• Our research suggest that anthocyanins are promising anti-bacterial agents • The antimicrobial effects are highly dependent on the source of the anthocyanin-extract • Rose-anthocyanins appear to posses the strongest anti-bacterial effects • Gram-positive strains appear to be more sensitive compared to gram-negative strains • Future research efforts should focus on different anthocyanin entities
DOCUMENT
With the alarming rise of antimicrobial resistance, studies on bacteria-surface interactions are both relevant and timely. Scanning electron microscopy and colony forming unit counting are commonly used techniques but require sophisticated sample preparation and long incubation time. Here, we present a direct method based on molecular dynamics simulation of nanostructured surfaces providing in silico predictions, complemented with time-lapse fluorescence imaging to study live interactions of bacteria at the membrane-substrate level. We evaluate its effectiveness in predicting and statistically analyzing the temporal evolution and spatial distribution of prototypical bacteria with costained nucleoids and membranes (E. coli) on surfaces with nanopillars. We observed cell reorientation, clustering, membrane damage, growth inhibition, and in the extreme case of hydrocarbon-coated nanopillars, this was followed by cell disappearance, validating the obtained simulation results. Contrary to commonly used experimental methods, microscopy data are fast processed, in less than 1 h. In particular, the bactericidal effects can be straightforwardly detected and correlated with surface morphology and/or wettability.
LINK
Acne vulgaris is considered one of the most common medical skin conditions globally, affecting approximately 85% of individuals worldwide. While acne is most prevalent among adolescents between 15 to 24 years old, it is not uncommon in adults either. Acne addresses a number of different challenges, causing a multidimensional disease burden. These challenges include clinical sequelae, such as post inflammatory hyperpigmentation (PIH) and the chance of developing lifelong disfiguring scars, psychological aspects such as deficits in health related quality of life, chronicity of acne, economic factors, and treatment-related issues, such as antimicrobial resistance. The multidimensionality of the disease burden stipulates the importance of an effective and timely treatment in a well organised care system. Within the Netherlands, acne care provision is managed by several types of professional care givers, each approaching acne care from different angles: (I) general practitioners (GPs) who serve as ‘gatekeepers’ of healthcare within primary care; (II) dermatologists providing specialist medical care within secondary care; (III) dermal therapists, a non-physician medical professional with a bachelor’s degree, exclusively operating within the Australian and Dutch primary and secondary health care; and (IV) beauticians, mainly working within the cosmetology or wellness domain. However, despite the large variety in acne care services, many patients experience a delay between the onset of acne and receiving an effective treatment, or a prolonged use of care, which raises the question whether acne related care resources are being used in the most effective and (cost)efficient way. It is therefore necessary to gain insights into the organization and quality of Dutch acne health care beyond conventional guidelines and protocols. Exploring areas of care that may need improvement allow Dutch acne healthcare services to develop and improve the quality of acne care services in harmony with patient needs.
DOCUMENT
To treat microbial infections, antibiotics are life-saving but the increasing antimicrobial resistance is a World-wide problem. Therefore, there is a great need for novel antimicrobial substances. Fruit and flower anthocyanins have been recognized as promising alternatives to traditional antibiotics. How-ever, for future application as innovative alternative antibiotics, the full potential of anthocyanins should be further investigated. The antimicrobial potential of anthocyanin mixtures against different bacterial species has been demonstrated in literature. Preliminary experiments performed by our laboratories, using grape, rose and red cabbage anthocyanins against S. aureus and E. coli confirmed the antimicrobial potential of these substances. Hundreds of different anthocyanin entities have been described. However, which of these entities hold antimicrobial effects is currently unknown. Our preliminary data show that an-thocyanins extracted from grape, rose and red cabbage contain different collections of anthocyanin entities with differential antimicrobial efficacies. Our focus is on the extraction and characterization of anthocyanins from various crop residues. Grape peels are residues in the production of wine, while red rose and tulip leaves are residues in the production of tulip bulbs and regular horticulture. The presence of high-grade substances for pharmacological purposes in these crops may provide an innovative strategy to add value to other-wise invaluable crop residues. This project will be performed by the collaborative effort of our institute together with the Medi-cal Microbiology department of the University Medical Center Groningen (UMCG), 'Wijnstaete', a small-scale wine-producer (Lemelerveld) and Imenz Bioengineering (Groningen), a company that develops processes to improve the production of biobased chemicals from waste products. Within this project, we will focus on the antimicrobial efficacy of anthocyanin-mixtures from sources that are abundantly and locally available as a residual waste product. The project is part of a larger re-search effect to further characterize, modify and study the antimicrobial effects of specific anthocy-anin entities.
Worldwide over- and misuse of antibiotics has contributed to the development of antibiotic-resistance. The occurrence and increase of antibiotic-resistance is one of the most pressing global health care issues of the 21st century. Recently it has been recognized that fruit and flower anthocyanins have antimicrobial activity and thereby the potential to function as novel antibiotics. At the Hanze University of Applied Science, we were able to confirm the antimicrobial efficacy of purified Rosa and Tulipa anthocyanin extracts against an array of microbial species. Using our optimized extraction methods, anthocyanins can easily be extracted and purified from floral residual streams. Once marketed as novel antimicrobials, this valorization of residual streams to high-value compounds contributes to the transition towards a circular economy. However, for future application in different antimicrobial products, it is necessary to identify and characterize single antimicrobial anthocyanin molecules. Moreover, analysis of pilot-scale extraction- and fractionation-yields and antimicrobial bench-mark doses will provide information on their market and application potential. In the current project we propose to develop a strategy composed of fractionation and state-of-the-art characterization methods to identify anthocyanin-molecules with potent antimicrobial effects. To our knowledge this is the first strategy that combines in-depth chemical characterization of anthocyanins in relation to their antimicrobial efficacy. Once developed, this strategy will allow us to single out anthocyanin molecules with antimicrobial properties. The development of the proposed fractionation and characterization strategy is the first step towards the development of single anthocyanin molecules as novel plant-based antibiotics.
The World Health Organization has pinpointed antimicrobial resistance (AMR) of increasing global concern, causing increased healthcare costs and threatening human health. Although AMR is a naturally occurring process, it is accelerated by misuse/overuse of antibiotics. Additionally, the development and production of antibiotics is becoming increasingly challenging and costly. These challenges underline the high demand for alternative microbial inhibitors (e.g. antibiotics) and their development. The chemical compound Allicin has been studied for its potential health benefits, including antimicrobial properties[1,2] and potential cardiovascular benefits[3]. It has been suggested that the antimicrobial effect of Allicin could be achieved indirectly by the imprint it leaves in surrounding water molecules, i.e. its hydration shell. Such imprints are known as time-crystals and possess unique properties. Since often biochemical reactions occur via water molecules and their hydrogen bonds, it is possible that a time-crystal imprint of a substance in water might have a similar effect as the substance itself, e.g. antimicrobial inhibition. A consortium of universities, knowledge institutes and companies was formed to test this hypothesis based on the antibacterial properties of Allicin, resulting in the project HyTimeCIA. The experiments involve attaching allicin onto a polymer surface (i.e. hybridization), thereby providing antibacterial properties. This surface is then exposed to bacteria to test the antimicrobial properties of the allicin/polymer surface. If proven feasible, HyTimeCIA could provide a novel alternative microbial inhibitor fixated to a surface, allowing for localized application of antibacterial effects and potentially reducing the requirement of antibiotics. This not only mitigates AMR, but also facilitates production of microbial inhibitors that are particularly difficult or expensive. From the partners perspective, HyTimeCIA provides opportunities for chemical-free alternative antimicrobial (water)treatment technology and gained knowledge on alternative microbial inhibitors, both aspects which are highly in demand due to AMR and antibiotic production challenges.
