To more effectively manage the substantial bleeding encountered during surgical procedures in oto-rhino-laryngology, we developed a novel hemostatic sponge made of pharmaceutical grade, chemically cross-linked gelatin. The sponge is characterized by a high pore density, reduced ligaments, and a high nanoscale roughness of lamella surfaces in the matrix. In vitro blood uptake assays revealed a very rapid absorption of human blood, which was two to three times faster than that measured with comparative hemostyptic devices. In an in vitro hemorrhage model using human veins, the novel gelatin sponge matrix induced hemostasis less than a minute after bleeding was induced. The sponge was shown to bring about rapid hemostasis when it was administered in a young patient suffering from acute bleeding of a pharyngeal angiofibroma, even though the patient had been treated with an anticoagulant because of a transient ischemic attack. As the gelatin matrix of the sponge is biocompatible and resorbable, the hemostyptic device could be left in place and was shown to be resorbed within 2 weeks. We hypothesize that the excellent hemostatic performance of the sponge might be linked to enhanced capillary effects in conjunction with optimized anchoring of fibrinogen on the nano-rough material surface, as suggested by scanning electron microscopy. The novel gelatin sponge appears to be a promising hemostatic matrix, which could be of great benefit for patients suffering from epistaxis and other acute injuries resulting in severe bleeding.
The permeability characteristics of biomaterials are critical parameters for a variety of implants. To analyse the permeability of membranes made from crosslinked ultrathin gelatin membranes and the transmigration of cells across the membranes, we combined three technical approaches: (1) a two-chamber-based permeability assay, (2) cell culturing with cytochemical analysis and (3) biochemical enzyme electrophoresis (zymography). Based on the diffusion of a coloured marker molecule in conjunction with photometric quantification, permeability data for a gelatin membrane were determined in the presence or absence of gelatin degrading fibroblasts. Cytochemical evaluation after cryosectioning of the membranes was used to ascertain whether fibroblasts had infiltrated the membrane inside. Zymography was used to investigate the potential release of proteases from fibroblasts, which are known to degrade collagen derivatives such as gelatin. Our data show that the diffusion equilibrium of a low molecular weight dye across the selected gelatin membrane is approached after about 6-8 h. Fibroblasts increase the permeability due to cavity formation in the membrane inside without penetrating the membrane for an extended time period (>21 days in vitro). Zymography indicates that cavity formation is most likely due to the secretion of matrix metalloproteinases. In summary, the combination of the depicted methods promises to facilitate a more rational development of biomaterials, because it provides a rapid means of determining permeability characteristics and bridges the gap between descriptive methodology and the mechanistic understanding of permeability alterations due to biological degradation.
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