Anti-Skiving Guide Tube And Surgical System Including The Same

What is claimed is: 1 . A surgical system to facilitate a spinal procedure on a vertebral body, the surgical system comprising: a robotic manipulator comprising an arm and a tool holder coupled to the arm, wherein the tool holder defines a tool holder channel extending along a tool holder axis, and wherein the tool holder channel has a tool holder diameter; and a guide tube configured to slide into the tool holder channel and comprising: a body extending along a body axis and defining a body channel that is configured to receive a surgical tool, wherein the body has a proximal portion defining the body channel and having an outer proximal portion diameter that is less than or equal to the tool holder diameter such that the proximal portion is slidable into the tool holder channel to align the body with the tool holder, and wherein the body has a distal portion extending from the proximal portion along the body axis and further defining the body channel, wherein the distal portion comprises a side surface disposed about the body axis, and wherein the side surface comprises abrasive features extending away from the body axis and configured to engage a surface of the vertebral body to minimize skiving. 2 . The surgical system of claim 1 , wherein the robotic manipulator is configured to align the tool holder such that the tool holder axis is aligned with a target axis defined relative to the vertebral body, and wherein the body axis of the guide tube is aligned with the target axis when the guide tube is inserted into the tool holder channel. 3 . The surgical system of claim 1 , wherein the guide tube is configured to be passively supported by the tool holder. 4 . The surgical system of claim 3 , wherein the guide tube is freely slidable along the tool holder axis. 5 . The surgical system of claim 1 , wherein the proximal portion has a proximal flange having a flange outer diameter greater than the tool holder diameter, and wherein the proximal flange is configured to be placed above an upper surface of the tool holder. 6 . The surgical system of claim 1 , wherein the abrasive features of the side surface are further defined as a plurality of protrusions. 7 . The surgical system of claim 6 , wherein at least a portion of the plurality of protrusions are oriented to face downward with respect to the body axis toward a distal end of the distal portion. 8 . The surgical system of claim 1 , wherein the distal portion includes a bulbous portion, and wherein the bulbous portion comprises the side surface. 9 . The surgical system of claim 1 , wherein the guide tube is configured to mechanically couple to the tool holder. 10 . A guide tube of a surgical system, the surgical system being configured to facilitate spinal procedure on a vertebral body and the surgical system including a robotic manipulator including an arm and a tool holder coupled to the arm, the tool holder defining a tool holder channel extending along a tool holder axis, and the tool holder channel having a tool holder diameter, the guide tube comprising: a body extending along a body axis and defining a body channel that is configured to receive a surgical tool, wherein the body has a proximal portion defining the body channel and having an outer proximal portion diameter that is configured to be less than or equal to the tool holder diameter such that the proximal portion is configured to be slidable into the tool holder channel to align the body with the tool holder, and wherein the body has a distal portion extending from the proximal portion along the body axis and further defining the body channel; wherein the distal portion comprises a side surface disposed about the body axis, and wherein the side surface comprises abrasive features extending away from the body axis and configured to engage a surface of the vertebral body to minimize skiving. 11 . The guide tube of claim 10 , wherein the abrasive features of the side surface are disposed 360 degrees about the body axis. 12 . The guide tube of claim 10 , wherein the abrasive features of the side surface are further defined as a plurality of protrusions, and wherein at least a portion of the plurality of protrusions are oriented to face downward with respect to the body axis toward a distal end of the distal portion. 13 . The guide tube of claim 12 , wherein each protrusion of the plurality of protrusions is of the same geometry. 14 . The guide tube of claim 12 , wherein the protrusions of the plurality of protrusions have varying geometries. 15 . The guide tube of claim 12 , wherein a geometry of at least one protrusion is a prism. 16 . The guide tube of claim 12 , wherein a geometry of at least one protrusion is a cone. 17 . The guide tube of claim 12 , wherein a geometry of at least one protrusion is a prong. 18 . The guide tube of claim 12 , wherein each protrusion has a protrusion base and a protrusion tip extending from the protrusion base away from the body axis. 19 . The guide tube of claim 12 , wherein the plurality of protrusions has a helical configuration with respect to the body axis. 20 . The guide tube of claim 12 , wherein the plurality of protrusions comprises layers of flanges disposed annularly about the body axis. 21 . The guide tube of claim 20 , wherein each flange of the layers of flanges comprises a first flange surface extending away from the body axis and a second flange surface extending away from the body axis, and wherein the first and second flange surfaces terminate at a flange edge that is configured to engage the vertebral body to minimize skiving. 22 . The guide tube of claim 21 , wherein the first flange surface is obliquely oriented with respect to the body axis. 23 . The guide tube of claim 10 , wherein the proximal portion has a proximal flange having a flange outer diameter configured to be greater than the tool holder diameter such that the proximal flange is configured to be placed above an upper surface of the tool holder, wherein the distal portion has a distal outer diameter that is less than the flange outer diameter. 24 . The guide tube of claim 10 , wherein the distal portion includes a bulbous portion, and wherein the bulbous portion comprises the side surface. 25 . A method of operating a surgical system to facilitate spinal procedure on a vertebral body, the surgical system including a robotic manipulator comprising an arm and a tool holder coupled to the arm, wherein the tool holder defines a tool holder channel extending along a tool holder axis and the tool holder channel defining a tool holder diameter; a guide tube including a body extending along a body axis and defining a body channel that is configured to receive a surgical tool, wherein the body has a proximal portion defining the body channel and having an outer proximal portion diameter that is less than or equal to the tool holder diameter, and the body has a distal portion extending from the proximal portion along the body axis and further defining the body channel, and wherein the distal portion of the body comprises a side surface disposed about the body axis and comprising abrasive features extending away from the body axis, the method comprising the steps of: controlling the robotic manipulator to align the tool holder such that the tool holder axis is aligned with a target axis defined relative to the vertebral body; inserting the guide tube in th