Your search keyword '"Daamen WF"' showing total 5 results

1. Seamless vascularized large-diameter tubular collagen scaffolds reinforced with polymer knittings for esophageal regenerative medicine.

Author

Hoogenkamp HR, Koens MJ, Geutjes PJ, Ainoedhofer H, Wanten G, Tiemessen DM, Hilborn J, Gupta B, Feitz WF, Daamen WF, Saxena AK, Oosterwijk E, and van Kuppevelt TH

Subjects

Animals, Cattle, Esophagus drug effects, Omentum drug effects, Omentum physiology, Prosthesis Implantation, Sheep, Collagen pharmacology, Esophagus physiology, Neovascularization, Physiologic drug effects, Polyesters pharmacology, Regenerative Medicine methods, Tissue Scaffolds chemistry

Abstract

A clinical demand exists for alternatives to repair the esophagus in case of congenital defects, cancer, or trauma. A seamless biocompatible off-the-shelf large-diameter tubular scaffold, which is accessible for vascularization, could set the stage for regenerative medicine of the esophagus. The use of seamless scaffolds eliminates the error-prone tubularization step, which is necessary when emanating from flat scaffolds. In this study, we developed and characterized three different types of seamless tubular scaffolds, and evaluated in vivo tissue compatibility, including vascularization by omental wrapping. Scaffolds (luminal Ø ∼ 1.5 cm) were constructed using freezing, lyophilizing, and cross-linking techniques and included (1) single-layered porous collagen scaffold, (2) dual-layered (porous+dense) collagen scaffold, and (3) hybrid scaffold (collagen+incorporated polycaprolacton knitting). The latter had an ultimate tensile strength comparable to a porcine esophagus. To induce rapid vascularization, scaffolds were implanted in the omentum of sheep using a wrapping technique. After 6 weeks of biocompatibility, vascularization, calcification, and hypoxia were evaluated using immunohistochemistry. Scaffolds were biocompatible, and cellular influx and ingrowth of blood vessels were observed throughout the whole scaffold. No calcification was observed, and slight hypoxic conditions were detected only in the direct vicinity of the polymer knitting. It is concluded that seamless large-diameter tubular collagen-based scaffolds can be constructed and vascularized in vivo. Such scaffolds provide novel tools for esophageal reconstruction.

Published

2014

2. Improving the cell distribution in collagen-coated poly-caprolactone knittings.

Author

Sun W, Tiemessen DM, Sloff M, Lammers RJ, de Mulder EL, Hilborn J, Gupta B, Feitz WF, Daamen WF, van Kuppevelt TH, Geutjes PJ, and Oosterwijk E

Subjects

Animals, Cattle, Collagen ultrastructure, Fluorescent Antibody Technique, Humans, Microspheres, Myocytes, Smooth Muscle metabolism, Tensile Strength drug effects, Tissue Engineering, Tissue Scaffolds chemistry, Coated Materials, Biocompatible pharmacology, Collagen pharmacology, Myocytes, Smooth Muscle cytology, Myocytes, Smooth Muscle drug effects, Polyesters pharmacology

Abstract

Adequate cellular in-growth into biomaterials is one of the fundamental requirements of scaffolds used in regenerative medicine. Type I collagen is the most commonly used material for soft tissue engineering, because it is nonimmunogenic and a highly porous network for cellular support can be produced. However, in general, adequate cell in-growth and cell seeding has been suboptimal. In this study we prepared collagen scaffolds of different collagen densities and investigated the cellular distribution. We also prepared a hybrid polymer-collagen scaffold to achieve an optimal cellular distribution as well as sufficient mechanical strength. Collagen scaffolds [ranging from 0.3% to 0.8% (w/v)] with and without a mechanically stable polymer knitting [poly-caprolactone (PCL)] were prepared. The porous structure of collagen scaffolds was characterized using scanning electron microscopy and hematoxylin-eosin staining. The mechanical strength of hybrid scaffolds (collagen with or without PCL) was determined using tensile strength analysis. Cellular in-growth and interconnectivity were evaluated using fluorescent bead distribution and human bladder smooth muscle cells and human urothelium seeding. The lower density collagen scaffolds showed remarkably deeper cellular penetration and by combining it with PCL knitting the tensile strength was enhanced. This study indicated that a hybrid scaffold prepared from 0.4% collagen strengthened with knitting achieved the best cellular distribution.

Published

2012

3. A comparison of seven methods to analyze heparin in biomaterials: quantification, location, and anticoagulant activity.

Author

Lammers G, van de Westerlo EM, Versteeg EM, van Kuppevelt TH, and Daamen WF

Subjects

Blood Coagulation Tests, Reproducibility of Results, Sensitivity and Specificity, Anticoagulants analysis, Anticoagulants chemistry, Biocompatible Materials analysis, Biocompatible Materials chemistry, Biological Assay methods, Heparin analysis, Heparin chemistry

Abstract

Glycosaminoglycans, like heparin, are frequently incorporated in biomaterials because of their capacity to bind and store growth factors and because of their hydrating properties. Heparin is also often used in biomaterials for its anticoagulant activity. Analysis of biomaterial-bound heparin is challenging because most assays are based on heparin in solution. In this study, seven different methods were probed to analyze heparin covalently attached to collagen scaffolds. For each method, the basic mechanism and the advantages and disadvantages are given. An analysis by the factor Xa assay and the Farndale assay clearly indicated that the amount of immobilized heparin cannot be determined correctly when the scaffold is intact. Scaffolds had to be proteolytically digested or acid treated to obtain reliable measurements. Methods used to quantify the amount of bound heparin included a hexosamine assay, an uronic acid assay, a Farndale assay, agarose gel electrophoresis, and immuno-dot blot analysis. Location and semiquantification of heparin were accomplished by immunofluorescence. Although all assays had their advantages and disadvantages, the hexosamine assay turned out to be the most robust and is recommended as the preferred assay to quantify the amount of heparin bound to scaffolds. It is applicable to all scaffolds that are acid hydrolyzable. This study may allow researchers in the field to select the most appropriate method to analyze glycosaminoglycans in biomaterials.

Published

2011

4. Organ-specific tubular and collagen-based composite scaffolds.

Author

Koens MJ, Geutjes PJ, Faraj KA, Hilborn J, Daamen WF, and van Kuppevelt TH

Subjects

Animals, Cattle, Horses, Immunohistochemistry, Microscopy, Electron, Scanning, Polymers chemistry, Sus scrofa, Sutures, Collagen chemistry, Organ Specificity, Tissue Scaffolds chemistry

Abstract

The body contains a number of organs characterized by a tubular shape. In this study, we explored several methodologies for the construction of collagenous tubular scaffolds and films with defined (ultra)structure, length, diameter, orientation, and molecular composition. Standardization of molding, casting, freezing, and lyophilizing techniques using inexpensive materials and methods resulted in controllable fabrication of a wide variety of tubular and tissue-specific tubular scaffolds and films. Analysis included immunohistochemical and (ultra)structural examination. Handling and suturability were found adequate for tissue engineering applications.

Published

2011

5. Micro-computed tomographical imaging of soft biological materials using contrast techniques.

Author

Faraj KA, Cuijpers VM, Wismans RG, Walboomers XF, Jansen JA, van Kuppevelt TH, and Daamen WF

Subjects

Biocompatible Materials analysis, Biomimetic Materials analysis, Contrast Media, Materials Testing methods, Biocompatible Materials chemistry, Biomimetic Materials chemistry, Extracellular Matrix diagnostic imaging, Radiographic Image Enhancement methods, Refractometry methods, Tomography, X-Ray Computed methods

Abstract

The aim of this work was to introduce high-resolution computed tomography (micro-CT) for scaffolds made from soft natural biomaterials, and to compare these data with the conventional techniques scanning electron microscopy and light microscopy. Collagen-based scaffolds were used as examples. Unlike mineralized tissues, collagen scaffolds do not provide enough X-ray attenuation for micro-CT imaging. Therefore, various metal-based contrast agents were applied and evaluated using two structurally distinct scaffolds, one with round pores and one with unidirectional lamellae. The optimal contrast techniques for obtaining high-resolution three-dimensional images were either a combination of osmium tetroxide and uranyl acetate, or a combination of uranyl acetate and lead citrate. The data obtained by micro-CT analysis were in line with data obtained by light and electron microscopy. However, small structures (less than a few mum) could not be visualized due to limitation of the spot size of the micro-CT apparatus. In conclusion, reliable three-dimensional images of scaffolds prepared from soft natural biomaterials can be obtained using appropriate contrast protocols. This extends the use of micro-CT analysis to soft materials, such as protein-based biomaterials.

Published

2009