A bioassembly system having a tissue/object modeling software component fully and seamlessly integrated with a robotic bioassembly workstation component for the computer-assisted design, fabrication and assembly of biological and non-biological constructs. The robotic bioassembly workstation includes a six-axis robot providing the capability for oblique-angle printing, printing by non-sequential planar layering, and printing on print substrates having variable surface topographies, enabling fabrication of more complex bio-constructs including tissues, organs and vascular trees.

Example embodiments relate to surgical systems having end-effector assembly, first and second arm assemblies, and elbow joint assembly. End-effector assembly includes instrument assembly and wrist assembly. Instrument assembly includes a first instrument. First arm assembly includes a body, first and second instrument drive assemblies, wrist drive assembly, and first arm drive assembly. First instrument drive assembly is configurable to move first instrument relative to first axis. Wrist drive assembly is configurable to move instrument assembly relative second axis. First arm drive assembly is configurable to rotate end-effector assembly relative to third axis. Elbow joint assembly includes elbow pitch joint portion configurable to be driven to move first arm assembly relative to fourth axis. Elbow joint assembly also includes elbow sway joint portion configurable to be driven to move first arm assembly relative to fifth axis.

A hand at a robot arm leading end is provided with a mounting portion for a finger. The mounting portion includes a guiding unit that guides a supported portion of the finger so as to enable the supported portion to pass through from one end part of the guiding unit 31 to another end part thereof. The mounting portion further includes a lock mechanism. The lock mechanism moves the supported portion from any of end parts of the guiding unit 31 toward a mount position between the end parts, to thereby bring the supported portion of the finger into a restricting state at the mount position. Moreover, the lock mechanism moves the supported portion toward any of the end parts from the restricting state, to thereby bring the supported portion from the restricting state into a releasing state.

A system maintains, generates, and manages layouts that map resources to control states of a robotic apparatus. The system may receive system control queries and produce search results and contextual information in response. The system may reference the system control queries against the layouts to determine the search results and contextual information. The contextual information may include operator-interactive tools that may be used to control the robotic apparatus. To control the apparatus, the system may generate control state update messages responsive to the operator interactions. The control state update messages may be sent to a control interface of the robotic device. The robotic device may execute an action responsive the receipt of the control state update message.

The present invention relates to a surgical robot for performing surgery of the minimally invasive type, comprising an instrument manipulator having a manipulator front end, which is provided with an instrument receiver for receiving therein a surgical instrument, and manipulating means for, at least in use, manipulating the manipulator front end with respect to a patient body. The manipulator front end further comprises a container for receiving therein the surgical instrument. The invention further relates to an instrument manipulator, a combination of an operating table and a surgical robot, and a master-slave operating system.

A brick laying system where an operator such as a mason works proximate a moveable platform having a robotic arm assembly, a mortar applicator with a mortar transfer device, and a brick transfer device to build structures. The robotically assisted brick laying system may also contain a stabilizer having a disturbance sensing and a disturbance correcting component that provides compensation for disturbances caused by load shifting, movement of the platform, wind, operator movement, and the like. In addition, the robotically assisted brick laying system has a sensing and positioning component for controlling placement of the moveable platform and robotic arm assembly. The interoperability of the system with a mason or skilled operator removes much of the manual labor component of brick laying, allowing the mason more time to focus on craftsmanship and quality, thus improving the end product and the overall working conditions of the mason.

An attachment for an end effector. The attachment may include a clamp and a foot adhesively bonded to an edge of the clamp and having a set of interlocking features that form a mechanical interlock with the clamp.

A surgical system includes a robotic device, and a surgical tool coupled to the robotic device and comprising a distal end. The system further includes a neural monitor configured to generate an electrical signal and apply the electrical signal to the distal end of the surgical tool, wherein the electrical signal causes innervation of a first portion of a patient's anatomy which generates an electromyographic signal, and a sensor configured to measure the electromyographic signal. The neural monitor is configured to determine a distance between the distal end of the surgical tool and a portion of nervous tissue based on the electrical signal and the electromyographic signal, and cause feedback to be provided to a user based on the distance.

A flexible exosuit includes rigid and flexible elements configured to couple forces to a body of a wearer. Further, the flexible exosuit includes flexible linear actuators and clutched compliance elements to apply and/or modulate forces and/or compliances between segments of the body of the wearer. The flexible exosuit further includes electronic controllers, power sources and sensors. The flexible exosuit can be configured to apply forces to the body of the wearer to enable a variety of applications. In some examples, the flexible exosuit can be configured to augment the physical strength or endurance of the wearer. In some examples, the flexible exosuit can be configured to train the wearer to perform certain physical tasks. In some examples, the flexible exosuit can be configured to record physical activities of the wearer.

Disturbance compensation in computer-assisted devices include a first articulated arm configured to support an imaging device a second articulated arm configured to support an end effector, and a control unit coupled to the first articulated arm and the second articulated arm. The control unit is configured to set a first reference frame, where the first reference frame is based on a first position of the imaging device at a first time. The control unit is further configured to detect a first disturbance to the first articulated arm moving the imaging device away from the first position, receive a command to move the end effector, and transform the command to move the end effector from a command in the first reference frame to a command in a reference frame for the end effector.