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Stomatal responses to humidity, soil moisture and other factors that influence plant water status are critical drivers of photosynthesis, productivity, water yield, ecohydrology and climate forcing, yet we still lack a thorough mechanistic understanding of these responses. Here I review historical and recent advances in stomatal water relations. Clear evidence now implicates a metabolically mediated response to leaf water status (‘hydroactive feedback’) in stomatal responses to evaporative demand and soil drought, possibly involving abscisic acid production in leaves. Other hypothetical mechanisms involving vapor and heat transport within leaves may contribute to humidity, light and temperature responses, but require further theoretical clarification and experimental validation. Variation and dynamics in hydraulic conductance, particularly within leaves, may contribute to water status responses. Continuing research to fully resolve mechanisms of stomatal responses to water status should focus on several areas: validating and quantifying the mechanism of leaf-based hydroactive feedback, identifying where in leaves water status is actively sensed, clarifying the role of leaf vapor and energy transport in humidity and temperature responses, and verifying foundational but minimally replicated results of stomatal hydromechanics across species. Clarity on these matters promises to deliver modelers with a tractable and reliable mechanistic model of stomatal responses to water status.

Wound management is a significant and growing issue worldwide. Knowledge of dressing products and clinical expertise in dressing selection are two major components in holistic wound management to ensure evidence-based wound care. With expanding global market of dressing products, there is need to update clinician knowledge of dressing properties in wound care. Optimal wound management depends on accurate patient assessment, wound diagnosis, clinicians' knowledge of the wound healing process and properties of wound dressings. We conducted a comprehensive review of the physical properties of wound dressing products, including the advantages and disadvantages, indications and contraindications and effectiveness of first-line interactive/bioactive dressing groups commonly used in clinical practice. These include semipermeable films, foams, hydroactives, alginates, hydrofibers, hydrocolloids, and hydrogels. In making decisions regarding dressing product selection, clinicians need to ensure a holistic assessment of patient and wound etiology, and understand dressing properties when making clinical decisions using wound management guidelines to ensure optimal patient outcomes. This review has highlighted there is lack of high quality evidence and the need for future well designed trials.

Whether they are caused by trauma, illness, or surgery, wounds may occur throughout anyone’s life. Some injuries’ complexity and healing difficulty pose important challenges in the medical field, demanding novel approaches in wound management. A highly researched possibility is applying biomaterials in various forms, ranging from thin protective films, foams, and hydrogels to scaffolds and textiles enriched with drugs and nanoparticles. The synergy of biocompatibility and cell proliferative effects of these materials is reflected in a more rapid wound healing rate and improved structural and functional properties of the newly grown tissue. This paper aims to present the biomaterial dressings and scaffolds suitable for wound management application, reviewing the most recent studies in the field.

Stomatal pores with apertures that can be adjusted by changes in guard cell turgor have facilitated plant success in dry environments. We explore their evolutionary origins, considering recent findings from bryophytes. Unlike vascular plant stomata, which close to prevent water loss, bryophyte stomata become locked open to promote spore desiccation. We find that the families of ion channels, known to control stomatal movements in angiosperms, are ancient and represented across extant land plants. However, although angiosperm guard cells express specific ion channel genes, none appear specifically expressed in stomata-bearing moss tissues. Given the evolutionary shift in stomatal function from promotion to prevention of water loss, we postulate that ion channels adopted guard cell-specific functions after the divergence of bryophytes.

Hard‐to‐heal wounds are frequently associated with underlying conditions such as diabetes, vascular disease, and biofilm‐related infections. Accurate identification of microbial origin is essential, but is often hindered by biofilms. This study evaluated whether sonication of wound dressings, combined with different sample transport methods, improves bacterial detection in venous leg ulcers. In a prospective observational case–control study, six patients with hard‐to‐heal venous leg ulcers received treatments with medical‐grade honey (MGH) (n = 1), ceramic dressings – “Cerdak” (n = 2), or hydroactive dressings (n = 3). Three microbiological samples were collected per patient: (1) conventional wound swab (Levin's technique) in Amies medium; (2) sonicate fluid from used dressings transported in sterile tubes without medium; and (3) sonicate fluid in haemoculture tubes (BACT/ALERT). Total pathogen count and diversity were compared across sampling methods. Patient quality of life (QoL) was assessed using the Wound‐QoL instrument. Sonication revealed additional pathogens not detected by conventional swabs. The highest number of pathogens was found in sonicate fluid transported in haemoculture tubes (n = 43), followed by swabs (n = 39) and sterile tube transport (n = 30). Adequate treatment significantly improved patients' QoL during the healing process. Dressing sonication, especially with haemoculture tube transport, enhances microbial identification and may improve diagnosis and management of hard‐to‐heal wounds.

Patients using PolyMem also benefit from its pain relieving properties, which are directly related to PolyMem’s influence upon the nociceptor response, even over intact skin (Cutting et al., 2015). The ability of PolyMem to focus and control inflammation makes it particularly useful for closed tissue injuries, including stage I and Deep Tissue Pressure Injuries (Benskin, 2018). [...]of her extensive experience using PolyMem on well over one thousand patients, LB became so passionate about the benefits of these unique dressings that she is currently an employee of Ferris Mfg. L.(2016).Polymeric Membrane Dressings for Topical Wound Management of Patients With Infected Wounds in a Challenging Environment: A Protocol With 3 Case Examples.Ostomy Wound Manage62,42–50. doi:10.25270/owm.2016.6.4250 BenskinL.

Weyers, J. D. B. and Paterson, N. W. 1987. Responses of Commelina communis stomata in vitro.— J. exp. Bot. 38: 631–641. Analysis of the kinetics of movements of Commelina communis L. stomata in vitro revealed a sequence of opening and closing phases dependent on the incubation medium used and the physiological state of the plant material. In buffer containing 50 mol m −3 KC1 the sequence of aperture changes appeared to be influenced by equilibration of cell water potentials with that of the medium and by solute fluxes (dependent and independent on metabolic activity). The results indicate that the stomatal aperture after several hours of incubation may not always provide a reliable quantitative estimate of the ability of the stomata to operate. As a consequence, modifications are suggested to the ways in which experiments using epidermal strips are carried out and reported.