Triggered Release of Bacteriophage K from Agarose/Hyaluronan Hydrogel Matrixes by <i>Staphylococcus aureus</i> Virulence Factors

Bean, Jessica; Alves, Diana R.; Laabei, Maisem; Esteban, Patricia Perez; Thet, Naing Tun; Enright, Mark C.; Jenkins, A. Toby A.

doi:10.1021/cm503974g

Cited by 84 publications

(56 citation statements)

References 49 publications

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“…In future different phage fomulations may need to be developed targeting phage release in the appropriate intestinal region perhaps using more specific infection related triggers e.g. enzymes or toxins released by the bacterium causing the infection [95]. …”

Section: Discussionmentioning

confidence: 99%

Microencapsulation of Clostridium difficile specific bacteriophages using microfluidic glass capillary devices for colon delivery using pH triggered release

et al. 2017

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The prevalence of pathogenic bacteria acquiring multidrug antibiotic resistance is a global health threat to mankind. This has motivated a renewed interest in developing alternatives to conventional antibiotics including bacteriophages (viruses) as therapeutic agents. The bacterium Clostridium difficile causes colon infection and is particularly difficult to treat with existing antibiotics; phage therapy may offer a viable alternative. The punitive environment within the gastrointestinal tract can inactivate orally delivered phages. C. difficile specific bacteriophage, myovirus CDKM9 was encapsulated in a pH responsive polymer (Eudragit® S100 with and without alginate) using a flow focussing glass microcapillary device. Highly monodispersed core-shell microparticles containing phages trapped within the particle core were produced by in situ polymer curing using 4-aminobenzoic acid dissolved in the oil phase. The size of the generated microparticles could be precisely controlled in the range 80 μm to 160 μm through design of the microfluidic device geometry and by varying flow rates of the dispersed and continuous phase. In contrast to free ‘naked’ phages, those encapsulated within the microparticles could withstand a 3 h exposure to simulated gastric fluid at pH 2 and then underwent a subsequent pH triggered burst release at pH 7. The significance of our research is in demonstrating that C. difficile specific phage can be formulated and encapsulated in highly uniform pH responsive microparticles using a microfluidic system. The microparticles were shown to afford significant protection to the encapsulated phage upon prolonged exposure to an acid solution mimicking the human stomach environment. Phage encapsulation and subsequent release kinetics revealed that the microparticles prepared using Eudragit® S100 formulations possess pH responsive characteristics with phage release triggered in an intestinal pH range suitable for therapeutic purposes. The results reported here provide proof-of-concept data supporting the suitability of our approach for colon targeted delivery of phages for therapeutic purposes.

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Section: Discussionmentioning

confidence: 99%

Microencapsulation of Clostridium difficile specific bacteriophages using microfluidic glass capillary devices for colon delivery using pH triggered release

et al. 2017

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“…Ensuring activity, stability and dosage conditions are correct (especially when considering biological material), is crucial to successful administration in order to maximise the therapeutic benefit and to reduce any potential side effects. The triggered release of a therapeutic agent (small molecule, protein or virus) may rely on a variety of external stimuli in order to release the active cargo, including pH, temperature, ultrasound, magnetism or biomarker signals [24], [25]. Utilising the difference between the healthy and the diseased state may provide certain conditions whereby treatment can be administered in a controlled fashion.…”

Section: Introductionmentioning

confidence: 99%

Thermally triggered release of the bacteriophage endolysin CHAPK and the bacteriocin lysostaphin for the control of methicillin resistant Staphylococcus aureus (MRSA)

Hathaway

Ajuebor

Stephens

et al. 2017

Journal of Controlled Release

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Staphylococcus aureus infections of the skin and soft tissue pose a major concern to public health, largely owing to the steadily increasing prevalence of drug resistant isolates. As an alternative mode of treatment both bacteriophage endolysins and bacteriocins have been shown to possess antimicrobial efficacy against multiple species of bacteria including otherwise drug resistant strains. Despite this, the administration and exposure of such antimicrobials should be restricted until required in order to discourage the continued evolution of bacterial resistance, whilst maintaining the activity and stability of such proteinaceous structures. Utilising the increase in skin temperature during infection, the truncated bacteriophage endolysin CHAPK and the staphylococcal bacteriocin lysostaphin have been co-administered in a thermally triggered manner from Poly(N-isopropylacrylamide) (PNIPAM) nanoparticles. The thermoresponsive nature of the PNIPAM polymer has been employed in order to achieve the controlled expulsion of a synergistic enzybiotic cocktail consisting of CHAPK and lysostaphin. The point at which this occurs is modifiable, in this case corresponding to the threshold temperature associated with an infected wound. Consequently, bacterial lysis was observed at 37 °C, whilst growth was maintained at the uninfected skin temperature of 32 °C.

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“…To confirm and quantify the degradation of the synthesized HYAMA by the target enzyme hyal, the breakdown product N ‐acetylglucosamine (NAG) (Figure S5, Supporting Information), was quantified using a modified carbazole assay published by Bean et al in 2014 . The assay is based on the colorimetric method for the quantification of N ‐acetylamino sugars by UV–vis spectroscopy, reported for the first time by Reissig et al in 1955 .…”

Section: Resultsmentioning

confidence: 99%

“…Interestingly, high levels of hyal are observed just before the exponential growth phase sets in. This enzymatic degradation of HYA‐based polymers by hyal has been exploited in signaling hydrogels and nanocapsules before for sensing high levels of the enzyme that indicate a bacterial infection …”

Section: Introductionmentioning

confidence: 99%

Hyaluronic Acid–Modified Porous Silicon Films for the Electrochemical Sensing of Bacterial Hyaluronidase

Tücking

Vasani

Cavallaro

et al. 2018

Macromol. Rapid Commun.

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The development of enzyme-responsive hyaluronic acid methacrylate (HYAMA)-coated porous silicon (pSi) films and their application in electrochemical diagnostic devices for the in situ detection of the enzyme hyaluronidase (hyal), which is secreted by Staphylococcus aureus (S. aureus) bacteria, are reported. The approach relies on a HYAMA-pSi electrode made of thermally hydrocarbonized pSi (pSi-THC) that is impregnated with crosslinked HYAMA/polyethylene glycol diacrylate (PEGDA) hydrogels. The enzymatic degradation of HYAMA by bacterial hyal is monitored by differential pulse voltammetry (DPV) utilizing pSi-THC as a working electrode and ferro/ferricyanide (FF) as external redox probe. The degradation of HYAMA results in reduced diffusion of the redox probe through the partially charged film, thereby enabling the detection of hyal by DPV. In addition to the determination of the concentration-dependent response in NaOAc buffer (pH 5.2), the detection of hyal as indicator for the presence of S. aureus bacteria above a threshold level in bacterial supernatants and artificial wound fluid is highlighted.

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Triggered Release of Bacteriophage K from Agarose/Hyaluronan Hydrogel Matrixes by Staphylococcus aureus Virulence Factors

Cited by 84 publications

References 49 publications

Microencapsulation of Clostridium difficile specific bacteriophages using microfluidic glass capillary devices for colon delivery using pH triggered release

Microencapsulation of Clostridium difficile specific bacteriophages using microfluidic glass capillary devices for colon delivery using pH triggered release

Thermally triggered release of the bacteriophage endolysin CHAPK and the bacteriocin lysostaphin for the control of methicillin resistant Staphylococcus aureus (MRSA)

Hyaluronic Acid–Modified Porous Silicon Films for the Electrochemical Sensing of Bacterial Hyaluronidase

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