Reliable Kinetics for Drug Delivery with a Microfluidic Device Integrated with the Dialysis Bag.

The clinical success of a drug delivery system turns back to performing experiments with more reliable data. The dialysis bag has been one of the most employed technologies to monitor drug release from nanocarriers, membranes, and scaffolds. Unfortunately, this technology has several challenges regarding the accuracy of the obtained results. In this study, the development of a new system by integrating a microfluidic device and dialysis bag named "MF-dialysis" was carried out to evaluate the accuracy of the reported data. The release study was performed focusing on two drug delivery systems: (i) nanocarrier: Artemisia Absinthium extract-loaded soy protein isolate nanoparticle and (ii) sodium alginate film loaded with the nanocarrier. The obtained nanocarrier was analyzed by SEM, DLS, and zeta potential. The final experimental data were modeled using SigmaPlot software. Based on the results, two distinct but fitted models for the dialysis bag (power model, R2 = 0.99) and MF-dialysis (exponential model, R2 = 0.95) were obtained. MF-dialysis approved that after a while, NPs and films showed more drug release compared to the dialysis bag. To sum up, the MF-dialysis system can be a good candidate for a quick and more reliable study of drug delivery systems.

Discussing the final size and shape of the reconstructed tissues in tissue engineering.

Tissue engineering (TE) has made a revolution in repairing, replacing, or regenerating tissues or organs, but it has still a long way ahead. The mechanical properties along with suitable physicochemical and biological characteristics are the initial criteria for scaffolds in TE that should be fulfilled. This research will provide another point of view toward TE challenges concerning the morphological and geometrical aspects of the reconstructed tissue and which parameters may affect it. Based on our survey, there is a high possibility that the final reconstructed tissue may be different in size and shape compared to the original design scaffold. Thereby, the 3D-printed scaffold might not guarantee an accurate tissue reconstruction. The main justification for this is the unpredicted behavior of cells, specifically in the outer layer of the scaffold. It can also be a concern when the scaffold is implanted while cell migration cannot be controlled through the in vivo signaling pathways, which might cause cancer challenges. To sum up, it is concluded that more studies are necessary to focus on the size and geometry of the final reconstructed tissue.

Efficient copper removal from wastewater through montmorillonite-supported hydrogel adsorbent.

A hybrid hydrogel based on acrylic acid monomer/wheat bran, supported by montmorillonite, was synthesized using in situ polymerization and utilized as an adsorbent to remove Cu (II) ions from an aqueous solution at batch condition. The structural and morphological microanalysis of adsorbents was carried out by scanning electron microscopy, Fourier transform infrared spectroscopy, and X-ray powder diffraction techniques. The type of water diffusion into the adsorbents was Fickian, and the swelling process has followed Schott's second-order kinetic model. The optimum adsorption conditions were the initial Cu (II) concentration 100 mg/l, pH 7.0, and montmorillonite dosage of 3.0 wt.%. The equilibrium time for the process was determined as 2 hr. The equilibrium data showed close fitting to the linear form of Langmuir isotherm model. Moreover, the maximum adsorption capacity has been determined to be 17.64 mg/g. Hence, montmorillonite-supported hydrogel adsorbent seems to be a promising adsorbent for the copper removal from industrial wastewaters. PRACTITIONER POINTS: A hydrogel adsorbent based on acrylic acid monomer/wheat bran, supported by montmorillonite was synthesized. The adsorbent was efficiently utilized for copper removal from aqueous solutions. The maximum adsorption capacity has been determined to be 17.64 mg/g.

In Vitro Release of Glycyrrhiza Glabra Extract by a Gel-Based Microneedle Patch for Psoriasis Treatment.

Microneedle patches are attractive drug delivery systems that give hope for treating skin disorders. In this study, to first fabricate a chitosan-based low-cost microneedle patch (MNP) using a CO2 laser cutter for in vitro purposes was tried and then the delivery and impact of Glycyrrhiza glabra extract (GgE) on the cell population by this microneedle was evaluated. Microscopic analysis, swelling, penetration, degradation, biocompatibility, and drug delivery were carried out to assess the patch's performance. DAPI staining and acridine orange (AO) staining were performed to evaluate cell numbers. Based on the results, the MNs were conical and sharp enough (diameter: 400-500 µm, height: 700-900 µm). They showed notable swelling (2 folds) during 5 min and good degradability during 30 min, which can be considered a burst release. The MNP showed no cytotoxicity against fibroblast cell line L929. It also demonstrated good potential for GgE delivery. The results from AO and DAPI staining approved the reduction in the cell population after GgE delivery. To sum up, the fabricated MNP can be a useful recommendation for lab-scale studies. In addition, a GgE-loaded MNP can be a good remedy for skin disorders in which cell proliferation needs to be controlled.

Reactive Blending of Recycled Poly(ethylene terephthalate)/Recycled Polypropylene: Kinetics Modeling of Non-Isothermal Crystallization.

Plastics were developed to change our world for the better. However, plastic pollution has become a serious global environmental crisis. Thermoplastic polyesters and polyolefins are among the most abundant plastic waste. This work presents an in-depth non-isothermal crystallization kinetics analysis of recycled post-consumer poly(ethylene terephthalate) (rPET) and recycled polypropylene (rPP) blends prepared through reactive compounding. The effect of pyromellitic dianhydride (PMDA) on crystallization kinetics and phase morphology of rPET/rPP blends was investigated by differential scanning calorimetry (DSC) and microscopy techniques. DSC results showed that increasing rPP content accelerated rPET crystallization while reducing crystallinity, which indicates the nucleation effect of the rPP phase in blends. Further, it was found that the incorporation of PMDA increased the degree of crystallinity during non-isothermal crystallization, even though the rate of crystallinity decreased slightly due to its restriction effects. The non-isothermal crystallization kinetics was analyzed based on the theoretical models developed by Jeziorny, Ozawa, Mo, and Tobin. The activation energy of the crystallization process derived from Kissinger, Takhor, and Augis-Bennett models was found to increase in rPET/rPP blends with increasing PMDA due to hindered dynamics of the system. Rheological measurements revealed that rPET melt viscosity is remarkably increased in the presence of PMDA and reactive blending with rPP relevant for processing. Moreover, nanomechanical mapping of the rPP phase dispersed in the rPET matrix demonstrated the broadening of the interfacial domains after reactive blending due to the branching effect of PMDA. Findings from this study are essential for the recycling/upcycling thermoplastics through non-isothermal fabrication processes, such as extrusion and injection molding, to mitigate the lack of sorting options.

Biaxial electrospun nanofibers based on chitosan-poly (vinyl alcohol) and poly (Ɛ-caprolactone) modified with CeAlO3 nanoparticles as potential wound dressing materials.

A two-nozzle electrospinning method was employed to fabricate hybrid nanofibers based on chitosan/polyvinyl alcohol (CS/PVA), with a ratio of 50:50, and poly (Ɛ-caprolactone) (PCL). CeAlO3 nanoparticles were synthesized by combustion method and utilized to improve the nanofiber's properties for wound dressing application. Cephalexin (CFX), as an antibiotic model, was also incorporated into the hydrophilic nanofibers. X-ray diffraction showed an increase in crystallinity when CeAlO3-NPs were present in the nanofibers. Water vapor transmission rates in the samples were calculated as 2201-2627 g m-2 day-1, all within the normal range of ideal wound dressings. Mechanical studies revealed a 43 % and 85 % increase in tensile strength and modulus when CeAlO3-NPs were incorporated. In vitro drug release tests were conducted to simulate drug release, and the neat fibers showed faster release than the modified fibers. The MTT assay and cell morphology experiments showed that CeAlO3-NPs did not affect the nanofiber's biocompatibility and fibroblast cells could better grow, differentiate and cover the prepared hybrid scaffold surface compared to the neat fibers. Taking the results of our study into account, we believe the prepared nanofibrous has the potential for use as a low-cost, effective wound dressing.

Decellularized Alstroemeria flower stem modified with chitosan for tissue engineering purposes: A cellulose/chitosan scaffold.

Utilizing plant-based scaffolds has pulled in the consideration of tissue engineers. Plant tissues own different structures with particular porosity and structure. In this study, the stem of the Alstroemeria flower was designated for decellularization to fabricate a new scaffold. The stems were decellularized and called AFSP and then modified by chitosan and named AFSPC. Osteoblast precursor cell line was employed to assess the biological potential of the final scaffolds. The results uncovered that AFSP owns linear microchannels with a smooth surface. AFSPC delineated uniform chitosan coating on the walls with appropriate roughness. AFSPC showed higher potential in swelling, degradation, diffusion, and having a porous structure than AFSP. Modification with chitosan improved mechanical behavior. Biological assays depicted no cytotoxicity for AFSP and AFSPC. AFSPC showed good cell attachment, proliferation, and migration. In conclusion, modified tissue plants can be a good candidate for tissue engineering of both soft and hard tissues.

3D printed chitosan/polycaprolactone scaffold for lung tissue engineering: hope to be useful for COVID-19 studies.

To prevent or reduce mortality from lung diseases, new biological materials and scaffolds are needed to conduct more accurate research and support lung tissue regeneration. On the other hand, the outbreak of the COVID-19 virus and its targeting of the human lung has caused many deaths worldwide. The main aim of this study was to provide a biologically and mechanically suitable 3D printed scaffold using chitosan/polycaprolactone bioink for lung tissue engineering. Design-Expert software was employed for studying various compositions for 3D printing. The selected scaffolds underwent physiochemical, biological and mechanical studies to evaluate if they are capable of MRC-5 cell line growth, proliferation, and migration. Based on the results, the average diameter of the chitosan/polycaprolactone strands was measured at 360 µm. Chitosan concentration controlled the printability, while changes in polycaprolactone content did not affect printability. The scaffolds showed excellent potential in swelling, degradation, and mechanical behavior, although they can be modified by adjusting the polycaprolactone content. The scaffolds also revealed notable cell adhesion, nontoxicity, low apoptosis, high proliferation, and cell biocompatibility in vitro. To sum up, scaffold 3 (chitosan/polycaprolactone ratio: 4 : 1) revealed better activity for MRC-5 cell culture. Thereby, this scaffold can be a good candidate for lung tissue engineering and may be applicable for more studies on the COVID-19 virus.

One-pot preparation of hyaluronic acid-coated iron oxide nanoparticles for magnetic hyperthermia therapy and targeting CD44-overexpressing cancer cells.

In the present study, a facile one-pot hydrothermal method is introduced for preparation of hyaluronic acid-coated Fe3O4 nanoparticles (Fe3O4@HA NPs) for theranostic applications. In the proposed method, hyaluronic acid acts simultaneously as a biocompatible coating layer and as a targeting ligand for CD44 receptor overexpressed on the surface of breast cancer cells. The obtained product with narrow hydrodynamic size distribution exhibited a high colloidal stability at physiological pH for more than three months. Cytotoxicity measurements indicated a negligible toxicity of the prepared sample against L929 normal cells. Preferential targeting of Fe3O4@HA NPs to CD44-overexpressing cancer cells was studied by comparing the uptake of the prepared nanoparticles by MDA-MB-231 cancer cells (positive CD44 expression) and L929 normal cells (negative CD44 expression). Uptake of the Fe3O4@HA NPs by MDA-MB-231 cells was found to be 4-fold higher than the normal cells. Also, the in vitro analysis showed that, the uptake of Fe3O4@HA NPs by MDA-MB-231 breast cancer cells is significantly enhanced as compared to non-targeted dextran-coated Fe3O4 NPs. Moreover, the heat generation capability of the Fe3O4@HA NPs for magnetic hyperthermia application was studied by exposing the prepared nanoparticles to different safe alternating magnetic fields (f = 120 kHz, H = 8, 10, and 12 kA/m). The intrinsic loss power obtained for Fe3O4@HA NPs was about 3.5 nHm2/kg, which is about 25-fold larger than that of obtained for commercial available Fe3O4 nanoparticles for biomedical applications. Good colloidal stability, biocompatibility, high heating efficacy, and targeting specificity to CD44 receptor-overexpressing cancer cells could make the Fe3O4@HA NPs as a promising multifunctional platform for diagnosis and therapeutic applications.

Nanofibrous cellulose acetate/gelatin wound dressing endowed with antibacterial and healing efficacy using nanoemulsion of Zataria multiflora.

In this paper, a multifunctional nanofibrous cellulose acetate/gelatin/Zataria multiflora-nanoemulsion (CA/Gel/ZM-nano) wound dressing was fabricated, in which nanoemulsion of a natural active antibacterial plant, by the scientific name of Zataria multiflora (ZM) was loaded into the nanofibrous mat. To fabricate the wound dressing, different weight ratios of CA/Gel (100, 0, 75, 25, 50, 50 and 25, 75) were selected, and solutions with concentrations of 16, 15, 14 and 12% w/v were prepared for each ratio, respectively to achieve smooth and uniform fibers by electrospinning. In vitro and in vivo analysis was taken for the samples. Nanofibrous mats with a lower ratio of CA/Gel and incorporated with ZM-nano promoted the adhesion and proliferation of L929 fibroblast cells significantly. Also, by lowering the ratio of CA/Gel, nanoemulsion drug-loading into nanofibers increased considerably, as the amount of ZM-nano loaded into CA/Gel = 50:50 was found to be 2.4-fold higher than CA/Gel = 100:0. Moreover, the rat model experiment in our study revealed that the nanofibrous samples incorporated with nanoemulsion drug (ZM-nano) accelerated the wound healing process so that the relative wound area for the nanoemulsion-loaded dressings was much smaller than the other samples after 22 days. Therefore, this multifunctional CA/Gel/ZM-nano wound dressing could be a promising and potential candidate for wound healing applications.

Removal and recovery of copper and nickel ions from aqueous solution by poly(methacrylamide-co-acrylic acid)/montmorillonite nanocomposites.

Nanocomposite hydrogels based on poly(methacrylamide-co-acrylic acid) and nano-sized montmorillonite were prepared by aqueous dispersion and in situ radical polymerization. Optimum sorption conditions were determined as a function of montmorillonite content, contact time, pH, and temperature. The equilibrium data of Cu(2+) and Ni(2+) conformed to the Freundlich and Langmuir isotherms in terms of relatively high regression values. The maximum monolayer adsorption capacity of the nanocomposite hydrogel (with 3 wt% montmorillonite content), as obtained from the Langmuir adsorption isotherm, was found to be 49.26 and 46.94 mg g(-1) for Cu(2+) and Ni(2+), respectively, at contact time = 60 min, pH = 6.8, adsorbent dose = 100 mg/ml, and temperature = 318 K. Kinetic studies of single system indicated that the pseudo-second order is the best fit with a high correlation coefficient (R (2) = 0.97-0.99). The result of five times sequential adsorption-desorption cycle shows a good degree of desorption and a high adsorption efficiency.