Multilayer device for tissue engineering
First Claim
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1. A multilayer device for use in tissue engineering, comprising:
- (a) at least a first layer comprised of a polymer scaffold having a pattern of microchannels therein and(i) wherein the microchannels are suitable for the attachment and culturing of animal cells within the microchannels, and(ii) wherein the microchannels are connected for the circulation of fluid through the first layer, and(b) at least a second layer comprised of a polymer scaffold,wherein the first and second layers are joined or fastened together and the first layer is formed by forming a mold from a substrate material using a photoresist processing technique that includes;
i) coating the substrate material with a photoresist; and
ii) forming a pattern in the photoresist, and casting the first layer on the respective mold.
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Abstract
The invention provides for translating two-dimensional microfabrication technology into the third dimension. Two-dimensional templates are fabricated using high-resolution molding processes. These templates are then bonded to form three-dimensional scaffold structures with closed lumens. The scaffolds can serve as the template for cell adhesion and growth by cells that are added to the scaffolds through the vessels, holes or pores. These scaffolds can be formed by layering techniques, to interconnect flat template sheets to build up a fully vascularized organ.
119 Citations
50 Claims
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1. A multilayer device for use in tissue engineering, comprising:
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(a) at least a first layer comprised of a polymer scaffold having a pattern of microchannels therein and (i) wherein the microchannels are suitable for the attachment and culturing of animal cells within the microchannels, and (ii) wherein the microchannels are connected for the circulation of fluid through the first layer, and (b) at least a second layer comprised of a polymer scaffold, wherein the first and second layers are joined or fastened together and the first layer is formed by forming a mold from a substrate material using a photoresist processing technique that includes;
i) coating the substrate material with a photoresist; and
ii) forming a pattern in the photoresist, and casting the first layer on the respective mold.- View Dependent Claims (2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12, 13, 14, 15, 16, 17, 18, 19, 20, 21, 22, 23, 24, 25, 26, 27, 28, 29, 30, 31, 32, 33)
(b) wherein the third layer has a pattern of channels therein, (i) wherein the channels are suitable for the attachment and culturing of animal cells within the channels, and (ii) wherein the channels are connected for the circulation of fluid through the layer.
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13. The multilayer device of claim 12, wherein the pattern in the first and third layers are similar.
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14. The multilayer device of claim 12, wherein the pattern in the first and third layers are different.
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15. The multilayer device of claim 14, wherein the pattern in the first layer is suitable for the culturing of endothelial cells and the layer in the third layer is suitable for the culturing of parenchymal cells.
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16. The multilayer device of claim 1, wherein the animal cells are selected from the group consisting of endothelial cells, parenchymal cells, bone marrow cells, osteoblasts, mesenchymal stem cells, satellite cells, and fibroblasts.
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17. The multilayer device of claim 1, wherein the cells cultured in the channels of the first layer are endothelial cells.
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18. The multilayer device of claim 1, wherein one or more of the layers comprise through-holes.
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19. The multilayer device of claim 1, wherein one or more of the layers comprise an alignment indentation on the surface of a layer and an alignment protrusion on an opposing surface of a layer, the alignment indentations shaped to mate with the alignment protrusion.
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20. The multilayer device of claim 1, wherein the first layer is subdivided into zones of animal cell support.
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21. The multilayer device of claim 20, wherein the zones of animal cell support comprise cell adhesion molecules.
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22. The multilayer device of claim 7 or 15, wherein the pattern in the first layer comprises microchannels that are about 30-200 microns in width.
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23. The multilayer device of claim 1, wherein the substrate is selected from the group consisting of silicon, ceramic, and glass.
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24. The multilayer device of claim 1, wherein the second layer is formed by forming a mold from a substrate selected from the group consisting of silicon, ceramic, and glass using a photoresist processing technique, and casting the second layer on the respective mold, wherein the photoresist processing technique for the second layer includes coating the substrate with a photoresist, forming a pattern in the photoresist to form a second mold and casting the second layer on the second mold.
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25. The multilayer device of claim 24, wherein the molds for the first and second layers are the same.
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26. The multilayer device of claim 24, wherein the molds for the first and second layers are different.
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27. The multilayer device of claim 1, wherein the polymer scaffold is selected from a material consisting of a biocompatible material, a biodegradable material, a porous material, a non-porous material and combinations thereof.
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28. The multilayer device of claim 1, wherein the microchannels are a branched pattern.
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29. The multilayer device of claim 1, wherein the microchannels have a height and width of about 30-200 microns.
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30. The multilayer device of claim 1, wherein the photoresist in combination with the substrate material form the mold.
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31. The multilayer device of claim 1, wherein forming the mold includes etching the substrate.
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32. The multilayer device of claim 1, wherein forming the mold includes etching the substrate in a pattern exposed through the photoresist and stripping the photoresist therefrom.
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33. The multilayer device of claim 1, wherein the photoresist processing technique further includes the step of etching the pattern into the substrate.
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34. A multilayer device for use in tissue engineering, comprising:
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(a) at least a first layer comprised of a polymer scaffold having a pattern of microchannels therein and (i) wherein the microchannels are suitable for the attachment and culturing of animal cells within the microchannels, (ii) wherein the microchannels are connected for the circulation of fluid through the first layer, and (iii) wherein the at least a first layer is fabricated by forming a mold from a semiconductor substrate material using a photoresist processing technique that includes coating the semiconductor substrate material with a photoresist, and forming a pattern in the photoresist, and then casting the at least a first layer on the mold; and (b) at least a second layer comprised of a polymer scaffold, wherein the first and second layers are joined or fastened together.
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35. A method of making a multilayer device, comprising the steps of:
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(a) fabricating at least a first layer comprised of a polymer scaffold suitable for attachment and culturing of animal cells and having a pattern of channels therein, wherein the at least a first layer is fabricated by forming a mold from a semiconductor substrate material using a photoresist processing technique that includes coating the semiconductor substrate material with a photoresist, and forming a pattern in the photoresist, and then casting the at least a first layer on the mold, and (i) wherein the channels are suitable for the attachment and culturing of animal cells within the channels, (ii) wherein the channels are connected for the circulation of fluid through the layer, and (iii) wherein at least one of the channels is about 30-200 microns in width; (b) obtaining at least a second layer for supporting animal cell growth wherein the second layer is comprised of a polymer scaffold suitable for attachment and culturing of animal cells; and (c) fastening together the first and second layers to form lumens of the channels. - View Dependent Claims (36, 37)
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38. A method of making a multilayer device comprising the steps of:
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(a) obtaining layers of a multilayer device, comprising; (i) at least a first layer comprised of a polymer scaffold having a pattern of microchannels therein, and (A) wherein the pattern of microchannels are suitable for the attachment and culturing of animal cells within the channels, (B) wherein the pattern of microchannels are connected for the circulation of fluid through the layer; and (C) wherein the first layer is formed by forming a first mold from a substrate material using a photoresist processing technique that includes coating the substrate material with a photoresist, and forming a pattern in the photoresist, and then casting an elastomer on the mold such that the pattern in the photoresist is transferred to the elastomer which acts as a second mold for the first layer, and (ii) at least a second layer, wherein the second layer is comprised of a polymer scaffold for attachment and culturing of animal cells; and (b) fastening the at least a first layer and the at least a second layer together. - View Dependent Claims (39, 40, 41, 42, 43, 44, 45, 46)
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47. A method of implanting a bioartificial organ into a recipient, comprising:
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(a) obtaining a multilayer device, comprising; (i) at least a first layer comprised of a polymer scaffold having a pattern of microchannels therein, and (A) wherein the microchannels are suitable for the attachment and culturing of animal cells within the channels, (B) wherein the microchannels are connected for the circulation of fluid through the layer, and (C) wherein the first layer is formed by forming a mold from a semiconductor substrate material using a photoresist processing technique that includes coating the semiconductor substrate material with a light sensitive photoresist, and forming a pattern in the photoresist by exposing the photoresist to short-wavelength light through a semi-transparent mask to create a microfluidic pattern in the photoresist, and then casting the first layer on the mold, and removing the first layer from the mold; and (ii) at least a second layer wherein the second layer is comprised of a polymer scaffold, the layers of the multilayer device being fastened together; and (b) implanting the multilayer device into the recipient, wherein the implanted multilayer device is a bioartificial organ. - View Dependent Claims (48, 49, 50)
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Specification