Methods of three-dimensional printing for fabricating a dental appliance

What is claimed is: 1. A method of fabricating at least one prosthetic denture base using a light-based three-dimensional printing apparatus, comprising the steps of: (a) preparing, in computer-aided design software, a virtual reference model of a prosthetic denture base, wherein the process of preparing a virtual reference model of a prosthetic denture base comprises the steps of: i. selecting a three-dimensional digital model of a prosthetic denture base, the three-dimensional digital model of a prosthetic denture base comprising a teeth-pockets facing side, a tissue facing side on the opposing side of the teeth-pockets facing side, and a denture border extending around the peripheral edge of the prosthetic denture base, forming a boundary between the teeth-pockets facing side and tissue facing side; ii. manipulating spatial orientation of the three-dimensional digital model of a prosthetic denture base to place the prosthetic denture base in a substantially horizontal position, wherein the teeth-pockets facing side is disposed either in an upward facing orientation or a downward facing orientation; iii. applying a minimum bounding box encompassing the three-dimensional digital model of a prosthetic denture base; iv. assigning a reference three-dimensional Cartesian coordinate (x-y-z) system to the three-dimensional digital model of a prosthetic denture base within the minimum bounding box, wherein the reference three-dimensional Cartesian coordinate system is aligned with the perimeter of the minimum bounding box, and further wherein an orienting reference plane is aligned with the base edge of the minimum bounding box; and v. removing the minimum bounding box; (b) preparing, in software of a computer system in operative control of a light-based three-dimensional printing apparatus, the virtual reference model and a three-dimensional digital model of at least one removable support structure for printing, wherein the process of preparing the virtual reference model and three-dimensional digital model of at least one removable support structure for printing comprises the steps of: i. positioning the virtual reference model adjacent to a virtual build platform surface provided by the software, wherein the tissue facing side of the virtual reference model is placed proximal to the virtual build platform surface; ii. manipulating spatial orientation of the virtual reference model, wherein the orienting reference plane of the virtual reference model is arranged at an inclination angle between about 65 degrees to about 80 degrees relative to the virtual build platform surface, with anterior teeth-pockets proximal to the virtual build platform surface and posterior teeth-pockets distal to the virtual build platform surface; and iii. generating a three-dimensional digital model of at least one removable support structure, connecting the virtual reference model to the virtual build platform surface; (c) providing a reservoir of liquid photopolymerizable composition in contact with a build platform surface of the light-based three-dimensional printing apparatus; (d) selecting, in software of the computer system in operative control of the light-based three-dimensional printing apparatus, printing process parameters to effectively photocure the liquid photopolymerizable composition in accordance with the virtual reference model and three-dimensional digital model of at least one removable support structure; and (e) instructing the light-based three-dimensional printing apparatus to print at least one prosthetic denture base and removable support structure from the liquid photopolymerizable composition. 2. The method of claim 1 , wherein the process of generating a three-dimensional digital model of at least one removable support structure comprises the steps of: (a) setting removable support structure contact points on areas of the teeth-pockets facing side and denture border of the virtual reference model; and (b) excluding, or substantially excluding, removable support structure contact points from areas on the tissue facing side and within teeth-pockets of the virtual reference model. 3. The method of claim 1 , further comprising the step of removing the at least one printed removable support structure from the build platform surface and the at least one printed prosthetic denture base following completion of printing. 4. The method of claim 3 , further comprising the step of performing a post-printing wash treatment on the at least one printed prosthetic denture base using a solvent composition comprising a C 1 -C 3 alcohol for a period of between about 1 minute to about 10 minutes. 5. The method of claim 4 , further comprising the step of performing a secondary curing treatment on the at least one printed prosthetic denture base, wherein the printed prosthetic denture base is exposed to broad-spectrum electromagnetic radiation across wavelengths from about 10 −8 m to 10 −3 m for between about 5 minutes to about 15 minutes each on both the teeth-pockets facing side and tissue facing side. 6. The method of claim 5 , further comprising the step of performing a corrective digital scaling process on the virtual reference model to fabricate at least one prosthetic denture base, wherein performing a corrective digital scaling process on the virtual reference model comprises the steps of: (a) acquiring an accurate three-dimensional digital model of the tissue facing side of at least one printed prosthetic denture base to establish a first intaglio model image; (b) comparing, in computer-aided digital inspection software, dimensions of the first intaglio model image, relative to dimensions of a second intaglio model image, wherein the second intaglio model image comprises the three-dimensional digital model of the tissue facing side of the virtual reference model from which the at least one printed prosthetic denture base is fabricated; (c) performing, in computer-aided digital inspection software, scaling factor adjustments across the x-dimension, y-dimension, and z-dimension on the first intaglio model image to establish corrective scaling factors across the x-dimension, y-dimension, and z-dimension that reduce differences of the first intaglio model image relative to the second intaglio model image; (d) generating, in computer-aided digital inspection software, a corrected prosthetic denture base digital model, wherein each of the corrective scaling factors for the x-dimension, y-dimension, and z-dimension established from performing scaling factor adjustments to the first intaglio model image are applied to corresponding dimensions of the virtual reference model; (e) preparing, in software of the computer system in operative control of the light-based three-dimensional printing apparatus, the corrected prosthetic denture base digital model and a three-dimensional digital model of at least one removable structure for printing, wherein the process of preparing the corrected prosthetic denture base digital model and three-dimensional digital model of at least one support structure for printing comprises the steps of: i. positioning the corrected prosthetic denture base digital model adjacent to the virtual build platform surface provided by the software, wherein the tissue facing side of the corrected prosthetic denture base digital model is placed proximal to the virtual build platform surface; ii. manipulating spatial orientation of the corrected prosthetic denture base digital model, wherein the orienting reference plane of the corrected prosthetic denture base digital model is arranged at an inclination angle between about 65 degrees to about 80 degrees relative to the virtual build platform surface, with anterior teeth-pockets proximal to the virtual build platform surface and posterior tee