In vitro and in vivo degradation behavior of aqueous-derived electrospun silk fibroin scaffolds

We investigated the in vitro degradation behavior of the electrospun silk fibroin (SF) scaffolds by protease XIV. Phosphate-buffered saline (PBS) without enzyme was used as a control. About 65% of the electrospun SF scaffolds were degraded within 24 d in protease XIV, while almost no scaffolds were degraded in PBS. A great deal of fragments was visible in protease XIV solution. SEM indicated surface erosion of the scaffolds increased during protease degradation with increasing exposure time. FTIR and XRD indicated the crystalline structure of the scaffolds decreased after protease degradation for 24 d, and a degradation mechanism was proposed. Furthermore, the results of the in vivo degradation by implantation in rats showed that the scaffolds were completely degraded in vivo after implantation for 8 weeks and well tolerated by the host animals. The insights gained in this study can serve as a guide to match desired degradation behavior with specific applications for the electrospun SF scaffolds, such as tissue engineering and drug delivery.     

Gelation time and degradation rate of chitosan-based injectable hydrogel

Gelation time and degradation rate of thermally-sensitive aqueous solutions of chitosan/Gp (glycerophosphate disodium salt) have been studied. The effects of different parameters such as Gp salt concentration, solution temperature, degree of deacetylation of chitosan (DDA) and drug loading on the gelation time have been investigated. Gravimetric analysis, gel permeation chromatography and FTIR spectrophotometry were used to investigate the influence of the DDA and concentration of chitosan solution on hydrogel degradation. The presented results indicated that gelation time decreases by increasing Gp salt concentration, temperature, concentration and DDA of chitosan solutions, while drug loading has no significant effect on gelation time. Slower degradation profile was recorded for hydrogel with the higher DDA and concentration of chitosan in the primary solution. FTIR studies indicated that the chemical structure of chitosan macromolecules does not change significantly during the degradation. It could be concluded that biodegradation of chitosan hydrogel occurred via its surfaces.     

Degradation of polyurethanes in vitro and in vitro: comparison of different models

This study compares and contrasts mechanisms of polyetherurethane (PEU) degradation in vitro and in vivo. Models comprising incubation with hydrogen peroxide in vitro (H₂O₂), in vivo subcutaneous rat implant (SUBQ), and subcutaneous rat cage implant (CAGE) are described and compared with in vivo degradation of the pacemaker lead device retrieved after human implant (PACE). Experimental results support the hypothesis that stress accelerates PEU degradation. Scanning electron microscopy (SEM), gel permeation chromatography (GPC), and Fourier transform IR spectroscopy/attenuated total reflectance (FT-1R/ATR) evaluation of tested PEU samples suggests, for all models, decreased soft segment and increased ester functionality at the polymer surface. These observations are consistent with a single, metal ion catalyzed, polyester intermediate, oxidative degradation mechanism common to all models, and with device performance in vivo. Model comparison suggests that in vitro H₂O₂ and in vivo SUBQ and CAGE models accurately mimic in vivo degradation of the pacemaker lead device (PACE).     

Degradation behaviors of nerve guidance conduits made up of silk fibroin in vitro and in vivo

We have developed a new design of nerve guidance conduits (NGCs) made up of silk fibroin (SF), referred to as SF-NGCs, by a well-established method. The present study aimed to comprehensively investigate the degradation behaviors of SF-NGCs versus SF fibers. After they were allowed to incubate in the protease XIV solution or to be subcutaneously implanted in rabbits, SF-NGCs and SF fibers were subjected to degradation level measurement, mass loss assessment and gel electrophoresis, or light and electron microscopy and mass loss assessment for testing the dynamic course of in vitro or in vivo degradation. The results collectively indicated that SF-NGCs were able to degrade at a significantly increasing rate as compared to SF fibers, thus meeting the requirements of peripheral nerve regeneration. Furthermore, based on the possible involvement pathway in the in vivo degradation of SF-NGCs, the time-dependent changes in the mRNA level of lysosome-related genes (Hip1R, cathepsin D, and tPA) in subcutaneous implantation site within 24-week period post-implantation was determined by real-time RT-PCR, and the resulting data might contribute to our understanding of the molecular aspects that affect in vivo degradation and absorption of SF-NGCs.     

Ultrasound augmenting injectable chemotaxis hydrogel for articular cartilage repair in osteoarthritis

The increasing incidence of osteoarthritis (OA) seriously affects life quality, posing a huge socioeconomic burden. Tissue engineering technology has become a hot topic in articular cartilage repair as one of the key treatment methods to alleviate OA. Hydrogel, one of the most commonly used scaffold materials, can provide a good extracellular matrix microenvironment for seed cells such as bone marrow mesenchymal stem cells (BMSCs), which can promote cartilage regeneration. However, the low homing rate of stem cells severely limits their role in promoting articular cartilage regeneration. Stromal cell-derived factor-1α (SDF-1α) plays a crucial role in the activation, mobilization, homing, and migration of MSCs. Herein, a novel injectable chemotaxis hydrogel, composed of chitosan-based injectable hydrogel and embedding SDF-1α-loaded nanodroplets (PFP@NDs-PEG-SDF-1α) was designed and fabricated. The ultrasound was then used to augment the injectable chemotaxis hydrogel and promote the homing migration of BMSCs for OA cartilage repair. The effect of ultrasound augmenting injectable PFP@NDs-PEG-SDF-1α/hydrogel on the migration of BMSCs was verified in vitro and in vivo, which remarkably promotes stem cell homing and the repair of cartilage in the OA model. Therefore, the treatment strategy of ultrasound augmenting injectable chemotaxis hydrogel has a bright potential for OA articular cartilage repair.     

In vivo degradation behavior of Ca-deficient hydroxyapatite coated Mg-Zn-Ca alloy for bone implant application

In present paper, an in vivo study was carried out on uncoated and calcium-deficient hydroxyapatite (Ca-def HA) coated Mg-Zn-Ca alloy to investigate the effect of Ca-def HA coating on the degradation behavior and bone response of magnesium substrate. Magnesium alloy rods were implanted into rabbit femora and evaluated during 24 weeks implantation. The characterization of both implants indicates that in vivo degradation of the Ca-def HA coating and magnesium substrate occurs almost simultaneously, and in vivo valid life of the coating is about 8 weeks, after that the degradation rate of the coated implants increases obviously. The main reasons for the Ca-def HA coating degradation can be attributed to its reaction with body fluid and the substitution of Mg²⁺ ions in Ca-def HA. Histopathological examinations show that the Ca-def HA coating has good osteoconductivity and is in favor of the formation of more new bone on the surface of magnesium alloy. So the Ca-def HA coating could not only slow down in vivo degradation of magnesium alloy but also improve its bone response.     

鼠肝星状细胞体内与体外激活的显微拉曼光谱

采用密度梯度离心法从肝组织中分离、提纯肝星状细胞, 进行常规细胞鉴定后, 通过体外培养诱导肝星状细胞体外活化, 在不同的时间点上进行原位拉曼光谱表征; 通过一次性腹腔注射CCl4诱导鼠急性肝损伤, 取不同的时间点的肝损伤组织做拉曼光谱表征, 并以肝组织的光谱变化来间接反映肝星状细胞的体内活化. 结果表明, 用拉曼光谱能快速、 灵敏地监测肝星状细胞体内和体外活化过程中的分子变化, 可为肝纤维化的早期诊断提供依据.     

The in vitro and in vivo toxicity of gold nanoparticles

Gold nanoparticles,owing to their unique physicochemical and optical properties,well-established synthetic methods and easy modifications,have been widely used in biomedical science.Therefore,for their safe and efficient applications,much attention has been given to the toxicological evaluations of gold nanoparticles in biological systems.A large number of studies focusing on this problem have been carried out during the past years.However,the researches on gold nanoparticles toxicity still remain fragmentary and even contradictory with each other.This may be caused by the variety in experimental conditions.In this review,we aim to provide a better understanding about the in vitro and in vivo toxicity of gold nanoparticles by reviewing and describing the up to date literatures related to this problem and we mainly focused on these properties such as the particle size and shape,the surface charge and modification.Besides,we also summarized the adverse effect of gold nanoparticles on immune systems and analyzed the origin of the toxicity.     

In vitro and in vivo metabolism studies of dimethazine

The use of anabolic steroids is prohibited in sports. Effective control is done by monitoring their metabolites in urine samples collected from athletes. Ethical objections however restrict the use of designer steroids in human administration studies. To overcome these problems alternative in vitro and in vivo models were developed to identify metabolites and to assure a fast response by anti‐doping laboratories to evolutions on the steroid market. In this study human liver microsomes and an uPA^+/+‐SCID chimeric mouse model were used to elucidate the metabolism of a steroid product called ‘Xtreme DMZ’. This product contains the designer steroid dimethazine (DMZ), which consists of two methasterone molecules linked by an azine group. In the performed stability study, degradation from dimethazine to methasterone was observed. By a combination of LC‐High Resolution Mass Spectrometry (HRMS) and GC‐MS(/MS) analysis methasterone and six other dimethazine metabolites (M1–M6), which are all methasterone metabolites, could be detected besides the parent compound in both models. The phase II metabolism of dimethazine was also investigated in the mouse urine samples. Only metabolites M1 and M2 were exclusively detected in the glucuro‐conjugated fraction; all other compounds were also found in the free fraction. For effective control of DMZ misuse in doping control samples, screening for methasterone and methasterone metabolites should be sufficient. Copyright © 2016 John Wiley & Sons, Ltd.     

In vitro and in vivo metabolisms of K-48

Metabolic pathways of the oxime K-48 have been elucidated by means of in vitro and in vivo experiments. K-48 exposure to rat liver microsomal fraction resulted in the formation of a hydroxylated derivative, in addition to a small molecular fragment. The in vivo metabolism in rats was investigated after intramuscular administration of 50 μmol oxime. K-48 was present in the rat serum in unchanged form. Similarly, the analysis of rat cerebrospinal fluid indicated the sole occurrence of unchanged K-48. In contrast, unchanged K-48 was not found in the rat urine, where only the metabolite generated by epoxidation on the alkyl chain connecting the two pyridinium rings was present. The presence of unchanged K-48 in the serum and cerebrospinal fluid facilitates quantitative determination using HPLC separation and ultraviolet absorbance detection. Figure Suggested metabolic pathways of K-48     

Study on oxidative degradation behaviors of polyesterurethane network

In this study H₂O₂/CoCl₂ system was used as an oxidative environment to investigate the in vitro degradation behavior of a crosslinked polyesterurethane network. Weight loss, water absorption, mechanical properties, swelling degree and gel content were determined as a function of degradation time. The results showed that the H₂O₂/CoCl₂ system could effectively accelerate the degradation of the polyurethanes. The samples had almost completely degraded after 84 days of incubation in a 3% H₂O₂/2% CoCl₂ solution at 37 °C. The weight loss process could be approximately divided into three major phases: the weight decreased slowly during an induction phase (1), which was followed by a phase characterized by accelerated weight loss (2), and finally by a phase showing slow linear weight loss until complete erosion (3). The attenuated total reflectance-Fourier transform infrared (ATR-FTIR) spectra of degraded polyurethane networks showed that the polyurethane underwent chain scission of the copolyester segment chains, and the joints of copolyester and 2,2,4- and 2,4,4-trimethylhexamethylene during degradation in the oxidative environment. The glass transition temperature of degraded polyesterurethane networks decreased significantly with increasing degradation time. From these results the H₂O₂/CoCl₂ system can be used as an oxidative condition to evaluate the in vitro degradability of polyesterurethane.     

Viscoelasticity,mechanical properties,and in vivo biocompatibility of injectable polyvinyl alcohol/bioactive glass composite hydrogels as potential bone tissue scaffolds

Abstract

An injectable composite hydrogel composed of polyvinyl alcohol (PVA) and bioactive glass (BG) particles were synthesized by a physical crosslinking approach. The morphology, mechanical properties, and viscoelasticity of the PVA/BG composite hydrogel were characterized. Scanning electronic microscopy (SEM) showed uniform and homogeneous distribution of BG particles throughout the composite hydrogel. The incorporation of 2.5?wt% of BG particles in the composite hydrogel formulations, enhanced the static compressive strength and static elastic modulus by 325% and 150%, respectively. The storage molds (G′) was greater than the loss modules (G′′) at all the frequency range studied, which revealed a self-standing elastic composite hydrogel with a smooth injectability. The PVA/BG composite hydrogel was also implanted subcutaneously in the dorsal region of adult male rats. After 4?weeks of implantation, no inflammatory cells were seen within and around the implant, which indicated that the composite hydrogel was biocompatible. The properties of the synthesized injectable PVA/BG composite hydrogel demonstrate its capability toward bone regeneration.     

In vivo toxicological effects and spectral studies of new triorganotin(IV)-N-maleoyltranexamates

Multinuclear NMR (¹H, ¹³C and ¹¹⁹Sn), FT-IR, ^119mSn Mössbauer spectroscopy, elemental analysis and MS have been carried out for five newly synthesized triorganotin(IV) esters of N-maleoyl-protected tranexamic acid. As per spectroscopic outcome these are five-coordinate polymers with bridging carboxylate group in the solid state, while five-coordinated in trigonal bipyramidal geometry in solution form. Elemental analysis and MS data confirmed the 1:1 ligand to metal ratio and spectroscopic data. These complexes were tested in vitro against various human tumoural cell lines, in vivo in mice and found to be active. Further complexes 4 and 5 showed higher toxicity as compared to complexes 1-3 and the ligand. The nature (alkyl/phenyl/aryl) and size of covalently attached R′ groups of Sn(IV) atom and partition coefficients played a key role in the toxicities of the reported complexes.     

Photo-crosslinking copolymers based polyanhydride and 1G polyamidoamine-methacrylamide as bone tissue engineering: Synthesis, characterization, and in vitro degradation

In the past decade, Biodegradable materials that are capable of in situ formation have attracted increased attention for use in restorative orthopedic devices. In this communication, the surface erosion biodegradable polymers derived from 1.0G-polyamidoamine-double bond (PAMAM-DB) and methacrylated sebacic anhydrides (MSA) were evaluated over 2 months period under physiological conditions. Rectangular shaped samples were prepared by crosslinking the components using both chemical and photo initiators and exposure to UV light. The effects of PAMAM-DB: MSA ratio on local pH, water uptake, mass loss, and mechanical properties were explored. Polymers were characterized by ¹H NMR, ¹³C NMR, FT-IR, compressive strength testing and SEM. It is found that copolymer with 50-60% PAMAM-DB (mass fraction) show more excellent mechanical properties compared with other formulations. Copolymers degraded mainly by surface erosion but the bulk erosion pattern also appeared at the initial time of degradation for formulation 30% and 40%. The material was expected to be useful for drug controlled delivery, tissue engineering scaffold and other biomedical applications.     

Hydrophobically modified hydrogels containing azoaromatic cross-links: swelling properties, degradation in vivo and application in drug delivery

Hydrogels based on n-alkyl methacrylate esters (n-AMA) of various chain lengths, acrylic acid, and acrylamide cross-linked with 4,4-di(methacryloylamino)azobenzene were synthesized. The equilibrium swelling degree of the hydrogels in buffered solutions at pH 7.4 was shown to be very low in the pH range of the stomach. The entire swelling processes of the gels in the gastrointestinal tract were mainly dependent on those in the small intestine. In the buffered solution of pH 7.4 the diffusion of water into the gel slabs was discussed on the stress relaxation model of polymer chains. The results obtained are in good agreement with Schott's second-order diffusion kinetics. The biodegradability in vivo of their azobenzene cross-linking groups as well as the mechanism of degradation by cecal bacteria was studied. The gels are stable in the stomach but degradable by ananerobes present in the colon. The extent of degradation was considerably related to the equilibrium degree of swelling. The factors influencing the swelling degree were shown to influence the in vivo degradation of the gels. By changing these factors such as the degree of cross-linking, the length and content of the n-AMA side chains, it is possible to control both the degree of swelling and the degradation of the hydrogels.     

Intestinal metabolism of Polygonum cuspidatum in vitro and in vivo

Rhizoma et Radix Polygoni Cuspidati (RRPC) is commonly prescribed for the treatment of amenorrhea, arthralgia, jaundice and abscess in traditional Chinese medicine. Previous pharmacological studies have indicated that polyphenols are the main pharmacological active ingredients in RRPC. Meanwhile, the poor bioavailability of polyphenols in RRPC implies that those components are probably metabolized by intestinal bacteria before absorption. However, there is rather limited information about RRPC''s metabolites produced by intestinal bacteria and the intestinal absorbed constituents. In the present study, the metabolites were characterized after the aqueous extract of RRPC was incubated with the crude enzyme of human intestinal bacteria in vitro. The metabolic characteristics of glycosides in RRPC were figured out by comparing the metabolic profiles of emodin‐8‐O‐β‐d ‐glucopyranoside and polydatin between aqueous extract of RRPC and equivalent amounts of these two glycosides. The transitional constituents absorbed into blood were investigated in rats via intraduodental administration and portal vein intubation. A total of 38 prototype components and 43 metabolites were detected and characterized in vivo. The overall results demonstrated that the intestinal bacteria played an important role in the metabolism of RRPC, and the main metabolic pathways were hydrolysis in vitro, glucuronidation and sulfation in vivo.     

In vitro Degradation and Biocompatibility of Ca-P Coated Magnesium Alloy

Calcium-phosphate compounds(Ca-P) coating was prepared on an Mg-Al alloy(AZ60). Biodegradation of Ca-P coated magnesium alloy was evaluated in simulated body fluid(SBF) by examining the changes in magnesium ion concentration and pH value, which indicated that the Ca-P coating on magnesium alloy strongly affected the corrosion of magnesium alloy. Osteoblast MC3T3-E1 cells were utilized to investigate the cellular cytocompatibility. The cytocompatibility was measured by carrying out a series of tests, such as cholecystokinin-octapeptide(CCK-8) test, alkaline phosphatase activity(ALP) test, cellular morphology of hematoxylin-eosin(HE) staining and the induction of apoptosis. It was found that the cell function showed better in the Ca-P coated Mg-alloy extract than in the uncoated magnesium alloy extract. In summary, the results indicate that the Ca-P coating can improve the corrosion resistance of magnesium alloy and elevate cellular proliferation and differentiation of osteoblast MC3T3-E1 cells.     

体内和体外生物测定在环境监测中的应用

生物测定在环境毒物学研究中普遍用于检测人为污染物对个别生物体和生态系统的影响.这些测定适用于个别化学品或复杂的混合物(如废水)对有代表性的生物系统或整个生物体所引起的影响,并普遍应用于环境监测项目.生物测定可在生物体外或生物体内进行,前者是在实验室内利用细胞培养技术,后者除可在实验室内进行还可应用在真实的环境中.体外生物测定往往是用来研究环境样品中的污染物对生物机制的具体影响,如受体结合特性.而体内活性生物测定则提供了一个更加具体化的综合生物反应.然而,这两种类型的生物测定法可以测量许多不同的生物指标,如对生物生长及发育的影响、内分泌功能和DNA损伤.无论是在体内和体外生物测定都分别有其特有的优点和缺点,其中一些测定法可以使用于毒性鉴定和评价程序.本文简要介绍了体内和体外生物测定方法的基本特点及其在环境监测中的应用实例,指出化学物质如何影响有机体及生态系统的结构和功能,认为广泛发展更能充分反映生态系统生物多样性的生物测定方法,将有助于更准确地了解环境污染物对环境的潜在影响.     

Poly(D,L-lactide)-block-poly(2-hydroxyethyl acrylate) block copolymers as potential biomaterials for peripheral nerve repair: in vitro and in vivo degradation studies

The properties of poly(D ,L ‐lactide)‐block‐poly(2‐hydroxyethyl acrylate) (PLA‐b‐PHEA) block copolymers by means of in vitro / in vivo (rat) degradation are investigated and compared to those of PLA homopolymer. Over 12 weeks, we observe mass loss and molecular weight decrease. In vitro and in vivo findings are very similar for each polymer tested. When a short PHEA block is used (PLA‐b‐PHEA 15 000–3 000 g · mol^?1, 85/15 wt%), the degradation process is found to be very similar to that of homo‐PLA, and to be typical of a bulk erosion mechanism, with no mass loss observed until week 7 and continuous decrease of molar mass within this timeframe. For a longer PHEA block length within the block copolymer (PLA‐b‐PHEA 15 000–7 500 g · mol^?1, 65/35 wt%), the degradation mechanism is modified, with a significant mass loss observed at early times and only a slight decrease in molar mass. The latter finding is related to the pronounced hydrophilicity and softness of the material induced by the PHEA block, which allow easy diffusion and rapid leakage of the degradation residues from the material towards the aqueous medium. Schwann cells are found to better adhere on spin‐coated films of PLA‐b‐PHEA (85/15 wt%) than on PLA ones. These results show the potential of such hydrophilized PLA‐based copolymers for use in peripheral nerve repair.

     

PAM-microfabricated polyurethane scaffolds: in vivo and in vitro preliminary studies

Polymeric scaffolds were realised with linear degradable PU in the form of square, hexagonal and octagonal grids. They were characterised in terms of their mechanical properties. Analysis shows that the mechanical properties of the scaffolds depend on their geometries which are easily modulated using PAM. In vitro biological assays showed that PU promotes the adhesion and proliferation of fibroblast cells and that cell activities are better on PU scaffolds than on PU films. In vivo implantation of PU and PLGA scaffolds and PU films demonstrated that the scaffolds are completely resorbed after three months with a slight inflammatory response, while the PU film was still present after six months with an intense granulomatous reaction.