pVEGF-loaded lipopolysaccharide-amine nanopolymersomes for therapeutic angiogenesis.

Therapeutic angiogenesis via gene delivery is promising for tissue survival and regeneration after injury or ischemia. A stable, safe and efficient gene vector is essential for successful angiogenesis. We have demonstrated that our newly developed lipopolysaccharide-amine nanopolymersomes (LNPs) have higher than 95% transfection efficiency when delivering pEGFP into mesenchymal stem cells (MSCs). To explore their clinical potential in therapeutic angiogenesis, in this study, we studied their toxicity, storage stability, protection ability to genes and efficacy to deliver therapeutic genes of pVEGF in MSCs and zebrafish. The results show that LNPs can condense pVEGF to form pVEGF-loaded nanopolymersomes (VNPs), and protect pVEGF against DNase digestion in 6 h. Both LNPs and VNPs have low toxicity to MSCs, erythrocytes and zebrafish embryos. LNPs are stable at 4 °C for at least two years with unchanged size and transfection efficiency. MSCs transfected by VNPs continuously synthesize VEGF for at least four days under control, with a peak (21.25 ng ml(-1)) ∼35-fold greater than that for the untreated group. VNPs induce significant and dose-dependent angiogenesis in zebrafish without causing death, deformity or delay in growth and development, and the induced maximal vessel area of subintestinal vessel plexus is 2.5-fold higher than that for the untreated group. Our study suggests that VNP has high potential in therapeutic angiogenesis.

Efficient cytosolic delivery mediated by polymersomes facilely prepared from a degradable, amphiphilic, and amphoteric copolymer.

To solve problems in polymersome preparation caused by liposolubility of copolymers and to improve the cytosolic delivery efficiency of polymersomes to drugs, a lipopolysaccharide-amine (LPSA) copolymer with amphotericity and amphiphilicity is developed. LPSA contains two hydrophilic oppositely charged blocks (anionic oxidized alginate (OA), cationic polyethyleneimine (PEI 1.8 k)) and one hydrophobic block (cholesteryl), where OA is the backbone and cholesteryl-grafted PEI is the side chain. The two hydrophilic blocks first guarantee that LPSA will dissolve in water, and then help polymersome formation via electrostatic interactions to generate water insoluble interpolyelectrolyte complexes, which supplement the hydrophobic part to reach the right hydrophilicity/hydrophobicity ratio, and thus realize a one-step self-assembly of polymersomes in water. Our results show LPSA nanopolymersomes (LNPs) have low cytotoxicity and degradability, and an excellent ability to enter cells. TEM observation demonstrates that LNPs are entrapped in endosomes after endocytosis, and are then released to cytosols because of their strong endosomal escape capacity. As an example of cytosolic delivery to bioactive molecules, pDNA is delivered in mesenchymal stem cells, and more than 95% of cells express a large target protein, indicating that LNPs have high cytosolic delivery efficiency. Our study provides a novel, easy, and universal method to design copolymers for the preparation of polymersomes as efficient cytosolic delivery nanocarriers.

Dopamine-assisted co-deposition of hydroxyapatite-functionalised nanoparticles of polydopamine on implant surfaces to promote osteogenesis in environments with high ROS levels.

Environments with high reactive oxygen species (ROS) levels, which are common in patients with diseases such as diabetes, periodontitis, and osteoporosis, impair the osseointegration of implants. To address this issue, by using a one-pot dopamine-assisted co-deposition method, we constructed a three-dimensional coating of hydroxyapatite-functionalised nanoparticles of polydopamine (HA/nPDAs) on implant surfaces, where polydopamine is designed to protect cells via scavenging excessive ROS and HA facilitates osteogenesis. First, nanoparticles of polydopamine (nPDAs) were prepared by self-polymerization and assembly of dopamine under alkaline conditions, and HA/nPDAs were obtained by incubating nPDAs in simulated body fluid (SBF) due to metal chelation and ionic interactions triggered by the catechol moieties of PDA. Thereafter, HA/nPDAs with thickness of ~4 µm were constructed on titanium surfaces by immersing titanium discs in a weak alkaline solution of HA/nPDAs and dopamine through interface interactions driven by catechol chemistry. The properties of coatings (e.g., thickness, composition, hydrophilia and morphology) can be controlled by preparation conditions such as mineralization time and reactant concentration. The coatings display efficient ROS-scavenging ability, promote cell proliferation, and upregulate the activity of alkaline phosphatase and the expression of osteogenesis-related genes in environments with high or normal ROS levels, demonstrating the great promise of such coatings for osseointegration promotion, especially in the state of high ROS in diseases. This study provides a facile, efficient, mild, and universal strategy in engineering functional surfaces on any substrates for diversified applications by simple variation of co-deposited components, through taking advantages of versatile catechol chemistry and nanoparticles with stereo structure and great specific surface area.

Hydrogel eye drops as a non-invasive drug carrier for topical enhanced Adalimumab permeation and highly efficient uveitis treatment.

Uveitis is one of the most popular blind-causing eye diseases worldwide. Adalimumab (ADA) is used for the uveitis treatment through systemic or intravitreal injection at the expense of systemic side effects and increased medical risks. Although eye drops, a non-invasive topical treatment, could be a potential strategy to reduce side effects, it remains challenging to apply due to limited bioavailability mainly linked to poor retention time and permeation capacity for eye biological barriers. Here, we reported hydrogel eye drops composed of low-deacetylated chitosan and ß-glycerophosphate as an ADA carrier and tested its toxicity, tolerability, intraocular permeability, and efficacy of non-invasive treatment for uveitis. It's found the ADA-loaded hydrogel eye drops were more efficient than free ADA both in permeation rate and clinical efficacy for uveitis, Overall, this study provides a friendly non-invasive strategy to improve drug permeation rate and uveitis treatment efficacy, which may be valuable to clinically ophthalmic medication.

Constructing self-adhesive and robust functional films on titanium resistant to mechanical damage during dental implanting.

HYPOTHESIS: Osseointegration can be enhanced by introducing bioactive polyelectrolyte-multilayer films on implant surfaces. To guarantee films to function successfully in use, keeping structural integrity during implanting is necessary, which requires films with strong adhesion and cohesion to resist the mechanical damage. Catechol is considered as the origin of amazing adhesion of mussels. We hypothesize that catechol functionalization of polyelectrolytes enables film construction on implants in a non-aggressive way, and helps films resist mechanical damages during implanting. EXPERIMENTS: With lipopolysaccharide-amine nanopolymersomes (NPs), catechol-functionalized hyaluronic acid and NPs (cHA, cNPs) as a polycation, polyanion and primer, respectively, catechol-functionalized polyelectrolyte-multilayer films (cPEMs) were constructed on substrates via Layer-by-layer self-assembly. Effects of catechol functionalization on construction, surface properties, assembly mechanisms, structural integrity, mechanical properties and cytotoxicity of cPEMs were studied. FINDINGS: Self-adhesive cPEMs can be constructed on substrates, which grow exponentially and are driven by coordination, covalent bonding, electrostatic interactions, hydrogen bonding, etc. cPEMs with suitable catechol concentrations can resist mechanical damage to keep structural integrity in simulated clinical implantation, show stronger adhesion and cohesion than non-catechol-functionalized films in nanoscratch and nanoindentation tests, and are non-cytotoxic to MSCs. With excellent drug-loading and cytosolic-delivery capacity of NPs, cPEM is promising in improving osseointegration of implants.

The Construction of Biomimetic Cementum Through a Combination of Bioskiving and Fluorine-Containing Biomineralization.

Despite tremendous attention is given to the construction of biomimetic cementum for regeneration of tooth cementum, the lack of recapitulating the composition and hierarchical structure of cementum often leads to the poor performance of constructed materials. How to highly mimic the sophisticated composition and hierarchy of cementum remains a longstanding challenge in constructing the biomimetic cementum. Inspired by cementum formation process, a novel construction approach via a combination of bioskiving and fluorine-containing biomineralization is developed in this study. The alternative collagen lamellae (ACL) that can highly mimic the rotated plywood structure of cementum collagen matrix is fabricated via bioskiving. Followed by biomineralization in the amorphous calcium phosphate (ACP) solution with different concentration of fluorine, a series of biomimetic cementum is constructed. Screened by physicochemical characterization, the biomimetic cementum with the composition and hierarchical structure highly similar to human cementum is selected. Through in vitro biological assay, this biomimetic cementum is proven to significantly promote the adhesion, proliferation, and cementogenic differentiation of periodontal ligament cells (PDLCs). Furthermore, in vivo study demonstrates that biomimetic cementum could induce cementogenesis. This biomimetic cementum constructed via combinatory application of bioskiving and fluorine-containing biomineralization stands as a promising candidate for achieving cementum regeneration.

Primary treatment of acute dacryocystitis by endoscopic dacryocystorhinostomy with silicone intubation guided by a soft probe.

PURPOSE: To investigate the suitability of cold steel endonasal endoscopic dacryocystorhinostomy (EES-DCR) with circular bicanalicular intubation with silicone tubes (CBIST) guided by a soft probe for the primary treatment of acute purulent dacryocystitis (APD). DESIGN: Prospective, randomized, interventional case series. PARTICIPANTS: Seventy-two patients (59 females, 13 males) with a median presenting age of 55+/-12 years (range, 28-71 years). METHODS: Eighty-four patients with unilateral APD were equally and randomly divided into 2 groups. Cold steel EES-DCR was performed after the lacrimal abscess formation, and external dacryocystorhinostomy (E-DCR) was performed 1 to 2 weeks after resolution of the acute inflammation. In both groups, CBIST guided by a soft probe was performed and the silicone tubes were kept in the lacrimal passages for 3 months. Postoperative follow-up ranged from 12 to 24 months. Outcomes were compared between both groups, considering resolution time for external acute inflammation, success rate of free lacrimal passage reconstruction, and lack of complications as indicators of treatment suitability. MAIN OUTCOME MEASURES: Time for resolution of the external acute inflammation, success rate of free lacrimal passage reconstruction, and complications. RESULTS: In this study, complete postoperative data were acquired from 40 patients in the EES-DCR group and from 32 patients in the E-DCR group, and the outcomes were compared. Acute inflammation resolved more quickly in the EES-DCR group than in the E-DCR group (P<0.05). Ostium patency at 12 months after silicone tube removal was achieved in significantly more patients in the EES-DCR group (36/40 [90%]) than in the E-DCR group (21/32 [65.7%]; P<0.01). In the EES-DCR group, lacrimal passage reconstruction failed because of intranasal ostial closure in 3 patients and because of common canaliculus obstruction in 1 patient. In the E-DCR group, lacrimal passage reconstruction failed because of intranasal ostial closure in 3 patients, lacrimal sac fibrosis, granulation, or both in 6 patients, and common canaliculus obstruction in 2 patients. Other than the slight laceration of the inferior puncta, no significant complications arose from the treatments. CONCLUSIONS: Cold steel EES-DCR with CBIST guided by a soft probe is a promising alternative for the primary treatment of APD with abscess formation. FINANCIAL DISCLOSURE(S): The authors have no proprietary or commercial interest in any materials discussed in this article.

A new modified dura mater implant: characteristics in recipient dogs.

Duraplasty is critical to the maintenance of anatomical integrity and the protection of brain tissue. Allotransplantation of cadaveric dura mater was abandoned after it was found to transmit Creutzfeldt-Jakob disease (CJD). In this study, the usefulness of a xenogeneic dura mater for dural reconstruction was tested. Twelve dogs were randomly assigned to 4 groups. To simulate the condition of patients with brain surface injury, an area of approximately 2 cm x 1.5 cm of the dura mater was removed to create a defect. Xenogeneic dura mater derived from porcine pericardium was trimmed to the shape and size of the defect and sutured to the endogenous dura mater. Muscles at the apex of the skull and scalp were also sutured. Three dogs were euthanized at 3, 6, 9, and 12 months after implantation and the xenogeneic dura mater and surrounding endogenous tissue were examined macroscopically and microscopically. Three months after implantation, the graft site had begun to heal. Macroscopically, at 6, 9, and 12 months after implantation, the graft had healed completely with the surrounding tissue. No boundary between the graft and surrounding tissue was distinguishable, and the two could not be separated. The graft was smoothly epithelialized and nonadherent to the brain surface. Microscopically, the inner surface of the implant was covered with epithelial cells, and internal capillaries, subepithelial fibrous tissue deposition, and fibroblast proliferation were observed. The xenogeneic dura mater progressively degraded over time. No cysts and no neutrophilic or lymphocytic inflammatory cell response developed between the implant and the recipient brain parenchyma. The modified xenogeneic dura mater is sufficiently biocompatible to allow epithelialization of its inner surface without adherence to brain tissue. No abnormalities develop in recipients, and the xenograft is gradually biodegraded and replaced by endogenous tissue identical to the endogenous dura mater.

Comparison of osteogenic differentiation induced by siNoggin and pBMP-2 delivered by lipopolysaccharide-amine nanopolymersomes and underlying molecular mechanisms.

Purpose: Gene therapies via Noggin small interfering (si)RNA (siNoggin) and bone morphogenetic protein (BMP)-2 plasmid DNA (pBMP-2) may be promising strategies for bone repair/regeneration, but their ideal delivery vectors, efficacy difference, and underlying mechanisms have not been explored, so these issues were probed here. Methods: This study used lipopolysaccharide-amine nanopolymersomes (LNPs), an efficient cytosolic delivery vector developed by the research team, to mediate siNoggin and pBMP-2 to transfect MC3T3-E1 cells, respectively. The cytotoxicity, cell uptake, and gene knockdown efficiency of siNoggin-loaded LNPs (LNPs/siNoggin) were studied, then the osteogenic-differentiation efficacy of MC3T3-E1 cells treated by LNPs/pBMP-2 and LNPs/siNoggin, respectively, were compared by measuring the expression of osteogenesis-related genes and proteins, alkaline phosphatase (ALP) activity, and mineralization of the extracellular matrix at all osteogenic stages. Finally, the possible signaling pathways of the two treatments were explored. Results: LNPs delivered siNoggin into cells efficiently to silence 50% of Noggin expression without obvious cytotoxicity. LNPs/siNoggin and LNPs/pBMP-2 enhanced the osteogenic differentiation of MC3T3 E1 cells, but LNPs/siNoggin was better than LNPs/pBMP-2. BMP/Mothers against decapentaplegic homolog (Smad) and glycogen synthase kinase (GSK)-3ß/ß-catenin signaling pathways appeared to be involved in osteogenic differentiation induced by LNPs/siNoggin, but GSK-3ß/ß-catenin was not stimulated upon LNPs/pBMP-2 treatment. Conclusion: LNPs are safe and efficient delivery vectors for DNA and RNA, which may find wide applications in gene therapy. siNoggin treatment may be a more efficient strategy to enhance osteogenic differentiation than pBMP-2 treatment. LNPs loaded with siNoggin and/or pBMP-2 may provide new opportunities for the repair and regeneration of bone.

Directing the nanoparticle formation by the combination with small molecular assembly and polymeric assembly for topical suppression of ocular inflammation.

In this paper, we presented a simple yet versatile strategy to generate a high drug payload nanoparticles by the combination with small molecular assembly and polymeric assembly for topical suppression of ocular inflammation. Upon physical mixing of the succinated triamcinolone acetonide (TA-SA) supramolecular hydrogel with the poly (ethylene glycol)-poly (ɛ-caprolactone)-poly (ethylene glycol) (PECE) aqueous solution at 37 °C, TA-SA/PECE nanoparticles formed spontaneously and characterized thoroughly by transmission electron microscopy (TEM), X-ray diffraction (XRD) and differential scanning calorimetry (DSC). The formed TA-SA/PECE nanoparticles displayed a comparable in vitro anti-inflammatory efficacy to that of native triamcinolone acetonide (TA), through a significant downregulation of various proinflammatory cytokines levels (e.g., NO, TNF-α) in a lipopolysaccharide (LPS) actived RAW264.7 macrophage. Meanwhile, the enhanced transcorneal drug permeability of TA-SA/PECE nanoparticles over that of TA suspension was clearly observed in an isolated rabbit cornea. Intraocular biocompatibility test demonstrated that TA-SA/PECE nanoparticles presented good biocompatibility after topical instillation during entire study period. More importantly, the TA-SA/PECE nanoparticles displayed superior therapeutic efficacy over that of the TA suspension in the endotoxin-induced uveitis (EIU) rabbit model via decreasing neutrophil infiltration in anterior chamber. Overall, the proposed TA-SA/PECE nanoparticles might be a promising candidate for uveitis therapy.

Preparation of hydrophilic polyhydroxyalkyl glutamine crosslinked films and its biodegradability.

Polybenzyl glutamate (PBLG) or polymethyl glutamate (PMLG) films have been aminolyzed with amino alcohol and crosslinked with aliphatic diamine at 60 degrees C for 48 h simultaneously which led to the formation of crosslinked films of polyhydroxyalkyl glutamine (PHAG). ATR-IR indicates that for the aminolysis of PBLG with 2-amino-1-ethanol or 3-amino-1-propanol, benzyl glutamate almost completely turned to hydroxyalkyl glutamine, however for the aminolysis of PMLG with 5-amino-1-pentanol, methyl glutamate partially turned to hydroxypentanyl glutamine. The water-swelling test shows that water-swelling ratio Q of PHAG films from amino alcohol with longer carbon chain was smaller, the PHAG films crosslinked by 1,2-diamino ethane have the higher water-swelling ratio Q, but the PHAG films crosslinked by 1,8-diamino octane have the lower water swelling ratio Q; and PHAG films with a greater amount of crosslinking agents have high crosslinking density or the low water swelling-ratio Q for same amino alcohol and diamine. It is obvious from in vitro enzymatic hydrolysis test that specimens with smaller swelling ratio Q displayed larger T(1/2), time for half weight digestion of PHAG film, that is, less biodegradability. Therefore, biodegradability of the crosslinked PHAG films can be controlled by changing amino alcohol and diamine.

Combination of dexamethasone and Avastin® by supramolecular hydrogel attenuates the inflammatory corneal neovascularization in rat alkali burn model.

Corneal neovascularization (CNV) is one of the leading causes of vision loss and a high-risk factor for transplant rejection. The present study proposed a supramolecular hydrogel comprised of MPEG-PCL micelles and α-cyclodextrin (α-CD) for co-delivery of dexamethasone sodium phosphate (Dexp) and Avastin® (Ava), and further evaluated its therapeutic efficacy in rat alkali burn model. A physical mixing of Dexp/Ava, MPEG-PCL micelles, and α-CD aqueous solution leads to a spontaneous formation of the supramolecular hydrogel via a "host-guest" recognition between MPEG and α-CD. The supramolecular hydrogel provides a relatively quick release of Dexp over Ava during the study of the 5-day in vitro release. The results of in vitro cytotoxicity test and wound healing assay illustrated that the proposed supramolecular hydrogel was non-toxic against L-929 and HCEC cells and did not significantly affect the migration of HCEC cells after 24h incubation. The corneal distribution test suggested that the precorneal duration of Ava was significantly extended by the supramolecular hydrogel with respect to its solution formulation. Moreover, the supramolecular hydrogel showed high ocular biocompatibility and was a non-irritant after topical instillation. Furthermore, the Dexp-Ava hydrogel medication, but not by Ava solution and Ava hydrogel medication, could greatly attenuate the alkali burn-induced corneal inflammation and remarkably suppress the corneal neovascularization via the downregulation of VEGF, CD31, and α-SMA expression in the rat alkali burn model. As a result, the combined Dexp and Ava by supramolecular hydrogel exhibited an advantage over Ava monotherapy approach, which might be a promising alternative therapy for inflammatory CNV.

Injectable, degradable, electroactive nanocomposite hydrogels containing conductive polymer nanoparticles for biomedical applications.

Injectable electroactive hydrogels (eGels) are promising in regenerative medicine and drug delivery, however, it is still a challenge to obtain such hydrogels simultaneously possessing other properties including uniform structure, degradability, robustness, and biocompatibility. An emerging strategy to endow hydrogels with desirable properties is to incorporate functional nanoparticles in their network. Herein, we report the synthesis and characterization of an injectable hydrogel based on oxidized alginate (OA) crosslinking gelatin reinforced by electroactive tetraaniline-graft-OA nanoparticles (nEOAs), where nEOAs are expected to impart electroactivity besides reinforcement without significantly degrading the other properties of hydrogels. Assays of transmission electron microscopy, (1)H nuclear magnetic resonance, and dynamic light scattering reveal that EOA can spontaneously and quickly self-assemble into robust nanoparticles in water, and this nanoparticle structure can be kept at pH 3~9. Measurement of the gel time by rheometer and the stir bar method confirms the formation of the eGels, and their gel time is dependent on the weight content of nEOAs. As expected, adding nEOAs to hydrogels does not cause the phase separation (scanning electron microscopy observation), but it improves mechanical strength up to ~8 kPa and conductivity up to ~10(-6) S/cm in our studied range. Incubating eGels in phosphate-buffered saline leads to their further swelling with an increase of water content <6% and gradual degradation. When growing mesenchymal stem cells on eGels with nEOA content ≤14%, the growth curves and morphology of cells were found to be similar to that on tissue culture plastic; when implanting these eGels on a chick chorioallantoic membrane for 1 week, mild inflammation response appeared without any other structural changes, indicating their good in vitro and in vivo biocompatibility. With injectability, uniformity, degradability, electroactivity, relative robustness, and biocompatibility, these eGels may have a huge potential as scaffolds for tissue regeneration and matrix for stimuli responsive drug release.

[Effect of stiffness of polyelectrolyte multilayer on titanium surface on bacterium adhesion].

OBJECTIVE: To provide a theoretical basis for surface modification of titanium implants, the effects of the stiffness of polyelectrolyte multilayer films on titanium surface on bacterium adhesion was explored. METHODS: Via layer-by-layer technique, catechol functionalized polyelectrolyte multilayer film (cPEM) was constructed on titanium surface by using catechol functionalized hyaluronic acid (cHA) and lipopolysaccharide-amine nanopolymersomes (NP). The stiffness of cPEM was controlled by adjusting the catechol substitution degree of cHA (5%, 10%, 20%, 30%, 40%, 50%, 60%, 70%). Titanium samples covered with cPEM were selected as test group, and the cPEM was constructed with the lowest, medium and highest stiffness. The polished titanium was used as a control. The surface topography of titanium before and after film construction was observed by scanning electron microscopy (SEM). At 1 and 24 h after incubation, the adhesion and clonal formation of Streptococcus mutans (S. mutans) on different titanium surfaces were quantified, and their morphology and survival status were observed by SEM and laser scanning confocal microscope (LSCM). RESULTS: When the catechol grafting ratio was 5%, 30% and 70%, the lowest, medium and highest cPEM stiffness were obtained, and the cPEM stiffness were (10.69±4.54) GPa(cPEM-L), (20.99± 5.81) GPa (cPEM-M) and (32.57±6.93) GPa (cPEM-H) respectively, and the stiffness of polished titanium was (107.12±8.68) GPa (P<0.05). SEM observation showed that after cPEM coating, the titanium surface became smoother. After incubation for 1 and 24 h, the amount of adhesion and clonal formation of S. mutans on cPEM were higher than those on control titanium, and the difference was statistically significant (P<0.05). SEM images showed that for 1 h incubation, softer surfaces were beneficial for S. mutans adhering and agglomerating, while this difference nearly disappeared at 24 h. Observation under LSCM revealed that most of bacteria were alive on titanium disks at 1 h, and their amount decreased with the increase of stiffness. At 24 h, the living/dead bacterium ratios on cPEM-L and control titanium was higher than that on cPEM-M and cPEM-H, and cPEM-L surface was dominated by living bacteria, while stiffer cPEM-M and cPEM-H had more dead bacteria than living bacteria. CONCLUSIONS: Increasing the stiffness of polyelectrolyte films on titanium limits the adhesion of S. mutans. As an independent factor, stiffness influences the bacterium adhesion.

Safety of femtosecond laser-assisted cataract surgery: assessment of aqueous humour and lens capsule.

PURPOSE: To investigate the effect of femtosecond laser-assisted cataract surgery (FLACS) on aqueous humour and lens capsule. METHODS: This prospective randomized comparative study enrolled 19 eyes that underwent FLACS as the trial group and 20 eyes that underwent conventional phacoemulsification as the control group. The femtosecond laser platform (LLS-fs 3D; LensAR, Orlando, FL, USA) was used to generate capsulotomy (laser energy 8 µJ) and lens fragmentation (laser energy 10 µJ). Morphology of the cutting edge and cells of anterior capsule was assessed by light microscopy. The proteins in the aqueous humour were identified by mass spectrometry (Ultraflex III TOF/TOF; Bruker Dalton, Bremen, Germany). Electrolyte in the aqueous humour was detected by a chemistry analyzer (Aeroset Clinical Chemistry Analyzer; Abbott Laboratories, Abbott Park, IL, USA). RESULTS: The cutting edge of anterior capsule was saw-tooth-shaped under magnification of 200× and 400× in the trial group, while it was smooth in the control group. Intact cells were found in the boundary area next to the cutting edge of anterior capsule in both groups. ß-Crystallin B1, γ-crystallin S and transferrin were detected in the aqueous humour in the trial group. The concentrations of K+ , Na+ and Cl- in the aqueous humour in the trial group differed significantly from those in the control group (p = 0.02, 0.03 and 0.04, respectively). CONCLUSION: Femtosecond laser-assisted cataract surgery (FLACS) causes release of transferrin and crystallin from lens to aqueous humour and results in significant changes in the concentrations of K+ , Na+ and Cl- in aqueous humour. However, these changes due to FLACS have no clinical significance or toxicity.

[Blood compatibility of block copolymer membranes of poly(benzyl L-glutamate)/poly(ethylene glycol)].

The blood compatibility of block copolymer membranes of poly(benzyl L-glutamate)/poly(ethylene glycol) and the effect of on the blood compatibility of copolymer were evaluated by the clotting time test, the platelet adhesion and deformation test, and the protein adsorption test. The results showed that in terms of blood compatibility, homopolymer was better than glass and silicone, copolymer was better than homopolymer, and the more the PEG in the copolymer, the better the blood compatibility.

[Study on gene transfection in bone marrow mesenchymal stem cells mediated by plasmid of bone morphogenetic protein 2 loaded lipopolysaccharide-amine nanopolymersomes].

OBJECTIVE: To evaluate the combination of lipopolysaccharide-amine nanopolymersomes (LNPs), as a gene vector, with target gene and the transfection in bone marrow mesenchymal stem cells (BMSCs) so as to provide a preliminary experiment basis for combination treatment of bone defect with gene therapy mediated by LNPs and stem cells. METHODS: Plasmid of bone morphogenetic protein 2 (pBMP-2)-loaded LNPs (pLNPs) were prepared. The binding ability of pLNPs to pBMP-2 was evaluated by a gel retardation experiment with different ratios of nitrogen to phosphorus elements (N/P). The morphology ofpLNPs (N/P = 60) was observed under transmission electron microscope (TEM) and atomic force microscope (AFM). The size and Zeta potential were measured by dynamic light scattering (DLS). The resistance of pLNPs against DNase I degradation over time was explored. The viability of BMSCs, transfection efficiency, and expression of target protein were investigated after transfection by pLNPs in vitro. RESULTS: At N/P ≥ 1.5, pLNPs could completely retard pBMP-2; at N/P of 60, pLNPs was uniform vesicular shape under AFM; TEM observation demonstrated that pLNPs were spherical nano-vesicles with the diameter of (72.07 ± 11.03) nm, DLS observation showed that the size of pLNPs was (123 ± 6) nm and Zeta potential was 20 mV; pLNPs could completely resist DNase I degradation within 4 hours, and such protection capacity to pBMP-2 decreased slightly at 6 hours. The cell survival rate first increased and then decreased with the increase of N/P, and reached the maximum value at N/P of 45; the cytotoxicity was in grade I at N/P ≤ 90, which meant no toxicity for in vivo experiment. While the transfection efficiency of pLNPs increased with the increase of N/P, and reached the maximum value at N/P of 60. So it is comprehensively determined that the best N/P was 60. At 4 days, transfected BMSCs expressed BMP-2 continuously at a relatively high level at N/P of 60. CONCLUSION: LNPs can compress pBMP-2 effectively to form the nanovesicles complex, which protects the target gene against enzymolysis. LNPs has higher transfection efficiency and produces more amount of protein than polyethylenimine 25k and Lipofectamine 2000.

[Angiogenic activity of alginate-graft-PEI/pVEGF complexes in vivo].

To study the angiogenic activity of amphoteric brush-type copolymer complex of alginate-graft-PEI/pVEGF (Alg-g-PEI/pVEGF) in vivo, we evaluated the toxicity of Alg-g-PEI/pVEGF complexes to rMSCs and zebra fish first. Then, we used gel retardation assay to investigate the protection of complex to pDNA against DNase I, serum and heparin. For in vivo study, we evaluated the angiogenic activity of Alg-g-PEI/pVEGF complexes by using CAM and zebra fish as animal models, PEI 25K/pVEGF and saline as positive and negative controls. Our results show that Alg-g-PEI protected pVEGF from enzymolysis and displacement of heparin in some degree, and its complexes with pVEGF were less toxic to rMSCs and zebra fish. Alg-g-PEI/pVEGF complexes induced significant angiogenesis, which was dosage-dependent. In CAM, when the dosage of pVEGF was 2.4 microg/CAM, Alg-g-PEI group achieved the maximum of angiogenesis, and the area ratio of vessel to the total surface was 44.04%, which is higher than PEI 25K group (35.90%) and saline group (24.03%) (**P < 0.01). In zebra fish, the angiogenesis increased with the increase of N/P ratios of Alg-g-PEI/pVEGF complexes in our studied range; when N/P ratio was 110, the optimal angiogenesis was obtained with vessel length of 1.11 mm and area of 1.70 x 10(3) pixels, which is higher than saline group (0.69 mm and 0.94 x 10(3) pixels) (**P < 0.01) and PEI 25k group (0.82 mm and 1.11 x 10(3) pixels) (**P < 0.01). Our results demonstratethat Alg-g-PEI/pVEGF significantly induces angiogenesis in CAM and zebra fish, and has a great potential in therapeutic angiogenesis.

Alginate-graft-PEI as a gene delivery vector with high efficiency and low cytotoxicity.

To overcome the efficiency-cytotoxicity dilemma of native PEI and incorporate the advantages of alginate, we designed a novel gene vector by grafting PEI 2000 onto alginate, an anionic polysaccharide with excellent biocompatibility. The alginate-graft-PEI (Alg-g-PEI) was successfully synthesized and then characterized by elemental analysis, (1)H-NMR and (13)C-NMR. The M(w) of Alg-g-PEI is ca. 17 000. Acid-base titration confirmed that Alg-g-PEI retained the buffering capacity of native PEI. The DNA binding ability of the polymer was confirmed by gel retardation assay. DSL analysis showed that Alg-g-PEI had a particle size and zeta-potential similar to PEI 25K. AFM detected a clear and well-shaped morphology of the complexes. Additionally, Alg-g-PEI exhibited lower cytotoxicity than PEI 25K in BEL7402, MSC and RVMSC cells. Compared with PEI 25K, Alg-g-PEI had comparable or even higher transfection efficiency. Similarly, Alg-g-PEI-mediated VEGF expression was significantly higher compared with PEI 25K-mediated VEGF expression. All together, our results suggest that Alg-g-PEI has a potential to be a safe and efficient agent for gene therapy.

[Immobilization and characterization of carbonic anhydrase on the surface of hollow fiber membrane of polymethyl pentene].

We immobilized carbonic anhydrase (CA) onto the surface of membrane oxygenator of polymethyl pentene (PMP) to enhance the removal of carbon dioxide in blood by two steps. We first introduced hydroxyl groups onto PMP surface by water plasma treatment, and then coupled CA onto PMP surface by using cyanate bromide (CNBr) as a crosslinker. After plasma treatment, the contact angle with water and chemical composition of PMP surface were characterized by analysis system of surface contact angle and XPS. Using p-nitrophenyl acetate (p-NPA) as a substrate, the activity, concentration, storage stability and re-usability of immobilized CA on PMP hollow fibers were studied by ultraviolet spectrophotometer. The preliminary data showed that hydroxyl groups could be introduced on the surface of PMP by water plasma treatment, and CA with catalysis activity could be successfully introduced onto PMP surface in high immobilization efficiency. The activity of covalently immobilized CA increased with the increase of concentration of CNBr, and the maximum was 73% of the theoretical activity of CA spread on PMP surface in monolayer in studied range. Covalently immobilized CA showed higher reusability compared to physically adsorbed CA, and higher storage stability compared to free CA in solution at 37 degrees C. The method would be used potentially in the membrane oxygenator to improve the capacity of removal of carbon dioxide in blood in the future.