Protective effects of Ecklonia cava extract on the toxicity and oxidative stress induced by hair dye in in-vitro and in-vivo models

Oxidative hair dyes containingρ-phenylenediamine(PPD)are reported to induce an allergic reaction by promoting oxidative stress when absorbed through the skin.Despite the associated risk,these hair dyes remain popular owing to their convenience and sharpness of color.This makes it important to minimize the cytotoxicity and oxidative stress induced by PPD-containing hair dyes.Ecklonia cava extract has been evaluated in different studies for its protective effects against external stress in fibroblasts and keratinocytes.Our study was aimed at using in-vitro and in-vivo models to investigate the extract’s effects on cytotoxicity of and oxidative stress induced by PPD-containing hair dyes.Analysis of CIEL*a*b*Color space was first used to determine the range of E.cava extract that would not interfere with the coloring ability of the dye upon addition.Subsequently,the set ranges of E.cava extract(5% and 7%)were added to the hair dye and their toxicity assessed by evaluating the viability of fibroblasts and keratinocytes.The effects on developmental phenotypes and induction of oxidative stress by hair dye were evaluated and compared with those of hair dyes containing different contents of E.cava extract using an in-vivo zebrafish model.Our results showed that E.cava extract in hair dye could significantly decrease the cytotoxicity and levels of oxidative stress caused by hair dyes containing PPD in both in-vitro and in-vivo models.These results suggest that the addition of 7% E.cava extract to 250μg/mL hair dye does not interfere with the coloring ability of the dye while showing significant protective eff ects against the hair dye.The study proposes that the use of E.cava extract as an adduct to hair dyes containing PPD reduces the cytotoxicity and oxidative stress induced by these hair dyes.

A review of effective strides in amelioration of the biocompatibility of PEO coatings on Mg alloys

Recently,developing bioactive and biocompatible materials based on Mg and Mg-alloys for implant applications has drawn attention among researchers owing to their suitable body degradability.Implementing Mg and its alloys reduces the risk of long-term incompatibility with tissues because of their close mechanical properties and no need for re-operation to remove the implant.Nevertheless,the degradation rate of the implant needs to be controlled because production of hydrogen gas and accumulation of its bubbles increases local pH around the implants.To confine the integrity of implants and the body,the corrosion concern in the body fluid requires to be addressed.Surface modification as one of the effective strategies can improve corrosion resistance.Besides,it creates a suitable surface for bone grafting and cell growth.The development of proper surface-coated implants needs appropriate techniques and approaches.Plasma electrolytic oxidation(PEO)coating can provide long-term protection by providing a ceramic layer and improving the implant’s biocompatibility.Herein,a general review of in-vivo and in-vitro evaluation of PEO coatings on Mg and Mg-alloys has been carried out.Recent advances in surface modification on Mg and Mg-alloys have been discussed,however,the need for reliable laboratory models to predict in-vivo degradation is still valid.

Chemically Induced Mutants of <i>Brassica oleracea var. botrytis</i>Maintained Stable Resistance to Drought and Salt Stress after Regeneration and Micropropagation

Investigation was made to confirm the stability of drought and salt stress tolerance in cauliflower (Brassica oleracea var.botrytis) mutants after regeneration and micropropagation. The N-nitroso-N-ethyleurea (NEU) and N-nitroso-N-methylurea (NMU) induced mutants of cauliflower were created and screened for drought and salt stress tolerance. The highly tolerant mutants were selected, regenerated by tissue culture techniques, screened again for drought and salt tolerance under in-vitro and in-vivo conditions, correlated the response of in-vitro and in-vivo plants within a clone. Free proline levels in clones were correlated with stress tolerance. Results confirmed the persistence of mutations in clones with enhanced resistance levels to stresses over control plants. The regenerated in-vitro and in-vivo plants within a clone showed a positive significant correlation for drought (R2 = 0.663) and salt (R2 = 0.647) resistance that confirms the stability of mutation in clones after generations. Proline showed a positive and significant correlation with drought (R2 = 0.524) and salt (R2 = 0.786) tolerance. Conclusively, drought and salt resistance can be successfully enhanced in cauliflower by chemical mutagenesis. Further molecular analysis is recommended to study these mutants.

In-vitro experimental study on the fluid-structure interaction in an image-based flexible model with a lateral cerebral aneurysm

Aiming to experimentally investigate the effect of aspect ratio(AR)of image-based aneurysm on wall deformation oscillation under different pulsatile flow conditions with considering the fluid-structure interaction.In this study,three silicon aneurysm models with different AR(0.8,1.0,and 1.2)were constructed.It was found that the detected wall deformation oscillation of patient-specific aneurysm increased with pulsatile inflow frequency increases,which was greater and more obvious oscillation than that in the ideal lateral aneurysm.In addition,the maximum amplitude of wall deformations oscillation of the aneurysm at the dome during the systolic phase decrease and the oscillation of wall deformation become obvious as AR increases.These results could provide more knowledge about the effect of AR and pulsatile flow on the wall deformation of aneurysm and will be helpful for understanding the aneurysm rupture risk.

Pathways of nanotoxicity:Modes of detection,impact,and challenges

Nanotoxicology has become the subject of intense research for more than two decades.Thousands of articles have been published but the space in understanding the nanotoxicity mechanism and the assessment is still unclear.Recent researches clearly show potential benefits of nanomaterials(NMs)in diagnostics and treatment,targeted drug delivery,and tissue engineering owing to their excellent physicochemical properties.However,these NMs display hazardous health effect then to the greater part of the materials because of small size,large surface area-to-volume ratio,quantum size effects,and environmental factors.Nowadays,a large number of NMs are used in industrial products including several medical applications,consumer,and healthcare products.However,they came into the environment without any safety test.The measurement of toxicity level has become important because of increasing toxic effects on living organisms.New realistic mechanism-based strategies are still needed to determine the toxic effects of NMs.For the assessment of NMs toxicity,reliable and standardized procedures are necessary.This review article provides systematic studies on toxicity of NMs involving manufacturing,environmental factors,eco-toxic and genotoxic effects,some parameters which have been ignored of NMs versus their biological counterparts,cell heterogeneity,and their current challenges and future perspectives.

Optimising soft tissue in-growth in vivo in additive layer manufactured osseointegrated transcutaneous implants

Osseointegrated transcutaneous implants could provide an alternative and improved means of attaching artificial limbs for amputees,however epithelial down growth,inflammation,and infections are common failure modalities associated with their use.To overcome these problems,a tight seal associated with the epidermal and dermal adhesion to the implant is crucial.This could be achieved with specific biomaterials(that mimic the surrounding tissue),or a tissue-specific design to enhance the proliferation and attachment of dermal fibroblasts and keratinocytes.The intraosseous transcutaneous amputation prosthesis is a new device with a pylon and a flange,which is specifically designed for optimising soft tissue attachment.Previously the flange has been fabricated using traditional machining techniques,however,the advent of additive layer manufacturing(ALM)has enabled 3-dimensional porous flanges with specific pore sizes to be used to optimise soft tissue integration and reduce failure of osseointegrated transcutaneous implants.The study aimed to investigate the effect of ALM-manufactured porous flanges on soft tissue ingrowth and attachment in an in vivo ovine model that replicates an osseointegrated percutaneous implant.At 12 and 24 weeks,epithelial downgrowth,dermal attachment and revascularisation into ALM-manufactured flanges with three different pore sizes were compared with machined controls where the pores were made using conventional drilling.The pore sizes of the ALM flanges were 700,1000 and 1250μm.We hypothesised that ALM porous flanges would reduce downgrowth,improve soft tissue integration and revascularisation compared with machined controls.The results supported our hypothesis with significantly greater soft tissue integration and revascularisation in ALM porous flanges compared with machined controls.