7 research outputs found
Synthesis of photo-excited Chlorin e6 conjugated silica nanoparticles for enhanced anti-bacterial efficiency to overcome methicillin-resistant Staphylococcus aureus
Multidrug resistant bacterial infection remains a significant public concern. In this report, photosensitizer Chlorin e6 doped silica was synthesized. This hybrid structure exhibits enhanced photostability and high antibacterial efficiency towards Staphylococcus aureus (S. aureus) and methicillin-resistant S. aureus (MRSA). In summary, this work demonstrates an effective platform to improve the efficiency of antibiotics for better treatment of wound infections
Advanced drug delivery systems for enhanced antibacterial and anticancer therapy
Antibiotics—once the main line of defence against bacterial infections—have
started losing their effectiveness in the treatment of bacterial infections owing
to antimicrobial resistance (AMR) caused by long-term abuse and overprescription.
With an exponential rise in AMR of bacteria, there is currently a
crucial need to develop alternative antimicrobial agents capable of effectively
containing their toxic effects while achieving a therapeutic function. While most
bacteria poses a threat to public health and need to be treated, there are
certain ‘friendly’ bacteria —mostly lactic acid bacteria (LAB)—with promising
therapeutic functions. This project focuses on developing advanced drug
delivery systems to kill harmful bacteria while making use of healthy bacteria
to treat cancer.
Chapter 1 delves into the structure of Gram-positive and Gram-negative
pathogenic bacteria and outlines in detail the distinct features that may
contribute to bacterial infections. Next, the targeting mechanisms of action of
currently available antibiotics are discussed and their limitations are presented.
As alternative antibacterial treatment options, nanomaterials and hydrogels
are introduced and the current state-of-art research is described and
supplemented with examples. Then, the potential use of healthy bacteria in
therapy is summarised with a strong focus on anticancer applications. After
highlighting some of the drawbacks associated with current drug delivery
systems, the rationale, aim, and objectives of this PhD thesis are established.
Chapter 2 provides an insight into the imaging and characterisation techniques
used in this thesis. A brief description of their operating principles is provided
and their benefits and drawbacks are highlighted. For some of the techniques,
the optimised operating modes for characterisation of the drug delivery
systems synthesised are described.
Chapter 3 is a collaboration work which focuses on photodynamic-based
therapy to treat methicillin-resistant Staphylococcus Aureus (MRSA). Chlorin
e6 (Ce6), a common photosensitiser, was covalently conjugated to a zeolitic
imidazolate framework-8 (ZIF-8) nanoparticle (NP) termed as MOF-Ce6 and
incubated with bacteria. After proving their antibacterial efficacy on the bacteria
upon irradiation with a 650 nm LED light using optical density and CFU
measurements, confocal imaging was used to provide a visual representation
of the results. An insight into the mechanism of its antibacterial activity was
provided.
Chapter 4 further explores photodynamic therapy of two Ce6-conjugated NPs,
namely, MOF-Ce6 and silica-Ce6 (MCM-Ce6) NPs to understand the
importance of cellular uptake of NPs in their photodynamic therapy-based
antibacterial applications. The effects of two times light irradiation on the
antibacterial performance of these NPs were studied and compared with that
of free Ce6 molecules. Results from this experiment revealed that larger NPs
are unable to enter MRSA bacteria and only act at their surface, thus showing
bacterial growth after 12 h. Free Ce6 molecules, on the contrary, were still
effective after 12 h and able to completely eradicate most bacteria after the
second LED light irradiation owing to their ability to penetrate and remain within
the bacteria.
Chapter 5 proposes a new generation of hand washing hydrogel with chitosan
NPs acting as the antibacterial agent. Chitosan NPs with sizes ranging from
50 – 200 nm were synthesised using an ionotropic gelation method. The
hydrogel formulation was prepared and the steps involved in its optimisation
were described. Results from this work demonstrated good antibacterial
activity against MRSA and streptomycin-resistant Escherichia Coli (E. Coli dB
3.1).
Chapter 6 investigates two LABs, namely, Lactococcus Lactis (L. Lactis) and
Lactobacillus Casei (L. Casei) as potential carriers of drug-loaded NPs for the
potential anticancer therapy of breast cancer cells. Mesoporous silica NPs
(MSNs) were separately loaded with the chemotherapeutic drug, Doxurubicin
HCl (DOX) and the photosensitising dye, methylene blue (MB). The drug5
loaded NPs were then coated with metal phenolic networks (MPNs). Nano
biohybrids were formed by the incubation of the nanocomposites synthesised
with each type of probiotic bacteria. These were then characterised by TEM
and the coating of the NPs on the surface of the bacteria was optimised after
testing under different incubation conditions. The potential benefits of using
the probiotic bacteria-based nanohybrids for cancer cell targeting as well as
coating of the NPs with MPNs for the long-term and sustained release of the
drug was highlighted.
The closing chapter, Chapter 7 provides a summary of the key results obtained
in the experiments carried out in this project. It draws a conclusion on their
efficacies and their novelty as well provides a critical insight into their potential
translation into commercial use
Biosensors and Point-of-Care Devices for Bacterial Detection: Rapid Diagnostics Informing Antibiotic Therapy
With an exponential rise in antimicrobial resistance and stagnant antibiotic development pipeline, there is, more than ever, a crucial need to optimize current infection therapy approaches. One of the most important stages in this process requires rapid and effective identification of pathogenic bacteria responsible for diseases. Current gold standard techniques of bacterial detection include culture methods, polymerase chain reactions, and immunoassays. However, their use is fraught with downsides with high turnaround time and low accuracy being the most prominent. This imposes great limitations on their eventual application as point-of-care devices. Over time, innovative detection techniques have been proposed and developed to curb these drawbacks. In this review, a systematic summary of a range of biosensing platforms is provided with a strong focus on technologies conferring high detection sensitivity and specificity. A thorough analysis is performed and the benefits and drawbacks of each type of biosensor are highlighted, the factors influencing their potential as point-of-care devices are discussed, and the authors' insights for their translation from proof-of-concept systems into commercial medical devices are provided
Photosensitizer doped zeolitic imidazolate framework-8 nanocomposites for combined antibacterial therapy to overcome methicillin-resistant Staphylococcus aureus (MRSA)
Antibiotics have played an important role in the treatment of bacteria related infections. However, the rapid emergence of multidrug-resistant bacteria and limited number of antibiotics available is a great challenge to humankind. To circumvent the use of antibiotics and hence, address this problem, we are proposing a photosensitizer-modified biodegradable zeolitic imidazolate framework-8 nanocomposite that can kill not only Gram-positive bacteria Staphylococcus aureus, but also methicillin-resistant Staphylococcus aureus with high efficacy. In vivo testing revealed that these nanocomposites are highly effective for in vivo wound disinfection with minimal side-effects. In conclusion, this photosensitizer-modified biodegradable nanocomposite could be very promising for a synergistic antibacterial therapy to overcome methicillin-resistant Staphylococcus aureus (MRSA)
Layered double hydroxides-silver-chlorin e6 nanocomposite for photo-chemo combination therapy to efficiently combat both Gram-positive and Gram-negative bacteria
Antibiotics play an important role in the treatment of infectious diseases. However, the growing threat of drug-resistant bacteria has limited the availability and effectiveness of antibiotics. Here, we introduced an antibiotic nanocomposite using biocompatible and biodegradable layered double hydroxides as a matrix, followed by covalent conjugation of a photosensitizer, chlorin e6 (Ce6), and in-situ doping of silver nanoparticles for synergistic photo-chemo combination therapy to effectively kill both Gram-positive and Gram-negative bacteria. This layered double hydroxides-silver-chlorin e6 nanocomposite could be potentially utilized for treating various bacterial infections and overcoming bacterial resistance