Poly(trimethylene carbonate) as an elastic biodegradable film for human embryonic stem cell-derived retinal pigment epithelial cells.

Human embryonic stem cell-derived retinal pigment epithelial (hESC-RPE) cell therapies show tremendous potential for the treatment of retinal degenerative diseases. A tissue engineering approach, where cells are delivered to the subretinal space on a biodegradable carrier as a sheet, shows great promise for these RPE cell therapies. The aim of the present study was to assess whether a flexible, elastic and biodegradable poly(trimethylene carbonate) (PTMC) film promotes the formation of functional hESC-RPE and performs better than often used biodegradable poly(d,l-lactide) (PDLLA) film. Human ESC-RPE maturation and functionality on PTMC films was assessed by cell proliferation assays, RPE-specific gene and protein expression, phagocytic activity and growth factor secretion. It is demonstrated that the mechanical properties of PTMC films have close resemblance to those of the native Bruch's membrane and support the formation hESC-RPE monolayer in serum-free culture conditions with high degree of functionality. In contrast, use of PDLLA films did not lead to the formation of confluent monolayers of hESC-RPE cells and had unsuitable mechanical properties for retinal application. In conclusion, the present study indicates that flexible and elastic biodegradable PTMC films show potential for retinal tissue engineering applications. Copyright © 2017 John Wiley & Sons, Ltd.

A new poly(1,3-trimethylene carbonate) film provides effective adhesion reduction after major abdominal surgery in a rat model.

BACKGROUND: Postoperative adhesions remain a major clinical problem after abdominal surgery. We evaluated the efficacy of a new poly(trimethylene carbonate) (PTMC) film as an antiadhesive material. In many abdominal operations, there is an increased risk of fecal contamination; the risk of (increased) infection in presence of PTMC film was studied in 2 additional animal models. METHODS: A validated rat adhesion model with peritoneal ischemic buttons was used to compare the new PTMC film with a hyaluronate carboxymethylcellulose (HA-CMC) sheet, icodextrin solution, and a control group. Primary endpoint was occurrence of adhesions at the ischemic buttons after 14 days in 44 rats (n = 11 per group). To evaluate potential risks associated with the film, both an anastomotic leakage model and a cecal ligation and puncture model were used. Kruskal-Wallis tests with subsequent Mann-Whitney tests were used to detect differences between groups. RESULTS: PTMC film showed a significant reduction in the amount of adhesions (median, 0.5 buttons) compared with control group (median, 4 buttons; P < .001) and icodextrin group (median, 4.5; P < .001). The amount of adhesions was similar to the HA-CMC group (median, 2; P = .04). The presence of the film did not increase the risk of anastomotic leakage or bacterial growth in a contaminated environment. CONCLUSION: The presence of a PTMC film leads to a significant reduction in the amount of adhesions after 14 days in an ischemic button rat model. Furthermore, this film was found to be safe in an animal model, even in complex abdominal operations with an increased risk of fecal contamination.

Use of non-porous pillar array columns for the separation of Pseudomonas pyoverdine siderophores as an example of a real-world biological sample.

We report on the first separation of a complex biomixture in pressure-driven mode using perfectly ordered pillar array columns. The separations were conducted in the reversed-phase mode using a highly aqueous mobile phase, while the outer surface of the non-porous pillars was chemically functionalized with a hydrophobic C8-layer. The samples originated from two different bacterial strains (Pseudomonas aeruginosa PAO1 and Pseudomonas sp. W15Feb38) of fluorescent pseudomonads. These produce fluorescent yellow-green pyoverdines that serve as siderophores to shuttle iron inside the cell. The pyoverdines of both strains were prepared from the supernatant through a crude solid phase extraction without any further purification step. In case of the PAO1 mixture, a separation of 15 components within a column length of 2.5 cm could be observed through the transparent cover glass of the chip. For the W15Feb38 mixture, a separation of eight components could be observed within the same distance. These fast chromatographic separations were compared with those obtained via iso-electrofocusing (IEF), which is the traditionally employed fingerprinting method to characterize pseudomonad strains based on their pyoverdine profiles (siderotyping). With this technique, and despite the injection of a 10,000 times larger sample mass, only nine bands were maximally observed for the PAO1 mixture, whereas maximally six bands were observed in case of the W15Feb38 mixture. The chromatographic pillar array method, yielding a separation in less than 1 min, was also significantly faster than the IEF method, which typically needs 1.5h. The present system can therefore be considered as a potential alternative fingerprinting tool for the fast identification of different strains of fluorescent pseudomonads, including as diagnostic tool for typing strains of the important opportunistic pathogen P. aeruginosa.

Experimental investigation of the band broadening arising from short-range interchannel heterogeneities in chromatographic beds under the condition of identical external porosity.

The interesting possibilities offered by micropillar array columns to investigate the relation between bed heterogeneity and band broadening in chromatographic columns are illustrated and investigated. The perfect control over the microscopic bed structure offered by the photolithographic fabrication technique could be used to produce a heterogeneous bed displaying a short-range interchannel heterogeneity and having exactly the same particle size and external porosity as the perfectly ordered bed that was used as the reference system. According to this approach, any observed difference in band broadening could be directly owed to the effect of the bed heterogeneity. Knowing that the only difference between the investigated beds was their degree of heterogeneity, the obtained plate height measurements provided a unique test to distinguish among the abilities to recognize short-range interchannel heterogeneity of the different existing plate height models. Interpreting the data with the classical van Deemter and Knox models, it was found that the increased bed heterogeneity leads not only to an increase in the A-term constant but also to a clear increase in the C-term constant.

Integration of porous layers in ordered pillar arrays for liquid chromatography.

The present paper describes a method for the production of partly porous micro-pillars in columns suitable for use in liquid chromatography. These layers increase the available surface at least two orders of magnitude without destroying the huge benefits of the ordered nature of the system. A process flow was developed that enabled us to create a 550 nm thick porous layer on the pillar array in a sealed channel configuration, withstanding pressures up to at least 70 bar. Measuring band broadening under non-retained conditions, only a modest increase in plate height was observed in the porous pillar array as compared to that in a non-porous pillar array. The homogeneity of the layers was demonstrated using an optical microscope and SEM pictures and by monitoring peak velocities at constant pressures. The internal porosity was determined using particles with a diameter larger than the mesopores in combination with a dye that could penetrate into the pores.