Your search keyword '"Phillips ARJ"' showing total 6 results

1. Polydopamine-Mediated Antimicrobial Lipopeptide Surface Coating for Medical Devices.

Author

Lamba S, Wang K, Lu J, Phillips ARJ, Swift S, and Sarojini V

Subjects

Humans, Particle Size, Molecular Structure, Indoles chemistry, Indoles pharmacology, Polymers chemistry, Polymers pharmacology, Anti-Bacterial Agents pharmacology, Anti-Bacterial Agents chemistry, Anti-Bacterial Agents chemical synthesis, Coated Materials, Biocompatible chemistry, Coated Materials, Biocompatible pharmacology, Microbial Sensitivity Tests, Biofilms drug effects, Surface Properties, Materials Testing, Lipopeptides chemistry, Lipopeptides pharmacology

Abstract

Biofilm formation on medical implants such as catheters is a major issue which needs to be addressed as it leads to severe health care associated infections. This study explored the design and synthesis of a polydopamine-lipopeptide based antimicrobial coating. The coating was used to modify the surface of Ultrathane Catheters. The lipopeptide SL1.15 with an N -terminal cysteine was covalently conjugated to the polydopamine modified catheters via a Michael addition reaction between the thiol moiety in the peptide and the aromatic ring in the polydopamine layer. The immobilization of the peptide on the polydopamine coated catheters was confirmed using water contact angle, X-ray photoelectron spectroscopy, atomic force microscopy, and scanning electron microscopy (SEM). The antimicrobial activity of the coated catheters investigated using drug resistant and clinical strains of Gram-positive (MRSA and S. aureus ) and Gram-negative ( E. coli , A. baumannii , and P. aeruginosa ) bacteria revealed that lipopeptide immobilization inhibited >90% bacterial adhesion to the catheter surface. Additionally, biofilm assays against MRSA and E. coli revealed that the lipopeptide immobilized catheters inhibited >85% bacterial growth after 1 week incubation. Finally, the cytotoxicity profile of the catheters using the human dermal fibroblast, and the human embryonic kidney cell lines demonstrated that the polydopamine-lipopeptide coating was not toxic after 72 h incubation.

Published

2024

2. Intestinal Lymphatic Biology, Drug Delivery, and Therapeutics: Current Status and Future Directions.

Author

Reddiar SB, Xie Y, Abdallah M, Han S, Hu L, Feeney OM, Gracia G, Anshabo A, Lu Z, Farooq MA, Styles IK, Phillips ARJ, Windsor JA, Porter CJH, Cao E, and Trevaskis NL

Subjects

Humans, Animals, Intestines drug effects, Pharmaceutical Preparations administration & dosage, Pharmaceutical Preparations metabolism, Pharmaceutical Preparations chemistry, Drug Delivery Systems methods, Lymphatic System metabolism, Lymphatic System physiology

Abstract

Historically, the intestinal lymphatics were considered passive conduits for fluids, immune cells, dietary lipids, lipid soluble vitamins, and lipophilic drugs. Studies of intestinal lymphatic drug delivery in the late 20th century focused primarily on the drugs' physicochemical properties, especially high lipophilicity, that resulted in intestinal lymphatic transport. More recent discoveries have changed our traditional view by demonstrating that the lymphatics are active, plastic, and tissue-specific players in a range of biological and pathological processes, including within the intestine. These findings have, in turn, inspired exploration of lymph-specific therapies for a range of diseases, as well as the development of more sophisticated strategies to actively deliver drugs or vaccines to the intestinal lymph, including a range of nanotechnologies, lipid prodrugs, and lipid-conjugated materials that "hitchhike" onto lymphatic transport pathways. With the increasing development of novel therapeutics such as biologics, there has been interest in whether these therapeutics are absorbed and transported through intestinal lymph after oral administration. Here we review the current state of understanding of the anatomy and physiology of the gastrointestinal lymphatic system in health and disease, with a focus on aspects relevant to drug delivery. We summarize the current state-of-the-art approaches to deliver drugs and quantify their uptake into the intestinal lymphatic system. Finally, and excitingly, we discuss recent examples of significant pharmacokinetic and therapeutic benefits achieved via intestinal lymphatic drug delivery. We also propose approaches to advance the development and clinical application of intestinal lymphatic delivery strategies in the future. SIGNIFICANCE STATEMENT: This comprehensive review details the understanding of the anatomy and physiology of the intestinal lymphatic system in health and disease, with a focus on aspects relevant to drug delivery. It highlights current state-of-the-art approaches to deliver drugs to the intestinal lymphatics and the shift toward the use of these strategies to achieve pharmacokinetic and therapeutic benefits for patients., (Copyright © 2024 by The American Society for Pharmacology and Experimental Therapeutics.)

Published

2024

3. Comment on Plutecki et al. The Anatomy of the Thoracic Duct and Cisterna Chyli: A Meta-Analysis with Surgical Implications. J. Clin. Med. 2024, 13 , 4285.

Author

O'Hagan LA, Phillips ARJ, Windsor JA, and Mirjalili SA

Abstract

We read, with interest, Plutecki and colleagues' systematic review of the anatomy of the thoracic duct and cisterna chyli, recently published in JCM [...].

Published

2024

4. Lymphatic Uptake of a Highly Lipophilic Protease Inhibitor Prodrug from a Lipid-Based Formulation is Limited by Instability in the Intestine.

Author

Xie Y, Lu Z, Styles IK, Reddiar SB, Phillips ARJ, Windsor JA, Porter CJH, Han S, and Trevaskis NL

Subjects

Dabigatran pharmacokinetics, Dabigatran chemistry, Lipids chemistry, Lymph metabolism, Drug Stability, Intestinal Mucosa metabolism, Emulsions, Animals, Protease Inhibitors pharmacokinetics, Protease Inhibitors administration & dosage, Protease Inhibitors chemistry, Male, Rats, Rats, Sprague-Dawley, Intestinal Absorption drug effects, Prodrugs pharmacokinetics, Prodrugs chemistry

Abstract

Dabigatran etexilate (DABE) is a lipophilic double alkyl ester prodrug of dabigatran (DAB) which is a serine protease inhibitor used clinically as an anticoagulant. Recently, translocation of serine protease enzymes, including trypsin, from the gut into the mesenteric lymph and then blood has been associated with organ failure in acute and critical illnesses (ACIs). Delivery of DABE into mesenteric lymph may thus be an effective strategy to prevent organ failure in ACIs. Most drugs access the mesenteric lymph in low quantities following oral administration, as they are rapidly transported away from the intestine via the blood. Here, we examine the potential to deliver DABE into the mesenteric lymph by promoting association with lymph lipid transport pathways via co-administration with a lipid-based formulation (LBF). A series of self-emulsifying LBFs were designed and tested in vitro for their potential to form stable DABE loaded emulsions and keep DABE solubilised and stable over time in simulated gastrointestinal conditions. The LBFs were found to form fine emulsions with a droplet size of 214 ± 30 nm and DABE was stable in the formulation. The stability of DABE in vitro in simulated intestinal conditions, plasma and lymph samples was also evaluated to ensure stability in collected samples and to evaluate whether the prodrug is likely to release active DAB. Ultimately, a highly uniform and stable self-emulsifying Type III A LBF of DABE was chosen for progression into in vivo studies in male Sprague Dawley rats to confirm the lymphatic uptake and plasma pharmacokinetics. Both in vitro and in vivo in plasma and lymph, DABE was rapidly converted to an intermediate and DAB. The main species present in vivo in both plasma and lymph was DAB and mass transport of DABE and DAB in lymph was minimal (∼0.5 % of dose). Importantly, the concentration of DABE in lymph was substantially (20-176 fold) higher than in plasma, supporting that if the prodrug were stable and did not convert to DAB in the intestine, it would be lymphatically transported. Future studies will therefore focus on optimizing the design of the prodrug and formulation to improve stability during absorption and further promote lymphatic uptake., Competing Interests: Declaration of competing interest N.L. Trevaskis is an Editorial Board Member for Journal of Pharmaceutical Sciences and was not involved in the editorial review or the decision to publish this article. The authors declare the following financial interests/personal relationships which may be considered as potential competing interests: N.L. Trevaskis, C.J.H. Porter, S. Han are inventors of a lymph-directing glyceride prodrug technology that has been patented and licensed to PureTech Health, Boston. The current work is not related to the glyceride prodrug technology. It evaluates and describe lymphatic uptake of a lipophilic ester prodrug of different molecular structure., (Copyright © 2024 American Pharmacists Association. Published by Elsevier Inc. All rights reserved.)

Published

2024

5. Computational fluid dynamic modeling of the lymphatic system: a review of existing models and future directions.

Author

Jayathungage Don TD, Safaei S, Maso Talou GD, Russell PS, Phillips ARJ, and Reynolds HM

Subjects

Lymphatic System physiology, Computer Simulation, Physics, Hydrodynamics, Lymphatic Vessels physiology

Abstract

Historically, research into the lymphatic system has been overlooked due to both a lack of knowledge and limited recognition of its importance. In the last decade however, lymphatic research has gained substantial momentum and has included the development of a variety of computational models to aid understanding of this complex system. This article reviews existing computational fluid dynamic models of the lymphatics covering each structural component including the initial lymphatics, pre-collecting and collecting vessels, and lymph nodes. This is followed by a summary of limitations and gaps in existing computational models and reasons that development in this field has been hindered to date. Over the next decade, efforts to further characterize lymphatic anatomy and physiology are anticipated to provide key data to further inform and validate lymphatic fluid dynamic models. Development of more comprehensive multiscale- and multi-physics computational models has the potential to significantly enhance the understanding of lymphatic function in both health and disease., (© 2023. The Author(s).)

Published

2024

6. Investigation of Staphylococcus aureus Biofilm-Associated Toxin as a Potential Squamous Cell Carcinoma Therapeutic.

Author

Ong ZX, Kannan B, Phillips ARJ, and Becker DL

Abstract

Cancer therapies developed using bacteria and their components have been around since the 19th century. Compared to traditional cancer treatments, the use of bacteria-derived compounds as cancer therapeutics could offer a higher degree of specificity, with minimal off-target effects. Here, we explored the use of soluble bacteria-derived toxins as a potential squamous cell carcinoma (SCC) therapeutic. We optimized a protocol to generate Staphylococcus aureus biofilm-conditioned media (BCM), where soluble bacterial products enriched in the development of biofilms were isolated from a bacterial culture and applied to SCC cell lines. Bioactive components of S. aureus ATCC 29213 (SA29213) BCM display selective toxicity towards cancerous human skin SCC-12 at low doses, while non-cancerous human keratinocyte HaCaT and fibroblast BJ-5ta are minimally affected. SA29213 BCM treatment causes DNA damage to SCC-12 and initiates Caspase 3-dependent-regulated cell death. The use of the novel SA29213 bursa aurealis transposon mutant library led to the identification of S. aureus alpha hemolysin as the main bioactive compound responsible for the observed SCC-12-specific toxicity. The antibody neutralisation of Hla eradicates the cytotoxicity of SA29213 BCM towards SCC-12. Hla displays high SCC-12-specific toxicity, which is exerted primarily through Hla-ADAM10 interaction, Hla oligomerisation, and pore formation. The high target specificity and potential to cause cell death in a controlled manner highlight SA29213 Hla as a good candidate as an alternative SCC therapeutic.

Published

2024