Your search keyword '"Shannon L. Haughney"' showing total 11 results

1. Nanotherapeutic delivery of antibiotic cocktail enhances intra-macrophage killing of Mycobacterium marinum

Author

Andrea M. Binnebose, Adam S. Mullis, Shannon L. Haughney, Balaji Narasimhan, and Bryan H. Bellaire

Subjects

Mycobacterium, nanotherapeutic, antimicrobial delivery, antibiotic cocktail, intracellular delivery drug release, Therapeutics. Pharmacology, RM1-950

Abstract

Mycobacterium marinum is a waterborne pathogen responsible for tuberculosis-like infections in cold-blooded animals and is an opportunistic pathogen in humans. M. marinum is the closest genetic relative of the Mycobacterium tuberculosis complex and is a reliable surrogate for drug susceptibility testing. We synthesized and evaluated two nanoparticle (NP) formulations for compatibility with rifampicin, isoniazid, pyrazinamide, and ethambutol (PIRE), the front-line antimycobacterial drugs used in combination against active tuberculosis infections. Improved in vitro antimicrobial activity was observed with encapsulated rifampicin alone or in a cocktail of drugs formulated through co-encapsulation in amphiphilic polyanhydride NPs. Broth antimicrobial testing revealed that the encapsulation of PIRE in NP resulted in a significant increase in antimicrobial activity, with the benefit over soluble formulations at biologically relevant concentrations ranging from >10 to >3,000 fold. M. marinum-infected human macrophages treated with NP-PIRE were cleared of viable bacteria in 48 h following a single treatment, representing a >4 log reduction in colony-forming units and a >2,000-fold increase in antimicrobial activity. The amphiphilic polyanhydride nanoparticles demonstrated the ability to co-encapsulate PIRE antibiotics and enhance their antimicrobial activity against M. marinum in infected macrophages in culture and in vitro. These data suggest that polyanhydride nanoparticles are a promising nanotherapeutic for combatting Mycobacterium infections through improved intracellular targeting of encapsulated antibiotics.

Published

2023

2. Room Temperature Stable PspA-Based Nanovaccine Induces Protective Immunity

Author

Danielle A. Wagner-Muñiz, Shannon L. Haughney, Sean M. Kelly, Michael J. Wannemuehler, and Balaji Narasimhan

Subjects

pneumococcal infections, pneumococcal surface protein A, polyanhydride, nanovaccine, room temperature stability, Immunologic diseases. Allergy, RC581-607

Abstract

Streptococcus pneumoniae is a major causative agent of pneumonia, a debilitating disease particularly in young and elderly populations, and is the leading worldwide cause of death in children under the age of five. While there are existing vaccines against S. pneumoniae, none are protective across all serotypes. Pneumococcal surface protein A (PspA), a key virulence factor of S. pneumoniae, is an antigen that may be incorporated into future vaccines to address the immunological challenges presented by the diversity of capsular antigens. PspA has been shown to be immunogenic and capable of initiating a humoral immune response that is reactive across approximately 94% of pneumococcal strains. Biodegradable polyanhydrides have been studied as a nanoparticle-based vaccine (i.e., nanovaccine) platform to stabilize labile proteins, to provide adjuvanticity, and enhance patient compliance by providing protective immunity in a single dose. In this study, we designed a room temperature stable PspA-based polyanhydride nanovaccine that eliminated the need for a free protein component (i.e., 100% encapsulated within the nanoparticles). Mice were immunized once with the lead nanovaccine and upon challenge, presented significantly higher survival rates than animals immunized with soluble protein alone, even with a 25-fold reduction in protein dose. This lead nanovaccine formulation performed similarly to protein adjuvanted with Alum, however, with much less tissue reactogenicity at the site of immunization. By eliminating the free PspA from the nanovaccine formulation, the lead nanovaccine was efficacious after being stored dry for 60 days at room temperature, breaking the need for maintaining the cold chain. Altogether, this study demonstrated that a single dose PspA-based nanovaccine against S. pneumoniae induced protective immunity and provided thermal stability when stored at room temperature for at least 60 days.

Published

2018

3. Polyanhydride Nanoparticle Delivery Platform Dramatically Enhances Killing of Filarial Worms.

Author

Andrea M Binnebose, Shannon L Haughney, Richard Martin, Paula M Imerman, Balaji Narasimhan, and Bryan H Bellaire

Subjects

Arctic medicine. Tropical medicine, RC955-962, Public aspects of medicine, RA1-1270

Abstract

Filarial diseases represent a significant social and economic burden to over 120 million people worldwide and are caused by endoparasites that require the presence of symbiotic bacteria of the genus Wolbachia for fertility and viability of the host parasite. Targeting Wolbachia for elimination is a therapeutic approach that shows promise in the treatment of onchocerciasis and lymphatic filariasis. Here we demonstrate the use of a biodegradable polyanhydride nanoparticle-based platform for the co-delivery of the antibiotic doxycycline with the antiparasitic drug, ivermectin, to reduce microfilarial burden and rapidly kill adult worms. When doxycycline and ivermectin were co-delivered within polyanhydride nanoparticles, effective killing of adult female Brugia malayi filarial worms was achieved with approximately 4,000-fold reduction in the amount of drug used. Additionally the time to death of the macrofilaria was also significantly reduced (five-fold) when the anti-filarial drug cocktail was delivered within polyanhydride nanoparticles. We hypothesize that the mechanism behind this dramatically enhanced killing of the macrofilaria is the ability of the polyanhydride nanoparticles to behave as a Trojan horse and penetrate the cuticle, bypassing excretory pumps of B. malayi, and effectively deliver drug directly to both the worm and Wolbachia at high enough microenvironmental concentrations to cause death. These provocative findings may have significant consequences for the reduction in the amount of drug and the length of treatment required for filarial infections in terms of patient compliance and reduced cost of treatment.

Published

2015

4. Safety and biocompatibility of injectable vaccine adjuvants composed of thermogelling block copolymer gels

Author

Justin R. Adams, Surya K. Mallapragada, Michael J. Wannemuehler, Shannon L. Haughney, Balaji Narasimhan, and Sujata Senapati

Subjects

Vinyl alcohol, Materials science, Biocompatibility, medicine.medical_treatment, 0206 medical engineering, Biomedical Engineering, Biocompatible Materials, Poloxamer, 02 engineering and technology, Pharmacology, Kidney Function Tests, Methacrylate, Injections, Biomaterials, Subcutaneous injection, chemistry.chemical_compound, Adjuvants, Immunologic, medicine, Animals, Triglycerides, Inflammation, Vaccines, Temperature, Metals and Alloys, Cationic polymerization, Hydrogels, 021001 nanoscience & nanotechnology, 020601 biomedical engineering, Mice, Inbred C57BL, Cholesterol, chemistry, Organ Specificity, Polyvinyl Alcohol, Self-healing hydrogels, Ceramics and Composites, Alum Compounds, Female, Immunization, 0210 nano-technology, Gels, Adjuvant, Biomarkers

Abstract

Injectable thermogelling polymers have been recently investigated as novel adjuvants and delivery systems for next generation vaccines. As research into natural and synthetic biocompatible polymers progresses, the safety and biocompatibility of these compounds is of paramount importance. We have developed cationic pentablock copolymer (PBC) vaccine adjuvants based on Pluronic F127, a thermogelling triblock copolymer that has been approved by the FDA for multiple applications, and methacrylated poly(diethyl amino)ethyl methacrylate outer blocks. These novel materials have been demonstrated to effectively create an antigen depot, minimally impact antigen stability, and enhance the immune response to antigens (i.e., adjuvanticity) in mice. In this work, we investigated the safety and biocompatibility of the parent triblock Pluronic gels and the cationic PBC gels in mice. Histological analysis showed no injection site reactions and no damage to the liver or kidneys was observed upon administering the block copolymer formulations. However, the subcutaneous injection of a thermogelling Pluronic solution induced increased levels of lipids in the blood, with no further deleterious effects observed from the addition of the cationic outer blocks. This hyperlipidemia resolved within 30 days after the administration of the Pluronic formulation. To mitigate this adverse effect, the vaccine adjuvant formulations were modified by adding poly(vinyl alcohol), which allowed gelation, while reducing the amount of Pluronic in the formulation. This modified formulation abrogated the observed hyperlipidemia and no adverse effects were observed in the serum through biomarker analysis or at the injection site (i.e., inflammation) in comparison to the responses induced by administration of saline or incomplete Freund's adjuvant. These studies provide a foundation to developing these gels as adjuvants for next generation vaccines. © 2019 Wiley Periodicals, Inc. J Biomed Mater Res Part A: 107A: 1754-1762, 2019.

Published

2019

5. Nanotherapeutic provides dose sparing and improved antimicrobial activity against Brucella melitensis infections

Author

Nathan Peroutka-Bigus, Paul Lueth, Adam S. Mullis, Bryan H. Bellaire, Balaji Narasimhan, Andrea M. Binnebose, and Shannon L. Haughney

Subjects

medicine.drug_class, Antibiotics, Pharmaceutical Science, 02 engineering and technology, Pharmacology, Brucellosis, 03 medical and health sciences, Mice, Drug Delivery Systems, In vivo, medicine, Brucella melitensis, Animals, 030304 developmental biology, Doxycycline, 0303 health sciences, Mice, Inbred BALB C, biology, business.industry, Intracellular parasite, 021001 nanoscience & nanotechnology, Antimicrobial, biology.organism_classification, Anti-Bacterial Agents, Drug Liberation, Nanomedicine, RAW 264.7 Cells, Delayed-Action Preparations, Drug delivery, Nanoparticles, Female, Rifampin, 0210 nano-technology, business, Rifampicin, medicine.drug

Abstract

New therapies are needed to treat chronic bacterial diseases and intracellular pathogens, in particular, are very difficult to manage. The use of nanotherapeutics represents an approach to exploit size and charge of biological membranes to overcome barriers for treatment of intracellular pathogens including Brucella melitensis. In this work, polyanhydride nanoparticles comprised of copolymers of sebacic acid, 1,6-bis(p-carboxyphenoxy)hexane, and 1,8-bis(p-carboxyphenoxy)-3,6-dioxaoctane were synthesized to encapsulate antimicrobial compounds doxycycline and rifampicin. The nanoparticles demonstrated sustained release of rifampicin for a week with the antimicrobial activity peaking at 72 h and lasting up to a week. Treatment of B. melitensis infected macrophages with rifampicin-containing nanoparticles rapidly eliminated viable intracellular bacteria following 48 h of treatment and pretreatment with the nano-formulations prevented intracellular infection in contrast to soluble drug controls. Treatment of infected BALB/c mice with a nanoparticle cocktail containing doxycycline and rifampicin for five days decreased bacterial burden by three log10 in the liver. Extended release of antibiotics was demonstrated in vivo by treating B. melitensis infected mice with the standard therapy of daily 0.5 mg doxycycline dose or single 0.5 mg doxycycline-encapsulated nanoparticles delivered once a week. After 3 weeks, bacterial counts in spleen and liver were statistically equal between animals treated with the weekly nano-formulation and daily soluble drug, representing a seven-fold dose sparing. Altogether, these results demonstrated that the use of nanotherapeutics was successful at increasing antimicrobial efficacy and improving in vivo activity through a combination of intracellular delivery, dose sparing, and extended release in treating chronic bacterial infections. This platform technology can also provide benefits for drug delivery against other chronic intracellular bacterial pathogens, including Mycobacterium and Burkholderia species, including treatments against antibiotic-resistant infections.

Published

2018

6. Efficacy of mucosal polyanhydride nanovaccine against respiratory syncytial virus infection in the neonatal calf

Author

Jamie Henningson, Balaji Narasimhan, Jodi L. McGill, Randy E. Sacco, Sean M. Kelly, Shannon L. Haughney, Pankaj Kumar, and Savannah Speckhart

Subjects

0301 basic medicine, Male, lcsh:Medicine, Cattle Diseases, Respiratory Syncytial Virus, Bovine, 02 engineering and technology, Respiratory Syncytial Virus Infections, Antibodies, Viral, Virus, Article, 03 medical and health sciences, Immune system, Immunity, Polyanhydrides, Respiratory Syncytial Virus Vaccines, Medicine, Animals, Viral shedding, lcsh:Science, Lung, Immunity, Cellular, Multidisciplinary, biology, business.industry, Immunogenicity, lcsh:R, Vaccination, 021001 nanoscience & nanotechnology, 3. Good health, Respiratory Syncytial Viruses, 030104 developmental biology, medicine.anatomical_structure, Animals, Newborn, Respiratory Syncytial Virus, Human, Immunology, Antibody Formation, biology.protein, Nanoparticles, lcsh:Q, Cattle, Female, Antibody, 0210 nano-technology, business, Viral load, Respiratory tract

Abstract

Human respiratory syncytial virus (HRSV) is a leading cause of severe acute lower respiratory tract infection in infants and children worldwide. Bovine RSV (BRSV) is closely related to HRSV and a significant cause of morbidity in young cattle. BRSV infection in calves displays many similarities to RSV infection in humans, including similar age dependency and disease pathogenesis. Polyanhydride nanoparticle-based vaccines (i.e., nanovaccines) have shown promise as adjuvants and vaccine delivery vehicles due to their ability to promote enhanced immunogenicity through the route of administration, provide sustained antigen exposure, and induce both antibody- and cell-mediated immunity. Here, we developed a novel, mucosal nanovaccine that encapsulates the post-fusion F and G glycoproteins from BRSV into polyanhydride nanoparticles and determined the efficacy of the vaccine against RSV infection using a neonatal calf model. Calves receiving the BRSV-F/G nanovaccine exhibited reduced pathology in the lungs, reduced viral burden, and decreased virus shedding compared to unvaccinated control calves, which correlated with BRSV-specific immune responses in the respiratory tract and peripheral blood. Our results indicate that the BRSV-F/G nanovaccine is highly immunogenic and, with optimization, has the potential to significantly reduce the disease burden associated with RSV infection in both humans and animals.

Published

2018

7. Effect of nanovaccine chemistry on humoral immune response kinetics and maturation

Author

Michael J. Wannemuehler, Shannon L. Haughney, Paola M. Boggiatto, Kathleen A. Ross, and Balaji Narasimhan

Subjects

Yersinia pestis, Biological Availability, Theranostic Nanomedicine, Mice, Immune system, Immunity, Polyanhydrides, Animals, General Materials Science, Avidity, Lung, Administration, Intranasal, Plague, Plague Vaccine, biology, Antibody titer, biology.organism_classification, Immunity, Humoral, Mice, Inbred C57BL, Immunization, Antibody Formation, Humoral immunity, Immunology, Nasal administration

Abstract

Acute respiratory infections represent a significant portion of global morbidity and mortality annually. There is a critical need for efficacious vaccines against respiratory pathogens. To vaccinate against respiratory disease, pulmonary delivery is an attractive route because it mimics the route of natural infection and can confer both mucosal and systemic immunity. We have previously demonstrated that a single dose, intranasal vaccine based on polyanhydride nanoparticles elicited a protective immune response against Yersinia pestis for at least 40 weeks after immunization with F1-V. Herein, we investigate the effect of nanoparticle chemistry and its attributes on the kinetics and maturation of the antigen-specific serum antibody response. We demonstrate that manipulation of polyanhydride nanoparticle chemistry facilitated differential kinetics of development of antibody titers, avidity, and epitope specificity. The results provide new insights into the underlying role(s) of nanoparticle chemistry in providing long-lived humoral immunity and aid in the rational design of nanovaccine formulations to induce long-lasting and mature antibody responses.

Published

2014

8. Polyanhydride Nanoparticle Delivery Platform Dramatically Enhances Killing of Filarial Worms

Author

Shannon L. Haughney, Richard J. Martin, Andrea M. Binnebose, Bryan H. Bellaire, Balaji Narasimhan, and Paula M. Imerman

Subjects

lcsh:Arctic medicine. Tropical medicine, lcsh:RC955-962, Brugia malayi, Filariasis, Ivermectin, Parasitic Sensitivity Tests, Polyanhydrides, parasitic diseases, medicine, Animals, Lymphatic filariasis, Doxycycline, Anthelmintics, Drug Carriers, biology, lcsh:Public aspects of medicine, Public Health, Environmental and Occupational Health, lcsh:RA1-1270, medicine.disease, biology.organism_classification, Antiparasitic agent, Survival Analysis, Anti-Bacterial Agents, Infectious Diseases, Immunology, Drug delivery, Nanoparticles, Wolbachia, Locomotion, medicine.drug, Research Article

Abstract

Filarial diseases represent a significant social and economic burden to over 120 million people worldwide and are caused by endoparasites that require the presence of symbiotic bacteria of the genus Wolbachia for fertility and viability of the host parasite. Targeting Wolbachia for elimination is a therapeutic approach that shows promise in the treatment of onchocerciasis and lymphatic filariasis. Here we demonstrate the use of a biodegradable polyanhydride nanoparticle-based platform for the co-delivery of the antibiotic doxycycline with the antiparasitic drug, ivermectin, to reduce microfilarial burden and rapidly kill adult worms. When doxycycline and ivermectin were co-delivered within polyanhydride nanoparticles, effective killing of adult female Brugia malayi filarial worms was achieved with approximately 4,000-fold reduction in the amount of drug used. Additionally the time to death of the macrofilaria was also significantly reduced (five-fold) when the anti-filarial drug cocktail was delivered within polyanhydride nanoparticles. We hypothesize that the mechanism behind this dramatically enhanced killing of the macrofilaria is the ability of the polyanhydride nanoparticles to behave as a Trojan horse and penetrate the cuticle, bypassing excretory pumps of B. malayi, and effectively deliver drug directly to both the worm and Wolbachia at high enough microenvironmental concentrations to cause death. These provocative findings may have significant consequences for the reduction in the amount of drug and the length of treatment required for filarial infections in terms of patient compliance and reduced cost of treatment., Author Summary Infection with the filarial endoparasites Brugia malayi and its symbiotic bacteria Wolbachia represent a significant burden to both humans and animals. Current treatment protocols include use of multiple drugs over a course of months to years, resulting in high costs, undesirable side effects, and poor patient compliance. By encapsulating two of these drugs, ivermectin and doxycycline, into biodegradable polyanhydride nanoparticles, we report the ability to effectively kill adult B. malayi with up to a 4,000-fold reduction in the amount of drug used. These results demonstrate a promising role for the use of nanoscale drug carriers to reduce both the course of treatment and the amount of drug needed to increase affordability of lymphatic filariasis treatment and enhance patient compliance.

Published

2015

9. Effective polymer adjuvants for sustained delivery of protein subunit vaccines

Author

Justin R. Adams, Surya K. Mallapragada, and Shannon L. Haughney

Subjects

Antigenicity, Materials science, Ovalbumin, Polymers, Protein subunit, Proton Magnetic Resonance Spectroscopy, Biomedical Engineering, Enzyme-Linked Immunosorbent Assay, Biochemistry, Fluorescence, Biomaterials, Antigen, Adjuvants, Immunologic, In vivo, Animals, Molecular Biology, biology, Protein Stability, Immunogenicity, Circular Dichroism, General Medicine, Poloxamer, Molecular biology, Immunity, Humoral, Mice, Inbred C57BL, Nylons, Protein Subunits, Delayed-Action Preparations, Self-healing hydrogels, Vaccines, Subunit, biology.protein, Biophysics, Methacrylates, Electrophoresis, Polyacrylamide Gel, Female, Immunization, Spectrophotometry, Ultraviolet, Porosity, Biotechnology

Abstract

We have synthesized thermogelling cationic amphiphilic pentablock copolymers that have the potential to act as injectable vaccine carriers and adjuvants that can simultaneously provide sustained delivery and enhance the immunogenicity of released antigen. While these pentablock copolymers have shown efficacy in DNA delivery in past studies, the ability to deliver both DNA and protein for subunit vaccines using the same polymeric carrier can provide greater flexibility and efficacy. We demonstrate the ability of these pentablock copolymers, and the parent triblock Pluronic copolymers to slowly release structurally intact and antigenically stable protein antigens in vitro, create an antigen depot through long-term injection-site persistence and enhance the in vivo immune response to these antigens. We show release of the model protein antigen ovalbumin in vitro from the thermogelling block copolymers with the primary, secondary and tertiary structures of the released protein unchanged compared to the native protein, and its antigenicity preserved upon release. The block copolymers form a gel at physiological temperatures that serves as an antigenic depot and persists in vivo at the site of injection for over 50days. The pentablock copolymers show a significant fivefold enhancement in the immune response compared to soluble protein alone, even 6weeks after the administration, based on measurement of antibody titers. These results demonstrate the potential of these block copolymers hydrogels to persist for several weeks and sustain the release of antigen with minimal effects on protein stability and antigenicity; and their ability to be used simultaneously as a sustained delivery device as well as a subunit vaccine adjuvant platform.

Published

2014

10. Lung deposition and cellular uptake behavior of pathogen-mimicking nanovaccines in the first 48 hours

Author

Kathleen A. Ross, Balaji Narasimhan, Michael J. Wannemuehler, Latrisha K. Petersen, Paola M. Boggiatto, and Shannon L. Haughney

Subjects

Yersinia pestis, media_common.quotation_subject, Biomedical Engineering, Pharmaceutical Science, Monophosphoryl Lipid A, Inflammation, Biomaterials, Mice, Immune system, Adjuvants, Immunologic, Polyanhydrides, medicine, Animals, Antigen-presenting cell, Internalization, Lung, media_common, Plague, Vaccines, business.industry, Pneumonia, Nanostructures, Mice, Inbred C57BL, medicine.anatomical_structure, Lipid A, Immunology, Nasal administration, Female, Immunization, medicine.symptom, business, Respiratory tract

Abstract

Pulmonary immunization poses the unique challenge of balancing vaccine efficacy with minimizing inflammation in the respiratory tract. While previous studies have shown that mice immunized intranasally with F1-V-loaded polyanhydride nanoparticles are protected from a lethal challenge with Yersinia pestis, little is known about the initial interaction between the nanoparticles and immune cells following intranasal administration. Here, the deposition within the lung and internalization by phagocytic cells of polyanhydride nanovaccines encapsulating F1-V are compared with that of soluble F1-V alone or F1-V adjuvanted with monophosphoryl lipid A (MPLA). Encapsulation of F1-V into polyanhydride nanoparticles prolonged its presence while F1-V administered with MPLA is undetectable within 48 h. The inflammation induced by the polyanhydride nanovaccine is mild compared with the marked inflammation induced by the MPLA-adjuvanted F1-V. Even though F1-V delivered with saline is detected in the lung 48 h after administration, it is known that this regimen does not elicit a protective immune response. The prolonged F1-V presence in the lung in concert with the mild inflammatory response provided by the nanovaccine provides new insights into the development of protective immune responses with a single intranasal dose.

Published

2013

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

Author

Shannon L. Haughney, Balaji Narasimhan, Latrisha K. Petersen, Amy Danielle Schoofs, Amanda E. Ramer-Tait, Janice D. King, Michael J. Wannemuehler, and David E. Briles

Subjects

Antigenicity, Immunogen, Materials science, Protein Conformation, Polyesters, Biomedical Engineering, medicine.disease_cause, Biochemistry, Virulence factor, Article, Microbiology, Biomaterials, Diffusion, Mice, Bacterial Proteins, Nanocapsules, Polyanhydrides, Streptococcus pneumoniae, Materials Testing, medicine, Animals, Particle Size, Molecular Biology, Escherichia coli, Antigens, Bacterial, Rational design, General Medicine, Bacterial vaccine, Delayed-Action Preparations, Bacterial Vaccines, Decanoic Acids, Biotechnology

Abstract

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 towards Escherichia coli. When the PspA nanoparticle formulations were administered subcutaneously to mice, the animals 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.

Published

2013