functions that include the regulation of cell death/survival, cell migration/invasion, cell differentiation and iron delivery. In our study, the hearts of C57BL/6 mice were flushed with and stored in cold Bretschneider solution for 8 h and then transplanted into a syngeneic recipient. We found that Lcn2 neutralization decreased the recruitment of neutrophils and macrophages. Troponin T (TnT) production, 24 h after myocardial IR injury, was reduced through anti‐Lcn2 antibody administration. The cardiac output at 60 mmHg of afterload pressure was significantly increased in hearts administrated with anti‐Lcn2 antibody administration (anti‐Lcn‐2: 58.9 ± 5.62 ml/min; control: 25.8 ± 4.1 ml/min; P < 0.05). Anti‐Lcn2 antibody treatment suppressed M1 marker (IL‐12, IL‐23 and iNOS) expression but increased M2 marker (IL‐10, Arg1 and Mrc1) expression. Furthermore, in our vitro and vivo experiments, we found that anti‐Lcn2 antibody treatment failed to induce M1‐related gene expression in response to LPS and that Lcn2 neutralization enhanced the expression of M2‐related genes following IL‐4 treatment. In conclusion, Lcn2 promotes M1 polarization, and Lcn2 neutralization attenuates cardiac IR injury.     

Lipocalin‐2 ameliorates granulocyte functionality

Attraction of neutrophils to sites of infection or tissue injury is an essential prerequisite for an efficient innate immune response. Herein, we provide novel evidence that the antimicrobial protein, neutrophil gelatinase associated lipocalin (24p3 or lipocalin‐2, Lcn2) is a central regulator of this process. Lcn2 is produced by several cell types but high amounts are released by neutrophils. Using human and murine neutrophils, we found that the addition of recombinant Lcn2 significantly stimulated their migration, which was independent of IL‐8/keratinocyte chemokine formation. Mechanistically, this could be traced back to Lcn2‐mediated changes of Erk1/2 signaling. Accordingly, the i.p. injection of Lcn2 into C57BL/6 mice stimulated the mobilization of neutrophils while we found a significantly reduced neutrophil chemotactic activity of cells obtained from Lcn2 KO mice. This observation transmitted to a reduced accumulation of neutrophils in intra‐dermal lesions infected with Salmonella typhimurium in Lcn2 KO mice as compared to WT mice. This was not only due to a reduced chemotaxis but also to an impaired cellular adhesion of neutrophils in the absence of Lcn2. We herein describe a novel role of Lcn2 as an important paracrine chemoattractant and an indispensable factor for neutrophil function in inflammation.     

Lipocalin‐2 ensures host defense against Salmonella Typhimurium by controlling macrophage iron homeostasis and immune response

Lipocalin‐2 (Lcn2) is an innate immune peptide with pleiotropic effects. Lcn2 binds iron‐laden bacterial siderophores, chemo‐attracts neutrophils and has immunomodulatory and apoptosis‐regulating effects. In this study, we show that upon infection with Salmonella enterica serovar Typhimurium, Lcn2 promotes iron export from Salmonella‐infected macrophages, which reduces cellular iron content and enhances the generation of pro‐inflammatory cytokines. Lcn2 represses IL‐10 production while augmenting Nos2, TNF‐α, and IL‐6 expression. Lcn2^?/? macrophages have elevated IL‐10 levels as a consequence of increased iron content. The crucial role of Lcn‐2/IL‐10 interactions was further demonstrated by the greater ability of Lcn2^?/? IL‐10^?/? macrophages and mice to control intracellular Salmonella proliferation in comparison to Lcn2^?/? counterparts. Overexpression of the iron exporter ferroportin‐1 in Lcn2^?/? macrophages represses IL‐10 and restores TNF‐α and IL‐6 production to the levels found in wild‐type macrophages, so that killing and clearance of intracellular Salmonella is promoted. Our observations suggest that Lcn2 promotes host resistance to Salmonella Typhimurium infection by binding bacterial siderophores and suppressing IL‐10 production, and that both functions are linked to its ability to shuttle iron from macrophages.     

Single dose vaccine based on biodegradable polyanhydride microspheres can modulate immune response mechanism

This study focuses on the development of single dose vaccines based on biodegradable polyanhydride microspheres that have the unique capability to modulate the immune response mechanism. The polymer system employed consists of copolymers of 1,6-bis(p-carboxyphenoxy)hexane and sebacic acid. Two copolymer formulations that have been shown to provide extended release kinetics and protein stability were investigated. Using tetanus toxoid (TT) as a model antigen, in vivo studies in C3H/HeOuJ mice demonstrated that the encapsulation procedure preserves the immunogenicity of the TT. The polymer itself exhibited an adjuvant effect, enhancing the immune response to a small dose of TT. The microspheres provided a prolonged exposure to TT sufficient to induce both a primary and a secondary immune response (i.e., high antibody titers) with high-avidity antibody production, without requiring an additional administration. Antigen-specific proliferation 28 weeks after a single immunization indicated that immunization with the polyanhydride microspheres generated long-lived memory cells and plasma cells (antibody-secreting B cells) that generally do not occur without maturation signals from T helper cells. Furthermore, by altering the vaccine formulation, the overall strength of the T helper type 2 immune response was selectively diminished, resulting in a balanced immune response, without reducing the overall titer. This result is striking, considering free TT induces a T helper type 2 immune response, and has important implications for developing vaccines to intracellular pathogens. The ability to selectively tune the immune response without the administration of additional cytokines or noxious adjuvants is a unique feature of this delivery vehicle that may make it an excellent candidate for vaccine development.     

Microphase separation in bioerodible copolymers for drug delivery

This research examines the microstructure of bioerodible polyanhydrides with an eye towards precise design of drug delivery devices. Our main hypothesis is that the bioerodible copolymer poly(1,6-bis-p-carboxyphenoxyhexane-co-sebacic anhydride) (CPH : SA) undergoes micro-phase separation at certain copolymer compositions due to differences in relative hydrophobicity of the co-monomers, resulting in thermodynamic partitioning of drugs incorporated into these copolymers. We investigate the thermal properties, degree of crystallinity, and surface microstructure of several compositions of CPH : SA using differential scanning calorimetry (DSC), wide-angle X-ray diffraction (WAXD), and atomic force microscopy (AFM). We observe that the degree of crystallinity decreases, while the crystal lamellar thickness increases with CPH content. Phase-imaging using AFM indicates the presence of micro-domains in 20 : 80 and 80 : 20 CPH : SA, while poly(SA) and 50 : 50 CPH : SA show no micro-phase separation. Finally, drug-polymer interactions are studied by loading the polymers with different amounts of brilliant blue (hydrophilic) and p-nitroaniline (hydrophobic). DSC and WAXD analysis shows that loading hydrophobic drugs into relatively hydrophobic polymers (poly(SA)) lowers melting point that becomes more pronounced with increased drug loading.     

Novel polyelectrolyte complexes based on poly(methacrylic acid)-bis(2-aminopropyl)poly(ethylene glycol) for oral protein delivery

In the present investigation a simple and effective strategy was employed for the development of pH-sensitive self-assembling microparticles based on poly(methacrylic acid) (PMAA)-bis(2-aminopropyl)poly(ethylene glycol) (APEG), and their efficiency in oral protein delivery was evaluated. An inter-ionic gelation process was employed for the preparation of microparticles and particles were obtained spontaneously during the process without using any surfactants or stabilizers. Particle size analysis was carried out to measure average particle size and surface morphology was evaluated using scanning electron microscopy (SEM). Bovine serum albumin (BSA) was incorporated onto these microparticles to evaluate the loading and release properties of the matrix. PMAA-APEG microparticles displayed pH responsive release profile, as less than 10% of encapsulated BSA was released at pH 1.2 in 2 h and more than 80% of loaded protein was released within 3 h at pH 7.4. Carboxymethyl beta-cyclodextrin (CM beta CD)-insulin non-covalent inclusion complex was prepared to enhance the stability of insulin formulations and complex formation was analyzed by fluorescence spectroscopic studies. CM beta CD-complexed insulin was encapsulated into PMAA-APEG microparticles by a diffusion filling method and biological activity of entrapped insulin was evaluated using an ELISA. Finally mucoadhesive studies of PMAA-APEG microparticles were carried out on freshly excised rat intestinal mucosa at neutral pH to establish the adhesive nature of the material.