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Kusumawati Arizah,Mustopa Apon Zaenal,Umami Rifqiyah Nur,Santoso Adi,Wibawan I Wayan Teguh,Setiyono Agus,Sudarwanto Mirnawati Bachrum 한국미생물·생명공학회 2022 한국미생물·생명공학회지 Vol.50 No.3
Aptamers are short, chemically synthesized, single-stranded DNA or RNA oligonucleotides that fold into unique three-dimensional structures. In this study, we aim to determine the antibiofilm activity and binding specificity of the six polyclonal DNA aptamers (S15K3, S15K4, S15K6, S15K13, S15K15, and S15K20) on Staphylococcus aureus BPA-12 and Escherichia coli EPEC 4. Aptamer S15K6 showed the highest percentage of antibiofilm activity against S. aureus BPA-12 (37.4%) as shown by the lowest OD570 value of 0.313. Aptamer S15K20 showed the highest percentage of antibiofilm activity against E. coli EPEC 4 (15.4%) as shown by the lowest OD570 value of 0.515. Aptamers S15K13 and S15K20 showed antibiofilm activities against both S. aureus BPA-12 and E. coli EPEC4, and thus potentially have broad reactivity. Furthermore, based on the binding capacity and Kd values from our previous study, the binding specificity assay of selected polyclonal DNA aptamers (S15K3 and S15K15) against S. aureus BPA-12, E. coli EPEC 4, S. aureus BPA-6, S. agalactiae, E. coli MHA-6, and Listeria monocytogenes were performed using qPCR. Aptamers S15K3 and S15K15 showed specific binding to S. aureus BPA-12, E. coli EPEC 4, S. aureus BPA-6, and S. agalactiae, but could not bind to E. coli MHA-6 and L. monocytogenes. Therefore, this study showed that the polyclonal DNA aptamers have antibiofilm activity and were able to bind to S. aureus BPA-12 and E. coli EPEC 4 bacteria.
Recent advancements of nitric oxide-releasing hydrogels for wound dressing applications
Hasan Nurhasni,Jiafu Cao,Mustopa Apon Zaenal,Himawan Achmad,Umami Rifqiyah Nur,Ullah Muneeb,Wathoni Nasrul,유진욱 한국약제학회 2023 Journal of Pharmaceutical Investigation Vol.53 No.6
Background Hydrogels are three-dimensional (3D) polymer networks that can absorb significant volumes of water inside their interstices and continue connecting these interstices while maintaining an inflated network structure; this capability is due to their unusual 3D crosslinked polymer meshwork structure. Hydrogels are promising wound dressings, particularly for chronic wounds, owing to their wound-healing properties, such as flexibility, adhesion, moisture control, biocompatibility, and biodegradability. Nitric oxide (NO) is a small molecule that has been thoroughly investigated for its wound-healing activity. The diverse roles of NO in wound healing require its stable delivery to the wound site. Thus, hydrogels have been evaluated as promising scaffolds for storing and releasing NO in a controlled manner to promote and accelerate wound healing. Area covered This review sought to introduce the types of polymers used to prepare hydrogel-based wound dressings and the types of NO donors used as wound healing promoters. The preparation method of the hydrogels and their physical and chemical properties were presented herein, and recent studies on NO-releasing hydrogels for wound therapy were summarized and discussed. Selected hydrogels with unique characteristics and significant findings for wound healing were also emphasized. Expert opinion Owing to the importance of chronic wounds in healthcare, the development of functional materials that support proper and rapid wound healing is required. NO-releasing hydrogels can be employed for wound dressing applications owing to their controlled NO releasability and antibacterial and wound healing activities.