Silk fibroin nanoparticles and ß-tricalcium phosphate loaded tissue engineered gelatin bone scaffolds: A Nature-based, low-cost solution.

Tissue engineering has recently attracted attention as an alternative to traditional treatment methods for tissue and organ damage. Since bone is one of the most important vital parts of the body, the treatment of bone damage is important. Silk fibroin is a natural polymer with properties such as biocompatibility and biodegradability, which attracts attention with its controlled release, especially in drug delivery systems. In this study, gelatin-based scaffolds loaded with silk fibroin nanoparticles and ß -tricalcium phosphate (ß -TCP) were developed to be used as a potential drug delivery system in bone tissue engineering. The chosen nanoparticle formulation has a 294 nm average diameter with a 0.380 polidispersity index (PDI). In vitro characterization of scaffolds was performed by mechanical, morphological characterization, swelling capacity, Differential Scanning Calorimetry (DSC), Fourier-Transform Infrared Spectroscopy (FT-IR) measurements, and biocompatibility was evaluated by cell culture studies. Swelling index, tensile strength, elongation at break, and Young modulus of the ß -TCP and silk nanoparticles loaded scaffold were found as 456%, 1.476 MPa, 6.75%, and 24 MPa, respectively. In vitro cell culture studies have shown that scaffolds prepared in the present study can accelerate osteoblast differentiation and increase the healing rate of bone tissues. In addition, they have the potential to be used as a drug delivery system in bone tissue engineering that needs to be evaluated with further studies.

Three-dimensional printed dosage forms based on disease-focussed perspectives.

OBJECTIVES: Three-dimensional printing (3DP) has gained importance worldwide recently as a novel drug manufacturing technology. 3DP technologies are suitable in the pharmaceutical field because of having the potential in personalized medicine. The aim of this review is to present an overview of the use of 3DP technologies in pharmaceutical area, their working principles and critical process parameters. In addition, this review presents an innovative approach that evaluates the use of 3DP technologies on disease to disease. KEY FINDINGS: This review covers the potential use of 3DP technologies in different diseases by evaluating them on a research basis. These diseases can be summarized as cardiovascular, neurological, respiratory, oncological, inflammatory, vaginal, dermatological and other diseases. It has been focussed on manuscripts that published after 2015. Studies on the use of 3DP in each disease group have been systematically reviewed by considering the methods, types of printers used and the prepared dosage forms. Oral formulations (tablets and films), implants, topical systems and vaccines are some of the examples of the mentioned dosage forms. SUMMARY: This review presented a systematic and novel overview of the use of 3DP in the treatment of different clinical disorders.

Preparation and characterization of colon-targeted pH/Time-dependent nanoparticles using anionic and cationic polymethacrylate polymers.

Inflammatory bowel disease (IBD), which is a chronic inflammatory disease of the gastrointestinal system, has two subtypes: Ulcerative Colitis (UC) and Crohn's Disease (CD). Only pH-sensitive drug delivery systems are commonly utilized for the treatment of IBD, but their effectiveness is frequently obstructed by the change in intestinal pH. To overcome the inadequacy of only pH-dependent delivery systems, we developed in vitro evaluated both pH- and time-dependent nanoparticles loaded budesonide (BUD) for the treatment of IBD in this study. Anionic polymethacrylate was utilized as a pH-dependent polymer whereas cationic polymethacrylate was utilized as a time-dependent sustained release polymer. Nanoparticles were prepared through a single oil-in-water emulsion/solvent evaporation method. The encapsulation efficiency, mean particle size, zeta potential, polydispersity index (PDI), drug release profiles, drug release kinetics, and stability of these nanoparticles were investigated. In all formulations, mean particle sizes were below 250 nm and PDI values were between 0.1 and 0.3. Nanoparticles containing 90% anionic-10% cationic polymethacrylate polymers inhibited burst BUD release under acidic conditions and exhibited sustained drug release at neutral pH. Consequently, in the medication of IBD, BUD-loaded pH and time-dependent nanoparticles may be a promising choice as a drug delivery system.

Effects of electrospun fiber curcumin on bisphenol A exposed Caco-2 cells.

Curcumin; the major polyphenolic compound, isolated from Curcuma longa L.; loaded polyvinylpyrrolidone K90 fibers were prepared using electrospinning method. Effectiveness was tested on human colorectal adenocarcinoma cells with the presence of the endocrine disrupter Bisphenol A. Curcumin-loaded fibers were shown to have good physicochemical properties where excellent morphology of the electrospin fibers were formed. With the presence of 8 nM Bisphenol A, 17.37 mM fibers were found to inhibit proliferation in the cells in a dose-dependent manner. Fibers induced a significant increase in malondialdehyde by Thiobarbituric Acid Reactive Substances Assay compared to the control and this effect was supported by the presence of Bisphenol A. Western blot results indicate Super Oxide Dismutase-1 levels were increased by fiber, while Bisphenol A coincubated group resulted in a decrease. Fibers increased the expression of Estrogen Receptor 2, while Estrogen Receptor 1 expression did not change. Estrogen Receptor 2 expression was increased by coincubation with Bisphenol A; indicating a possible role of Estrogen Receptor 2 in the protective effects of fiber. This study presents that fiber had enhanced bioavailability and solubility with increased anticancer effect in human colon adenocarcinoma cells in presence of Bisphenol A; where involved mechanisms are antioxidant system and estrogen receptor expression.

Electrospun orally disintegrating film formulation of telmisartan.

Telmisartan (TEL) is an antihypertensive BCS class II drug with low solubility at physiological pH. However, the solubility of TEL increases with the presence of an alkalizer. Electrospinning is one of the most recent techniques for the solubility enhancement studies. In this study, an electrospun orally disintegrating film (ODF) formulation of TEL was developed with L-arginine and polyvinylpyrrolidone K90 (PVP), and its characterization studies were performed. Preformulation studies were performed to investigate possible incompatibilities in the components of formulation with differential scanning calorimetry (DSC) and Fourier transform infrared spectrometer (FT-IR) analyses. ODFs were characterized in terms of drug content and uniformity, mechanical properties, fiber shape and diameter and in vitro dissolution profile. Smooth nanofibers without any beads were obtained. The dissolution rate of the TEL significantly increased. The chosen formulation had acceptable mechanical properties with much faster dissolution compared to the commercially available product. Developed ODF and marketed product were compared with a dissolution study in phosphate-buffered solution (pH 7.4). ODF and marketed product both reached 100% release in the 45th minute, and ODF results showed that ODF had much faster release than marketed product. In this study, TEL ODF formulation was successfully produced and characterized.

Development and characterization of chitosan nanoparticles loaded nanofiber hybrid system for vaginal controlled release of benzydamine.

Vaginal infections caused by various pathogens such as fungi, viruses and protozoa are frequently seen. Systemic and local treatments can be applied to eliminate these infections. Novel vaginal drug delivery systems can be used to provide local treatment. Vaginal drug delivery systems prevent systemic side effects and can provide long-term drug release in the vaginal area. Nanofibers and nanoparticles have a wide range of applications and can also be preferred as vaginal drug delivery systems. Benzydamine is a non-steroidal anti-inflammatory and antiseptic drug which is used for treatment of vaginal infections. The aim of this study was to compare the nanofiber and gel formulations containing lyophilized benzydamine nanoparticles with nanofiber and gel formulations containing free benzydamine, and to provide prolonged release for protection from the vaginal infections. Ionic gelation method was used for the preparation of benzydamine loaded nanoparticles. To produce benzydamine nanoparticles loaded nanofiber formulations, polyvinylpyrrolidone (PVP) solutions were prepared at 10% concentrations and mixed with nanoparticles. Hydroxypropyl methylcellulose (HPMC) was used as a gelling agent at the concentration of 1% for the vaginal gel formulation. Nanoparticles were characterized in terms of zeta potential, polydispersity index and particle size. Viscosity, surface tension and conductivity values of the polymer solutions were measured for the electrospinning. Mechanical properties, contact angle and drug loading capacity of the fibers were determined. Scanning electron microscopy (SEM), differential scanning calorimetry (DSC), transmission electron microscopy (TEM), fourier-transform infrared (FT-IR) spectroscopy, mucoadhesion, ex vivo permeability studies and in vitro release studies were performed for the selected formulations. Ex vivo permeability studies were performed using Franz diffusion cell method. SEM and TEM images showed that fiber diameters increased with loading of nanoparticles. DSC studies showed no interaction between excipients used in the formulation. Tensile strength and elongation at break values of the fibers increased with the loading of nanoparticles, and the contact angle values of the fibers were found to be 0°. Addition of benzydamine nanoparticles to gel and nanofiber formulations increased mucoadhesion compared to free benzydamine loading formulations. Benzydamine nanoparticle loaded gel and nanofiber formulations penetrated slower than that of free benzydamine gel and fiber formulations. The results demonstrated that benzydamine and benzydamine nanoparticle loaded fibers and gels could be a potential drug delivery system for the treatment of vaginal infections. Chitosan nanoparticle loaded nanofiber formulations are offered as an alternative controlled release vaginal formulations for vaginal infections.

3D printed extended release tablets for once daily use: An in vitro and in vivo evaluation study for a personalized solid dosage form.

Fused deposition modeling (FDM)-3D printing enables the manufacturing of dosage forms with personalized doses and controllable release profiles. Parkinson's disease is a neurodegenerative disorder that causes motor complications. In the treatment of the disease, the nonergot dopamine receptor agonist pramipexole is used in gradually increasing doses depending on patient's needs. Hence, there are various dosed commercial products of pramipexole and it is a suitable model drug for the preparation of personalized-dose 3D printed dosage forms. In this study, we prepared extended release 3D tablets of pramipexole for once daily use in Parkinson's disease. Herein, 12 different 3D tablet formulations were prepared and in vitro characterizations were performed on these formulations. The formulations were compared with the marketed tablet and the optimum formulation was selected. The chosen formulation was prepared with commercially available doses of pramipexole and also with intermediate doses which are not available in the market to demonstrate the applicability of 3D printing in personalized dosing. Stability studies, which have innovative features for 3D tablets, were conducted in optimum 3D tablet formulation for 6 months at 25 °C/60% relative humidity (RH) and 40 °C/75% RH conditions. After oral administration of the optimum 3D tablets and the marketed tablets (in the same dose) to the rats, 24-hour plasma profiles were obtained and pharmacokinetic parameters were calculated. 3D tablets were successfully prepared in personalized doses and their properties were similar for almost all doses. The optimum 3D tablet formulation was found to be stable during the stability tests. 3D tablet and marketed tablet performed similar plasma profiles. The relative bioavailability of 3D tablet formulation was calculated as 107.6% compared with the marketed tablet. Briefly, in vitro and in vivo evaluations demonstrated that FDM-3D printing is a promising technology for the development of personalized dosage forms with extended release property and comparable to conventional ones.

Three dimensional bioprinting technology: Applications in pharmaceutical and biomedical area.

3D bioprinting is a technology based on the principle of three-dimensional printing of designed biological materials, which has been widely used recently. The production of biological materials, such as tissues, organs, cells and blood vessels with this technology is alternative and promising approach for organ and tissue transplantation. Apart from tissue and organ printing, it has a wide range of usage, such as in vitro/in vivo modeling, production of drug delivery systems and, drug screening. However, there are various restrictions on the use of this technology. In this review, the process steps, classification, advantages, limitations, usage and application areas of 3D bioprinting technology, materials and auxiliary materials used in this technology are discussed.

Electrospun metronidazole-loaded nanofibers for vaginal drug delivery.

Objective: To develop and characterize innovative vaginal dosage forms for the treatment of bacterial vaginosis (BV).Significance: This study is the first comparative evaluation of the metronidazole (MET)-loaded polyvinylpyrrolidone (PVP) nanofiber formulations on BV treatment. Vaginal nanofibers are one of the potential innovative dosage forms for BV treatment because of their flexible, mucoadhesive, and easy application in vaginal application which can be applied by the mucosal route.Methods: Blank and MET-loaded PVP solutions were prepared at three different concentrations (10, 12.5, 15%) for produce nanofiber. The suitability of the viscosities, surface tensions, and conductivity values of the solutions used to produce nanofibers for the electrospinning process has been evaluated. Scanning electron microscopy, mucoadhesion, permeability, Fourier transform infrared spectroscopy, differential scanning calorimetry, and drug release tests were performed to reveal the physical, chemical, and pharmaceutical properties of the nanofibers. Mechanical properties, and contact angle of the fibers were also determined. Gel and solution formulations containing MET were prepared for comparative studies.Results: All polymer solutions were found to be suitable for electrospinning process. PVP concentration directly affected nanofiber diameter, mechanical, and mucoadhesion properties of nanofibers. The release profiles of the drug from the nanofibers were similar for all concentration of PVP and release from the fibers was rapid. The permeability coefficient of MET from nanofibers was increased more than gel and solution formulations.Conclusions: Vaginal use of MET-loaded nanofibers has been shown to be a potential drug delivery system for the treatment of BV.

Peptide-protein based nanofibers in pharmaceutical and biomedical applications.

In recent years, electrospun fibers have found wide use, especially in pharmaceutical area and biomedical applications, related to the various advantages such as high surface-volume ratio, high solubility and having wide usage areas they have provided. Biocompatible and biodegradable fibers can be obtained by using peptide-protein structures of plant and animal derived along with synthetic polymers. Plant-derived proteins used in nanofiber production can be listed as, zein, soy protein, and gluten and animal derived proteins can be listed as casein, silk fibroin, hemoglobine, bovine serum albumin, elastin, collagen, gelatin, and keratin. Plant and animal proteins and synthetic peptides used in electrospun fiber production were reviewed in detail. In addition, the important physical properties of these materials for the electrospinning process and their use in pharmaceutical and biomedical areas were discussed.

The effect of a new wound dressing on wound healing: Biochemical and histopathological evaluation.

Electrospinning process has gained importance in the production of wound dressings in recent years. The wound dressings prepared by electrospinning method provide many advantages over conventional wound dressings. The aim of this study was to assess the histological, biochemical, and immunohistochemical evaluation of collagen/doxycycline loaded nanofiber wound dressing in both acute and chronic wound healing. Full-thickness wound model was created on rats and rats were divided in two main groups: normoglycemic (acute) and hyperglycemic (chronic) groups. Each group was divided into three sub groups: not treated (control) group, treated with nanofiber wound dressing group and treated with commercial product group. Wound closure rates were measured. Oxidative events were investigated by biochemical analyses. In addition to histological studies, matrix metalloproteinase, tissue inhibitor of metalloproteinase, vascular endothelial growth factor, basic-fibroblast growth factor, and von Willebrand factor levels were investigated with immunohistochemical studies. According to the biochemical analyses, it was concluded that the nanofiber wound dressing helps to increase antioxidant capacity and decrease lipid peroxidation. Immunohistochemical studies showed that nanofiber wound dressing enhanced angiogenesis and shortened the inflammatory phase. It was concluded that an effective and safe prototype nanofiber wound dressing, which has similar wound healing effect to the commercial product, has been developed to be used in acute or chronic wound treatment.

An Effective Technology for the Development of Immediate Release Solid Dosage Forms Containing Low-Dose Drug: Fused Deposition Modeling 3D Printing.

PURPOSE: Fabrication of immediate release (IR) tablet formulations with rapid release profile via fused deposition modeling 3D printing (FDM 3DP) is a challenge. The aims of this study were to prepare IR tablets with different dissolution profiles and to increase their in vitro dissolution rates by making physical modifications on them. Pramipexole was used as the model low-dose drug. METHODS: Polymeric filaments were prepared with six different combinations of Eudragit EPO and poly(ethylene) oxide by hot melt extrusion and 3D tablets were produced using an FDM printer. Characterization studies for the filaments and tablets were carried out. The printability of the filaments was also evaluated using a novel mechanical characterization method. Tablet formulation with optimum dissolution profile was chosen and physical modifications (infill %, shape change and thickness) on this formulation were made. RESULTS: Low-dose pramipexole loading filaments and 3D tablets were homogenously prepared. The printability of the filaments was related to their flexibility. With the physical modifications, the drug release completion time of the tablets reduced to 5 min. CONCLUSIONS: The same rapid release profiles with conventional IR tablets can be reached by making only physical changes on 3D tablets without using any filling or disintegrating agents.

Fabrication of doxycycline-loaded electrospun PCL/PEO membranes for a potential drug delivery system.

Potential usage of biodegradable and biocompatible polymeric nanofibers is the most attention grabbing topic for the drug delivery system. In order to fabricate ultrafine fibers, electrospinning, one of the well-known techniques, has been extensively studied in the literature. In the present study, the objective is to achieve the optimum blend of hydrophobic and hydrophilic polymers to be used as a drug delivery vehicle and also to obtain the optimum amount of doxycycline (DOXH) to reach the optimum release. In this case, the biodegradable and biocompatible synthetic polymers, poly(ε-caprolactone) (PCL) and poly(ethylene oxide) (PEO), were blended with different ratios for the production of DOXH-loaded electrospun PCL/PEO membranes using electrospinning technique, which is a novel attempt. The fabricated membranes were subsequently characterized to optimize the blending ratio of polymers by scanning electron microscopy (SEM), Fourier transform infrared spectroscopy (FTIR), X-ray diffraction analysis (XRD) and water contact angle analysis. After the characterization studies, different amounts of DOXH were loaded to the optimized blend of PCL and PEO to investigate the release of DOXH from the membrane used as a drug delivery vehicle. In vitro drug release studies were performed, and in vitro drug release kinetics were assessed to confirm the usage of these nanofiber materials as efficient drug delivery vehicles. The results indicated that 3.5% DOXH-loaded (75:25 w/w) PCL/PEO is the most acceptable membrane to provide prolonged release rather than immediate release of DOXH.

Development and characterization of rapid dissolving ornidazole loaded PVP electrospun fibers.

Gingivitis is a common and mild form of periodontal disease and can be described as a limited inflammation of the gingiva. This study aims to develop and characterize rapid releasing mucoadhesive fibers containing ornidazole with electrospinning process for the treatment of gingivitis. Polyvinylpyrrolidone (PVP) was chosen as a polymer and used at different concentrations of 10%, 12.5%, and 15%. Scanning electron microscopy images showed that fiber diameters increased with increasing polymer concentrations. Tensile strength and elongation at break values of fibers increased with increasing PVP amount, whereas the loading of ornidazole into the fibers decreased these parameters. The contact angle values of all fibers were found to be 0° due to the hydrophilic nature of PVP. Ornidazole was released within 5 min and diffused from all of the fibers faster than that of gel and solution formulations. Electrospun ornidazole fibers were found efficient against Porphyromonas gingivalis in antimicrobial activity studies. The results demonstrated that ornidazole loaded fibers could be a potential drug delivery system for the treatment of gingivitis.

Comparison of Oxidative Effects of Two Different Administration Form of Oxybutynin in the Potential Target Tissues.

Oxybutynin is an important anticholinergic agent that prevents uncontrolled contractions in the treatment of overactive bladder (OAB). However, drugs containing oxybutynin have significant side effects such as dry eyes, dry mouth, increased heart rate, constipation, blurred vision, and confusion. In recent years, new delivery methods for this agent are being searched. One of them is vaginal delivery. In this study, we aimed to compare the effects of oxybutynin on oxidative parameters in the potential target tissues of the oral and vaginal delivery. Female New Zealand white rabbits (n=12) were divided into two groups: oral delivery and vaginal delivery. The animals were sacrificed 48 h after administration and nitric oxide (NOx), thiobarbituric acid-reactive substances (TBARs), and glutathione (GSH) levels were determined spectrophotometrically in the aorta, salivary gland, and small intestine tissue samples. Vaginal delivery significantly decreased NOx levels in all tissue samples as compared to oral delivery (p < 0.05). Moreover, it reduced TBARs levels in salivary gland and aorta tissue samples (p < 0.05). In the light on these findings, it can be said that vaginal delivery may decrease the oxidant-induced side effects of oxybutynin as compared to oral delivery.

Evaluation of three-layered doxycycline-collagen loaded nanofiber wound dressing.

Nanofiber wound dressings have great potential for both acute and chronic wound healing. The aim of this study is to develop a wound dressing by the electrospinning method and to determine its in vitro characteristics. The viscosity and the surface tension values of the polymer solutions used in the electrospinning were measured and their suitability for electrospinning was evaluated. Nanofiber wound dressing consists of three layers. The first and the second layers are sodium alginate and chitosan nanofibers, respectively. The core of the coaxial nanofibers that comprises the third layer of the wound dressing contains 1% polycaprolactone and 4.5% collagen, the shell comprises 2.5% doxycycline and 2.5% polyethylene oxide. The developed wound dressing comprises aligned nanofibers, with a contact angle of 38°, a work of bioadhesion value of 0.485mJ/cm2 on rat skin, a tensile strength of 2.76MPa, an elongation at break value of 7.65%, a specific surface area of 9.65m2/g and a porosity of 52.3%. The amount of doxycycline content was found to be 260µg/cm2 and the complete drug release was achieved in 15min. No cytotoxic effect was shown in cell culture studies with keratinocyte cell lines. As a result of the stability studies, it was found that the morphological, mechanical, bioadhesion and wettability properties and the amount of doxycycline remained stable for a period of 12 months at 4°C/ambient humidity condition. The developed three-layered wound dressing could be an alternative for wound healing applications.

Preparation and characterization of electrospun nanofibers containing glutamine.

Oral mucositis is a painful inflammation of mucous membranes commonly after chemotherapy or radiotherapy. The aim of this study was to develop mucoadhesive nanofibers containing glutamine via electrospinning and to characterize them for the treatment of oral mucositis. Different mucoadhesive polymers were tried for preparing nanofibers and sodium alginate nanofibers were chosen after the characterization studies. Glutamine-loaded nanofibers were produced and characterized. Glutamine loaded onto nanofibers was confirmed by differantial scanning calorimetry and fourier transform infrared spectroscopy analyses. As a result, scanning electron microscopy observations showed that the glutamine loaded nanofibers had average diameter of 160nm. Glutamine amount was found to be 0.452mg/cm(2). Work of mucoadhesion, tensile strength and elongation at break values of the glutamine loaded nanofibers were found to be 0.165mJ/cm(2), 2.61mPa and 6.62% respectively. In vitro dissolution tests showed that more than 85% of the drug was diffused from the nanofibers at the end of 4h. Stability studies showed that there was no significant changes at 4 and 25°C/65% relative humidity storage conditions. Therefore, these results demonstrate that glutamine loaded nanofibers could have potential as an oromucosal drug delivery system for the treatment oral mucositis.

Investigation of the effect of intracolonic melatonin gel formulation on acetic acid-induced colitis.

The aims of the present study were to develop a colon-specific gel formulation of melatonin with sodium alginate and to evaluate its in vitro characteristics and intracolonic performance on oxidative stress parameters, such as nitric oxide (NOx), malondialdehyde (MDA) and glutathione (GSH) levels in rats with acetic acid-induced colitis. The melatonin-alginate gel formulations were prepared and their physico-pharmaceutical properties were determined. Formulation M5, which contained 3% of sodium alginate and 20% polyethylene glycol, was used for in vivo studies. The in vivo studies were conducted in rats with acetic acid-induced colitis. NOx, MDA and GSH levels were determined and histological investigations were performed. It was found that formulation M5 was the most suitable formulation for the colon-specific melatonin gel, in terms of pH, viscosity, drug release and mucoadhesion properties. The MDA levels in the tissues of Group 2 (treated with an intracolonic gel formulation without melatonin) were found to be significantly higher than in Group 1 (the untreated group). NOx levels decreased with the intracolonic and systemic melatonin treatment in the colitis-induced rats. Neither intracolonic nor intra-peritoneal (IP) melatonin treatment affected GSH levels. The epitelization of the colon tissues in groups administered with intracolonic melatonin, IP melatonin, and the intracolonic gel formulation without melatonin was much better than that found in the untreated group. It was concluded that melatonin participated in various defense mechanisms against the colonic inflammatory process, and that the dose, route and formulation type were the most important parameters in the effectiveness of melatonin.

Preparation and characterization of bioadhesive controlled-release gels of cidofovir for vaginal delivery.

The aim of this study was to develop mucoadhesive and thermosensitive gels for vaginal delivery that would be able to provide a controlled release of the model drug, cidofovir. The study also monitored the drug's potential antiviral properties. Cidofovir was put into the form of a vaginal gel, using mucoadhesive and thermosensitive polymers such as chitosan, Carbopol 974P, HPMC, and poloxamer 407. The physicopharmaceutical properties and stability of the vaginal gel formulations were evaluated. The gel formulation which was prepared with HPMC K100M exhibited the highest viscosity, as well as maximum adhesiveness, cohesiveness, and mucoadhesion values. The results of antiviral activity studies, which used the bovine herpes virus type 1 virus infection in vitro model using Vero cells, demonstrated the antiherpetic effect of the cidofovir gel containing HPMC K100M, at least under in vitro conditions. The study found that a mucoadhesive vaginal gel containing cidofovir can be a promising and innovative alternative therapeutic system for the treatment of genital herpes simplex virus and human papilloma virus induced infections in women.

Investigation of the effects of local glutathione and chitosan administration on incisional oral mucosal wound healing in rabbits.

The aim of the present study was to investigate the effects of local glutathione (GSH) and chitosan applications on the oxidant events and histological changes that occur, during healing processes in rabbits with incisional intraoral mucosal wounds. For this purpose, discs containing glutathione and chitosan (1:1) were prepared and their physicochemical characteristics were evaluated. New Zealand white rabbits were used in in vivo studies. A standard incision was applied to the oral mucosa of rabbits. The rabbits were divided into four groups, being: an untreated incisional group (n=6), a group treated with discs containing GSH+chitosan (n=6), a group treated with discs containing solely chitosan (n=5) and a group treated with discs containing solely GSH (n=5). The levels of malondialdehyde (MDA), glutathione and nitric oxide (NOx) in the oral wound tissues were measured on the fifth day after the injury. Histological changes in the wound tissues were also investigated. The tissue MDA levels in the group treated with the disc containing GSH+chitosan were found to be lower than those in the other groups. There were no statistically significant differences in terms of tissue GSH and NOx levels between the group treated with the disc comprising GSH+chitosan and the control group that had untreated incision wounds. According to the histological findings, wound healing in the group treated with the disc containing solely chitosan was found to be better than in the other groups. The results of the experiments showed that the local application to the intraoral incision wounds of chitosan+GSH, and chitosan alone, can be effective in the wound healing processes of soft tissues and dental implants.