Genipin-crosslinked gelatin microspheres as a drug carrier for intramuscular administration: in vitro and in vivo studies

Gelatin microspheres have been widely evaluated as a drug carrier. Nevertheless, gelatin dissolves rather rapidly in aqueous environments, making the use of the polymer difficult for the production of long-term delivery systems. This adverse aspect requires the use of a crosslinking agent in forming nonsoluble networks in microspheres. However, the use of crosslinking agents such as formaldehyde and glutaraldehyde can lead to toxic side effects owing to residual crosslinkers. In an attempt to overcome this problem, a naturally occurring crosslinking agent (genipin) was used to crosslink gelatin microspheres as a biodegradable drug-delivery system for intramuscular administration. Glutaraldehyde was used as a control. In the in vitro study, the morphology, dynamic swelling, and antienzymatic degradation of test microspheres were evaluated. In the in vivo study, the biocompatibility and degradability of test microspheres were implanted in the skeletal muscle of a rat model via intramuscular injection. The results obtained in the study suggested that crosslinking of gelatin microspheres with glutaraldehyde or genipin may produce distinct crosslinking structures. The water transport mechanism in both the glutaraldehyde- and genipin-crosslinked gelatin microspheres exhibit anomalous behavior ranging from Fickian to Case-II extremes. The increase of the swelling diameter for the genipin-crosslinked microspheres was significantly less than that observed for the glutaraldehyde-crosslinked microspheres. In the animal study, it was found that the degree in inflammatory reaction for tissues implanted with the genipin-crosslinked microspheres was significantly less than that implanted with the glutaraldehyde-crosslinked microspheres. Additionally, the degradation rate of the genipin-crosslinked microspheres was significantly slower than their glutaraldehyde-crosslinked counterparts. These results indicated that the genipin-crosslinked gelatin microspheres may be used as a long-acting drug carrier for intramuscular administration.     

In vivo biocompatibility and degradability of a novel injectable-chitosan-based implant.

A novel injectable-chitosan-based delivery system with low cytotoxicity was fabricated in the study. The chitosan microspheres with small particle size, low crystallinity and good sphericity were prepared by a spray-drying method followed by treating with a crosslinker. In the study, a naturally occurring crosslinking reagent (genipin), which has been used in herbal medicine and in the production of food dyes, was used to crosslink the chitosan microspheres. The glutaraldehyde-crosslinked counterparts were used as a control. Histological study of the genipin-crosslinked chitosan microspheres injected intramuscularly into the skeletal muscle of a rat model showed a less inflammatory reaction than its glutaraldehyde-crosslinked counterparts. The results of the scanning electron microscopic examination indicated that the glutaraldehyde-crosslinked chitosan microspheres retrieved at 12-week postoperatively were already degraded into a loose and porous structure. However, the degradation of the genipin-crosslinked chitosan microspheres was not significant after 20 weeks of implantation. The results of the study demonstrated that the genipin-crosslinked chitosan microspheres have a superior biocompatibility and a slower degradation rate than the glutaraldehyde-crosslinked chitosan microspheres. Accordingly, the genipin-crosslinked chitosan microspheres may be a suitable polymeric carrier for long-acting injectable drug delivery.     

Study on gelatin-containing artificial skin: I. Preparation and characteristics of novel gelatin-alginate sponge

An absorbable sponge, composed of gelatin and alginate, was prepared by new crosslinking method that improved the efficiency of crosslinking. The crosslinking degree was characterized by trinitrobenzenesulfonic acid (TNBS) assay. A water uptake ability test, in vitro drug release and collagenase degradation tests, and an in vivo animal test were employed to confirm the applicability of this gelatin-alginate sponge as a wound dressing material. As the alginate content in the sponge increased, the porosity increased, resulting in an enhanced water uptake ability. Sponges loaded with silver sulfadiazine or gentamicin sulfate slowly released drugs for up to four days. The crosslinked sponge resisted in vitro collagenase digestion for up to three days. An in vivo animal test using witar rat showed rather good wound healing effect of gelatin-alginate sponge containing AgSD than vaseline gauze in our full-thickness skin defect model.     

Stabilization of gelatin films by crosslinking with genipin

The possibility to stabilize gelatin films by crosslinking with genipin was investigated through a mechanical, chemical and thermal characterization of samples treated with genipin solutions at different concentrations. The extent of crosslinking, evaluated as difference between the number of free -amino groups before and after crosslinking, increases as a function of genipin concentration up to about 85%. Simultaneously, the deformability of the films decreases whereas the Young's modulus E, increases. Furthermore, crosslinking provokes a significant reduction of the swelling in physiological solution, and enhances the thermal stability of the samples, as indicated by the results of the d.s.c. investigation. The data obtained from the films treated with genipin at concentrations higher than 0.67% are quite similar, and indicative of a good stabilizing effect of genipin. In spite of the small gelatin release (2%) observed after 1 month of storage in buffer solution, the mechanical, thermal and swelling properties of the films are very close to those previously obtained for glutaraldehyde crosslinked gelatin, and suggest that genipin, which is by far less cytotoxic, can be considered a valid alternative for crosslinking gelatin biomaterials.     

Preparation of gelatin/genipin nanofibrous membrane for tympanic member repair

Abstract

The wound healing for tympanic membrane (TM) perforations is one of the most common clinical treatment in otomicrosurgery. Recently, tissue-engineered composites and grafts, also new designs of biomaterials are applied to the management of TM perforation. In this work, a series of gelatin/genipin nanofibrous films were prepared as a patch for repairing TM perforation. Gelatin, a type of biomaterial with excellent electrospinning performance, has been used for preparing the nanofibers. The genipin, as a crosslinking agent, has been blended into the gelatin nanofibers. The reaction between gelatin and genipin engender suitable tensile strength and water-resistance for TM patch. The survival rate of human umbilical vein endothelial cells and fibroblasts demonstrated that the gelatin/genipin nanofiber scaffolds had good biocompatibility, which indicated the genipin was a kind of effective and nontoxic crosslinking agent for improving the mechanical property and water-resistance of gelatin films. In short, our work provides a novel macromolecular material with good mechanical properties, water-tolerance and excellent biocompatibility which could be used as a potential patch for TM repair.     

Suture pullout strength and in vitro fibroblast and RAW 264.7 monocyte biocompatibility of genipin crosslinked nanofibrous chitosan mats for guided tissue regeneration

Guided tissue regeneration (GTR) is a surgical technique used to direct the formation of bone in the graft space by protecting it with a barrier membrane used to exclude soft tissues during healing. Chitosan has been advocated for GTR applications because of its biocompatibility, degradability, wound healing, and osteogenic properties. In this study, electrospun chitosan membranes, crosslinked with 5 mM or 10 mM geinipin, a natural crosslinker extracted from the gardenia plant, were evaluated for suture pullout strength, crystallinity, and cytocompatibility with normal human dermal fibroblast and TIB 71(?) RAW 264.7 monocyte cells. Ultimate suture pullout strength was significantly lower (51-67%) than that of commercially available collagen membranes. Crystallinity of the electrospun chitosan mats decreased upon crosslinking by 14-17% (p = 0.013). The molecular weight of the chitosan polymer was decreased by 75% during the electrospinning process. Uncrosslinked and genipin-crosslinked chitosan mats were cytocompatible and supported fibroblast cell proliferation for 9 days. Uncrosslinked and genipin-crosslinked membranes did not activate monocytes to produce nitric oxide (NO) in vitro in the absence of lipopolysaccharide (LPS). Finally, chitosan membranes inhibited LPS-induced NO production of RAW 264.7 cells by 59-67% as compared to tissue culture plastic and collagen membrane. Improvements are needed in the tear strength of electrospun chitosan membranes for clinical application. ? 2012 Wiley Periodicals, Inc. J Biomed Mater Res Part A: 100A:2890-2896, 2012.     

In vitro evaluation of a chitosan membrane cross-linked with genipin.

The study was to evaluate the characteristics of a chitosan membrane cross-linked with a naturally-occurring cross-linking reagent, genipin. This newly-developed genipin-cross-linked chitosan membrane may be used as an implantable drug-delivery system. The chitosan membrane without cross-linking (fresh) and the glutaraldehyde-cross-linked chitosan membrane were used as controls. The characteristics of test chitosan membranes evaluated were their cross-linking degree, swelling ratio, mechanical properties. antimicrobial activity, cytotoxicity, and degradability. It was found that cross-linking of chitosan membrane using genipin increased its ultimate tensile strength but significantly reduced its strain-at-fracture and swelling ratio. There was no significant difference in antimicrobial activity between the genipin-cross-linked chitosan membrane and its fresh counterpart. Additionally, the results showed that the genipin-cross-linked chitosan membrane had a significantly less cytotoxicity and a slower degradation rate compared to the glutaraldehyde-cross-linked membrane. These results suggested that the genipin-cross-linked chitosan membrane may be a promising carrier for fabricating an implantable drug-delivery system. The drug-release characteristics of the genipin-cross-linked chitosan membrane are currently under investigation.     

In vitro evaluation of a chitosan membrane cross-linked with genipin

The study was to evaluate the characteristics of a chitosan membrane cross-linked with a naturally-occurring cross-linking reagent, genipin. This newly-developed genipin-cross-linked chitosan membrane may be used as an implantable drug-delivery system. The chitosan membrane without cross-linking (fresh) and the glutaraldehyde-cross-linked chitosan membrane were used as controls. The characteristics of test chitosan membranes evaluated were their cross-linking degree, swelling ratio, mechanical properties, antimicrobial activity, cytotoxicity, and degradability. It was found that cross-linking of chitosan membrane using genipin increased its ultimate tensile strength but significantly reduced its strain-at-fracture and swelling ratio. There was no significant difference in antimicrobial activity between the genipin-cross-linked chitosan membrane and its fresh counterpart. Additionally, the results showed that the genipin-cross-linked chitosan membrane had a significantly less cytotoxicity and a slower degradation rate compared to the glutaraldehyde-cross-linked membrane. These results suggested that the genipin-cross-linked chitosan membrane may be a promising carrier for fabricating an implantable drug-delivery system. The drug-release characteristics of the genipin-cross-linked chitosan membrane are currently under investigation.     

In vitro evaluation of degradation and cytotoxicity of a novel composite as a bone substitute

The purpose of this study was to prepare and evaluate in vitro the feasibility and cytocompatibility of a novel composite (GGT) as a large defect bone substitute. The composite is tricalcium phosphate ceramic particles combined with genipin crosslinked gelatin. After soaking the GGT composites in Ringer solutions at 37 degrees C for 7, 14, 28, 42, 56, and 84 days, the in vitro biologic degradation rate and biocompatibility were determined. Substances released from soaked GGT composites were analyzed with an ultraviolet visible light spectrophotometer. In addition, the solution soaking the GGT was co-cultured with osteoblasts to determine whether or not the released substances from GGT could facilitate the growth of bone cells. After they had been cultured for 2 days, the osteoblasts were tested for differentiation and proliferation by alkaline phosphatase (ALP) activity and a MTT assay. Results indicate that the concentration of the genipin solution is a critical factor in deciding the crosslinking degree of the GGT composite. Complete crosslinking reaction in the GGT composite occurred when 0.5 wt % of genipin had been added. Cytotoxic testing revealed that 80 ppm of the genipin in the culture medium served as the level over which cytotoxicity to osteoblasts could be produced. In addition, we found that gelatin and calcium continuously were released from the GGT composite in the soaking solution, which promoted differentiation and proliferation of the osteoblasts.     

京尼平交联明胶特性随时间变化的研究

研究了京尼平交联明胶材料的交联度、细胞毒性、溶胀度、降解率等特性随交联时间的变化.用1%京尼平交联明胶,按交联时间分为7组:10 min组、30 min组、1 h组、2 h组、12 h组、24 h组、72 h组.结果显示京尼平可有效交联明胶,随着交联时间延长,交联度增加,溶胀度和降解率降低.交联10 min的材料,交联度低(26.7%),溶胀度高(265%),不到一周就完全降解,说明材料很不稳定,易降解;交联30min的材料,交联度(45.7%)、溶胀度(207%)、降解率与10 min材料比都有明显变化,4周未完全降解,8周完全降解,说明京尼平可以在30 min内显著改变明胶性能;30 min后的材料,随交联时间延长,交联度逐渐增加,溶胀度和降解率逐渐降低.交联72 h的材料,交联度73.1%,溶胀度153%,12周仅降解15.6%.MTT法测各组材料细胞增殖率在87.9%～105.4%之间,说明京尼平交联明胶材料细胞毒性均很低.     

Crosslinking of biological tissues using genipin and/or carbodiimide

The study was to investigate the crosslinking characteristics, mechanical properties, and resistance against enzymatic degradation of biological tissues after fixation with genipin (a naturally occurring crosslinking agent) and/or carbodiimide. Fresh tissue was used as a control. It was found that both genipin and carbodiimide are effective crosslinking agents for tissue fixation and genipin crosslinking is comparatively slower than carbodiimide crosslinking. Additionally, tissue fixation in genipin and/or carbodiimide may produce distinct crosslinking structures. Carbodiimide may form intrahelical and interhelical crosslinks within or between tropocollagen molecules, whereas genipin may further introduce intermicrofibrillar crosslinks between adjacent collagen microfibrils. The stability (denaturation temperature and resistance against enzymatic degradation) of the fixed tissue is mainly determined by its intrahelical and interhelical crosslinks. In contrast, intermicrofibrillar crosslinks significantly affect the mechanical properties (tissue shrinkage during fixation, tensile strength, strain at break, and ruptured pattern) of the fixed tissue. Moreover, the degree of enzymatic degradation of the fixed tissue may be influenced by three factors: the availability, to the enzyme, of recognizable cleavage sites, the degree of crosslinking, and the extent of helical integrity of tropocollagen molecules in tissue.     

Effects of crosslinking degree of an acellular biological tissue on its tissue regeneration pattern

It was reported that acellular biological tissues can provide a natural microenvironment for host cell migration and may be used as a scaffold for tissue regeneration. To reduce antigenicity, biological tissues have to be fixed with a crosslinking agent before implantation. As a tissue-engineering scaffold, it is speculated that the crosslinking degree of an acellular tissue may affect its tissue regeneration pattern. In the study, a cell extraction process was employed to remove the cellular components from bovine pericardia. The acellular tissues then were fixed with genipin at various known concentrations to obtain varying degrees of crosslinking. It was shown in the in vitro degradation study that after fixing with genipin, the resistance against enzymatic degradation of the acellular tissue increased significantly with increasing its crosslinking degree. In the in vivo subcutaneous study, it was found that cells (inflammatory cells, fibroblasts, endothelial cells, and red blood cells) were able to infiltrate into acellular tissues. Generally, the depth of cell infiltration into the acellular tissue decreased with increasing its crosslinking degree. Infiltration of inflammatory cells was accompanied by degradation of the acellular tissue. Due to early degradation, no tissue regeneration was observed within fresh (without crosslinking) and the 30%-degree-crosslinking acellular tissues. This is because the scaffolds provided by these two samples were already completely degraded before the infiltrated cells began to secrete their own extracellular matrix. In contrast, tissue regeneration (fibroblasts, neo-collagen fibrils, and neo-capillaries) was observed for the 60%- and 95%-degree-crosslinking acellular tissues by the histological examination, immunohistological staining, transmission electron microscopy, and denaturation temperature measurement. The 95%-degree-crosslinking acellular tissue was more resistant against enzymatic degradation than its 60%-degree-crosslinking counterpart. Consequently, tissue regeneration was limited in the outer layer of the 95%-degree-crosslinking acellular tissue throughout the entire course of the study (1-year postoperatively), while tissue regeneration was observed within the entire sample for the 60%-degree-crosslinking acellular tissue. In conclusion, the crosslinking degree determines the degradation rate of the acellular tissue and its tissue regeneration pattern.     

Effects of bFGF incorporated into a gelatin sheet on wound healing

Basic fibroblast growth factor (bFGF) is well known to promote the proliferation of almost all cells associated with wound healing. However, as the activation duration of bFGF is very short in vivo, we incorporated bFGF into an acidic gelatin hydrogel and studied the sustained release of bFGF in vivo. In addition, we investigated the effects of the acidic gelatin sheet containing bFGF on wound healing. To distinguish wound contraction from neoepithelialization, we measured both the wound area and neoepithelium length. Other histological parameters such as thickness of granulation tissue and number of capillaries were also determined as indices of wound healing. Fibrous tissue was assessed using an Elastica van Gieson and Azan stain. A skin defect (1.5 x 1.5 cm) of full thickness was created on the back of each test mouse and the wound was covered with an acidic gelatin hydrogel, referred to as a gelatin sheet in this study (2 x 2 cm), with bFGF (100 microg/site) (A) or without bFGF (B). 1, 2, 3, 5, 7 and 14 days after covering, mice were killed and an enzyme-linked immunosorbent assay (ELISA) was performed to estimate the concentration of bFGF in the plasma. In another experiment, each wound was covered with (A), (B) or a hydrogel dressing (control group, C) and the wound area was measured 1 or 2 weeks postoperatively with a computer planimeter. The histological parameters, as mentioned above, were assessed using a light microscope. Sustained release of bFGF from the gelatin sheet was observed and the gelatin sheet containing bFGF promoted neoepithelialization, granulation, neovascularization and wound closure. This gelatin sheet containing bFGF was concluded to be effective for wound healing and promising for clinical use.     

Dose- and time-dependent effects of genipin crosslinking on cell viability and tissue mechanics – Toward clinical application for tendon repair

The crosslinking agent genipin is increasingly invoked for the mechanical augmentation of collagen tissues and implants, and has previously been demonstrated to arrest mechanical damage accumulation in various tissues. This study established an in vitro dose–response baseline for the effects of genipin treatment on tendon cells and their matrix, with a view to in vivo application to the repair of partial tendon tears. Regression models based on a broad range of experimental data were used to delineate the range of concentrations that are likely to achieve functionally effective crosslinking, and predict the corresponding degree of cell loss and diminished metabolic activity that can be expected. On these data, it was concluded that rapid mechanical augmentation of tissue properties can only be achieved by accepting some degree of cytotoxicity, yet that post-treatment cell survival may be adequate to eventually repopulate and stabilize the tissue. On this basis, development of delivery strategies and subsequent in vivo study seems warranted.     

Gelatin-derived bioadhesives for closing skin wounds: An in vivo study

Bioadhesives have been used in surgery as hemostatic and wound healing agents. GRF (gelatin + resorcinol + formaldehyde) glue, composed of a mixture of gelatin and resorcinol polymerized by the addition of formaldehyde, has been used for this purpose. Widespread acceptance of the GRF glue, however, has been limited by reports of cytotoxicity due to its release of formaldehyde upon degradation. It has been suggested by Wertzel et al. that the cytotoxicity problem of GRF glue may be overcome by changing its cross-linking method. The study was, therefore, undertaken to assess the feasibility of using a water-soluble carbodiimide or genipin to cross-link gelatin as new bioadhesives to close skin wound lesions in a rat model. Formaldehyde-cross-linked counterpart (GRF glue) and a resorbable suture were used as controls. It was noted that the tensile strength of the skin across each wound treated by either application of test glues or suture increased consistently with time during the healing process. Also, the wounds repaired by test glues or suture caused no calcification. The suture used in the study was completely resorbed at the wound area in about 6 days postoperatively. However, the durations required to completely resorb the carbodiimide-or genipin-cross-linked glues were approximately the same (9 days), while it took about 14 days to completely resorb the formaldehyde-cross-linked glue. The healing process for the suture wound repaired was more rapid than those treated by test glues. Of the test glues, the wounds treated by the carbodiimide- or genipin-cross-linked glues induced less inflammatory response and recovered sooner than that treated by the formaldehyde-cross-linked glue. This indicated that the biocompatibility of the carbodiimide- or genipin-cross-linked glues was superior to the formaldehyde-cross-linked glue. The results of this study may serve as a preliminary experimental model for the further investigation of both the carbodiimide- and genipin-cross-linked glues when applied to human skin closure.     

Gelatin-derived bioadhesives for closing skin wounds: an in vivo study.

Bioadhesives have been used in surgery as hemostatic and wound healing agents. GRF (gelatin + resorcinol + formaldehyde) glue, composed of a mixture of gelatin and resorcinol polymerized by the addition of formaldehyde, has been used for this purpose. Widespread acceptance of the GRF glue, however, has been limited by reports of cytotoxicity due to its release of formaldehyde upon degradation. It has been suggested by Wertzel et al. that the cytotoxicity problem of GRF glue may be overcome by changing its cross-linking method. The study was, therefore, undertaken to assess the feasibility of using a water-soluble carbodiimide or genipin to cross-link gelatin as new bioadhesives to close skin wound lesions in a rat model. Formaldehyde-cross-linked counterpart (GRF glue) and a resorbable suture were used as controls. It was noted that the tensile strength of the skin across each wound treated by either application of test glues or suture increased consistently with time during the healing process. Also, the wounds repaired by test glues or suture caused no calcification. The suture used in the study was completely resorbed at the wound area in about 6 days postoperatively. However, the durations required to completely resorb the carbodiimide- or genipin-cross-linked glues were approximately the same (9 days), while it took about 14 days to completely resorb the formaldehyde-cross-linked glue. The healing process for the suture wound repaired was more rapid than those treated by test glues. Of the test glues, the wounds treated by the carbodiimide- or genipin-cross-linked glues induced less inflammatory response and recovered sooner than that treated by the formaldehyde-cross-linked glue. This indicated that the biocompatibility of the carbodiimide- or genipin-cross-linked glues was superior to the formaldehyde-cross-linked glue. The results of this study may serve as a preliminary experimental model for the further investigation of both the carbodiimide- and genipin-cross-linked glues when applied to human skin closure.     

EGF containing gelatin-based wound dressings

In case of bulk loss of tissue or non-healing wounds such as burns, trauma, diabetic, decubitus and venous stasis ulcers, a proper wound dressing is needed to cover the wound area, protect the damaged tissue, and if possible to activate the cell proliferation and stimulate the healing process. In this study, synthesis of a novel polymeric bilayer wound dressing containing epidermal growth-factor (EGF) -loaded microspheres was aimed. For this purpose, a natural, nontoxic and biocompatible material, gelatin, was chosen as the underlying layer and various porous matrices in sponge form were prepared from gelatin by freeze-drying technique. As the external layer, elastomeric polyurethane membranes were used. Two different doses of EGF was added into the prepared gelatin sponges (1 and 15 microg/cm2) to activate cell proliferation. EGF addition was carried out either in free form or within microspheres to achieve prolonged release of EGF for higher efficiency. The prepared systems were tested in in vivo experiments on full-thickness skin defects created on rabbits. At certain intervals, wound areas were measured and tissues from wound areas were biopsied and processed for histological examinations. The wound areas decreased upon low-dose EGF application but the difference between the affects of free EGF and microsphere loaded EGF was not so distinct. Upon increasing the dose of EGF by a factor of 15, it was observed that controlled release of EGF from microspheres provided a higher degree of reduction in the wound areas. Histological investigations showed that the prepared dressings were biocompatible and did not cause any mononuclear cell infiltration or foreign body reaction. The structure of the newly formed dermis was almost the same as that of the normal skin.     

Biocompatibility and biodegradation of a bone composite containing tricalcium phosphate and genipin crosslinked gelatin

A biodegradable composite (GGT) containing tricalcium phosphate ceramic particles and genipin crosslinked gelatin was developed for use as a bone substitute. The objective of this study was to assess the biocompatibility and the osteoconductivity of the GGT composite on new bone formation in vitro. Additionally, biodegradation and biocompatibility of the GGT composite in animals were investigated. Results of the GGT composites cocultured with osteoblasts showed that the concentration of genipin used as a crosslinking agent should be <0.5 wt % to avoid cytotoxicity. For in vivo degradation studies, we found that when the concentration of genipin in the composite <0.5 wt % was not enough to fully crosslink the gelatin, it results in a rapid degradation of the gelatin-genipin mixture. However, we also found that the foreign body capsule surrounding the GGT composite containing 1.0 wt % of the genipin was much thicker than that in the other three groups, that is, the composites containing 0.05, 0.1, and 0.5 wt % of the genipin. We therefore concluded that the ideal concentration of genipin used in the GGT was 0.5 wt %. Finally, we examined the organ culture units, which were maintained in cultured medium for 5 weeks. Morphology of tissue was observed and the quantitative evaluation of the regenerated bone was determined. We found that the GGT composites containing 0.5 wt % of the genipin had an excellent biocompatibility and could produce osteoconduction for the regenerating bone tissues.     

Physico-mechanical properties of wound dressing material and its biomedical application

A bioadhesive wound dressing material, based on gelatin, was prepared by solution casting, and its properties were evaluated. The tensile strength (TS) and percentage elongation at break (Eb) of the membranes were found to be 12.7 MPa and 40.4%, respectively. The buffer uptake and water uptake of the prepared membranes were found to be 298 and 312%, respectively, after 8 min. A scanning electron micrograph of the membrane revealed its uniform porosity, which is an essential criterion to be an ideal wound dressing. From microbial sensitivity analysis, it was found that the membrane had a significant resistance against infection. The wound-healing characteristics of the membrane were evaluated using a rat (Rattus norvegicus) model. Full-thickness wounds were created on the ventral side of the Rattus norvegicus and were dressed with the membrane; eco-plast was used as a control. The wound healing and bioadhesion were monitored at 3-day intervals by real-time imaging. The results revealed that the prepared membrane was more effective in healing the wound than conventional wound dressing.     

Controlled release of sphingosine-1-phosphate agonist with gelatin hydrogels for macrophage recruitment

The objective of this study is to design a drug delivery system (DDS) for the in vivo promotion of macrophage recruitment. As the drug, a water-insoluble agonist of sphingosine-1-phosphate type 1 receptor (SEW2871) was selected. SEW2871 (SEW) was water-solubilized by micelle formation with gelatin grafted by l-lactic acid oligomer. SEW micelles were mixed with gelatin, followed by dehydrothermal crosslinking of gelatin to obtain gelatin hydrogels incorporating SEW micelles. SEW was released from the hydrogels incorporating SEW micelles in vitro and in vivo. The water-solubilized SEW showed in vitro macrophage migration activity. When implanted into the back subcutis or the skin wound defect of mice, the hydrogel incorporating SEW micelles promoted macrophage migration toward the tissue around the implanted site to a significantly great extent compared with SEW-free hydrogel and that mixed with SEW micelles. The hydrogel is a promising DDS to enhance macrophage recruitment in vivo.