ABSTRACT
INTRODUCTION: The prevention and control of hospital-acquired infections remain a significant challenge worldwide, as textiles used in hospital wards are highly involved in transmission processes. Herein, we report a new antibacterial medical fabric used to prepare hospital pillowcases, bottom sheets, and quilt covers for controlling and reducing hospital-acquired infections. METHOD: The medical fabric was composed of blended yarns of staple polyester and degradable poly(3-hydroxybutyrate co-3-hydroxyvalerate)/polylactide fibres, which were then coated with polylactide oligomers, an environmentally friendly and safe antimicrobial agent with excellent thermal stability in high-temperature laundry. A clinical trial was conducted with emphasis on the bacterial species that were closely related to the infection cases in the trial hospital. RESULT: After 7 days of usage, 94% of PET/PHBV/PLA-PLAO fabric could keep less than 20 CFU/100 cm2 of total bacterial amount, meeting hygiene and cleanliness standards. CONCLUSION: This study demonstrates the potential of fabrics containing polyhydroxyalkanoate oligomers as highly effective, safe, and long-lasting antimicrobial medical textiles that can effectively reduce the incidence of hospital-acquired infections.
ABSTRACT
The development of continuous conducting polymer fibres is essential for applications ranging from advanced fibrous devices to frontier fabric electronics. The use of continuous conducting polymer fibres requires a small diameter to maximize their electroactive surface, microstructural orientation, and mechanical strength. However, regularly used wet spinning techniques have rarely achieved this goal due primarily to the insufficient slenderization of rapidly solidified conducting polymer molecules in poor solvents. Here we report a good solvent exchange strategy to wet spin the ultrafine polyaniline fibres. The slow diffusion between good solvents distinctly decreases the viscosity of protofibers, which undergo an impressive drawing ratio. The continuously collected polyaniline fibres have a previously unattained diameter below 5 µm, high energy and charge storage capacities, and favorable mechanical performance. We demonstrated an ultrathin all-solid organic electrochemical transistor based on ultrafine polyaniline fibres, which operated as a tactile sensor detecting pressure and friction forces at different levels.
