A medical imaging device includes an elongated shaft having proximal and distal ends, a handle detachably connected to the shaft, and a connector assembly. The connector assembly comprises a plug at the proximal end of the shaft with an outer circumferential wall and a first plurality of electrical terminals, and a receptacle in the handle with a cavity for the plug. An image sensor is at the distal end of the shaft, and a plurality of electrical conductors electrically connected to the image sensor, are electrically connected to the first plurality of electrical terminals. An inner circumferential wall of the receptacle includes a second plurality of electrical terminals, and the outer circumferential wall of the plug has a plurality of apertures therein through which the first plurality of electrical terminals establishes an electrical connection with the second plurality of electrical terminals when the plug is inserted in the receptacle.

Several defibrillators, defibrillator architectures, defibrillator components and methods of operating defibrillators are described. In one aspect, a modular defibrillator architecture is described. A base unit provides a fully functional defibrillator. The functionality of the base unit can be supplemented by attaching an interface unit to the base unit or by connecting a smartphone the base unit. Such devices provide connectivity as well as a screen for displaying supplementary graphics and/or videos which are useful to support both emergency and maintenance & monitoring activities. In some embodiments a battery pack may also or alternatively be coupled to the base unit to prolong the unit's shelf life before recharging or replacement of its batteries is required. If necessary the base unit can be powered from a connected external device such as a mobile communication device.

Ultrasound imaging systems are provided. An ultrasound system according to some embodiments includes a console configured to selectively communicate with a first ultrasound imaging device and a second ultrasound imaging device. The console includes a housing, a computing device disposed within the housing, and a connector receptacle assembly coupled to the housing. The connector receptacle assembly includes a first connector bank including a first plurality of electrical connections; and a second connector bank including a second plurality of electrical connections. The connector receptacle assembly is selectively matable to a first connector of the first ultrasound imaging device via only the first connector bank and to a second connector of the second ultrasound imaging device via the first and second connector banks.

A multi-line electrical assembly that includes a multi-line cable (14), including a multiplicity of insulated conductive wires (59); and a multi-line electrical plug (16), physically connected to the cable. The plug has a housing (56) and a plurality of spaced-apart printed circuit hoards (PCBs, 48), housed in the housing and having a first end (47) that is connected to the cable and having a second end (46), separated from the first end. Further, the PCBs bear a plurality of conductive traces (50), at least some of the traces being electrically connected to the wires proximal to the first end. The traces terminate proximal to the second end.

Systems and methods for changing an end effector are provided. A robot flange may have a first receiver and a first electrical connection. An end effector may have a second receiver, a second electrical connection, and a locking assembly. The locking assembly may be configured to releasably secure the end effector to the robot flange. A connector may have an interface and an electrical connector for transferring at least one of power and data from the first electrical connection to the second electrical connection. The interface may be received by the first receiver and the second receiver when the connector is positioned between the robot flange and the end effector and the locking assembly secures the end effector to the robot flange.

Systems and methods for changing an end effector are provided. A connecting plate may have a first side, a second side opposite the first side, and a kinematic interface. The kinematic interface may include at least one projection extending from both the first side and the second side. A robot flange may have a first kinematic receiver including at least one recess for receiving a corresponding projection of the at least one projection of the first side. An end effector may have a second kinematic receiver and a locking assembly. The second kinematic receiver may include at least one recess for receiving a corresponding projection of the at least one projection of the second side. The locking assembly may be configured to releasably secure the end effector to the robot flange.

In various examples, a connector for an implantable medical device is configured to accept a lead therein and electrically couple to a lead contact of the lead. The connector includes a connector housing, which includes a bore portion including a bore hole therethrough. The bore hole includes a bore hole axis, the bore hole being sized and shaped to accept the lead within the bore hole. An attachment portion is coupled to the bore portion. The attachment portion includes an attachment hole within the attachment portion sized and shaped to accept a feedthrough wire within the attachment hole. The attachment hole includes an attachment hole axis offset from and non-parallel to the bore hole axis.

A plug assembly for an electromechanical surgical system includes: a housing defining a proximal facing bore; a pair of electrical contacts disposed within the housing, each electrical contact including a distal end portion projecting distally from a distal end of the housing; and a proximal end portion disposed within the proximal facing bore of the housing; a ribbon cable having a distal end portion electrically connected to the proximal end portion of each of the pair of electrical contacts, and being disposed with the proximal facing bore of the housing; and an encapsulating material filling the proximal facing bore of the housing.

An electric wire connection structure is composed of insulated electric wires each including a core and an insulation coating covering the core. The cores of the insulated electric wires are connected to pads provided on a substrate. The insulated electric wires are arranged along a predetermined alignment direction and arranged parallel to each other. The insulation coating is removed at a part in a longitudinal direction of each of the insulated electric wires to expose the core. Exposed portions of the cores are connected to the pads, respectively. Some of the insulated electric wires are configured in such a manner that the core is exposed in an area where the insulation coatings of adjacent ones of the other insulated electric wires in the alignment direction are not removed.

A base and a detection device for installing a detection apparatus are provided. The base includes a base member, a first fixing member, provided on the base member for fixing the detection apparatus, and an extension member, configured to transmit an electric signal to the detection apparatus, in which the extension member extends outward to a predetermined position of the base member. The detection device includes a detection apparatus and the base.