Medical devices and connector assemblies for connecting medical devices are disclosed. An example connector assembly for connecting a robotic arm with a medical end effector may include a plate configured to be coupled to a robotic arm. The plate may have a connection region that includes a flange defining a circumferential groove. The connector assembly may also include an attachment assembly having an attachment region configured to be detachably secured to the connection region with a securing distance of less than 12 millimeters. The attachment region may include one or more engagement members that are configured to shift between an unsecured position and a secured position where the engagement members are secured to the connection region. An actuator may be coupled to the attachment assembly for shifting the one or more engagement members between the unsecured position and the secured position.

Disclosed are bone screw drill targeting guides and methods for using such targeting guides that are useful in surgical procedures for correcting hallux valgus deformity.

Disclosed is a system to engage one or more tools. In the system, a drive shaft and collet may be assembled to engage and disengage, selectively, a plurality of tools. A guide may be used with the system to select various features of a procedure, such as depth and position.

Antifibrinolytic agents/drugs are applied to the concussive area of a patient's brain to counter the activation of a fibrinolytic process in the concussive area. Various techniques are described for administering the antifibrinolytic agent.

Antifibrinolytic agents/drugs are applied to the concussive area of a patient's brain to counter the activation of a fibrinolytic process in the concussive area. Various techniques are described for administering the antifibrinolytic agent.

An interventional tool stepper (30) employing a frame (31), a carriage (33), an optional gear assembly (32), and an optional grid template(34). The frame (31) is structurally configured to be positioned relative to an anatomical region for holding an interventional tool (40) relative to the anatomical region. The carriage (33) is structurally configured to hold the interventional tool (40) relative to the anatomical region. The gear assembly (32) is structurally configured to translate and/or rotate the carriage (33) relative to the frame (31). The grid template (34) is structurally configured to guide one or more additional interventional tools (41) relative to the anatomical region. The frame (31), the carriage (33), the optional gear assembly (32) and the optional grid template (34) have an electromagnetic-compatible material composition for minimizing any distortion by the interventional tool stepper (30) of an electromagnetic field.

An interventional tool stepper (30) employing a frame (31), a carriage (33), an optional gear assembly (32), and an optional grid template(34). The frame (31) is structurally configured to be positioned relative to an anatomical region for holding an interventional tool (40) relative to the anatomical region. The carriage (33) is structurally configured to hold the interventional tool (40) relative to the anatomical region. The gear assembly (32) is structurally configured to translate and/or rotate the carriage (33) relative to the frame (31). The grid template (34) is structurally configured to guide one or more additional interventional tools (41) relative to the anatomical region. The frame (31), the carriage (33), the optional gear assembly (32) and the optional grid template (34) have an electromagnetic-compatible material composition for minimizing any distortion by the interventional tool stepper (30) of an electromagnetic field.

The embodiments of the present invention provide a system and method for light and shadow guided needle positioning. DICOM images of a patient are captured for identifying a point of insertion of a needle on the patient's body and a target point inside the patient's body. Needle coordinates are computed based on the captured DICOM images to position the mechanical arms. Light is projected at a particular angle on the needle to form shadows of the needle. Laser light beams are projected to form cross hair at the point of insertion. Images or videos of the point of insertion, shadow of the needle and the cross hair are captured and displayed on a monitoring unit. A virtual circle is projected on the displayed image and is aligned with the point of insertion, shadow of the needle and cross hair in order to insert the needle precisely.

Provided are adjustable protective covers for automated medical devices, that protect inner and/or outer components of the medical device, while maintaining the functionality of the automated device.

Provided are adjustable protective covers for automated medical devices, that protect inner and/or outer components of the medical device, while maintaining the functionality of the automated device.