Embodiments disclosed include systems, apparatus, and/or methods to receive a target health status of and/or quality of bioproduct produced by a managed livestock and indications of health status and quality of bioproduct. The systems, apparatus, and/or methods generate a set of input vectors based on the target health status or bioproduct quality, and the indications of bioproduct quality, and health status, and provide the set of input vectors to a machine learning model trained to generate an output indicating a feed selection. The feed selection can be included in a feed blend and administered to the managed livestock, such that, upon consumption, it increases a likelihood of collectively improving the health status of the managed livestock and the bioproduct quality of the managed livestock.

A telescoping pet ramp incudes a bottom frame that has a rectangular shape and fasteners to tether the telescoping pet ramp to an interior of a vehicle. The telescoping pet ramp includes a top frame, a platform, connectors, a ramp storage area, and a telescoping ramp. The top frame has four sides that create a rectangular shape and an opening between the four sides. The platform is attached to the top frame and covers the opening. Four or more connectors connect the top frame and the bottom frame. The ramp storage area is between the top frame and the bottom frame. The telescoping ramp is moveable with respect to a front of the top frame and a front of the bottom frame. The ramp storage area retains the telescoping ramp when the telescoping ramp is in a non-extended state.

The present disclosure provides for a securable pet door. The securable pet door may comprise at least one door, at least one knob, one or more windows, at least one frame, and/or at least one hinge. The knob may comprise a latch for secure closing. When the pet door comprises at least one hinge, the hinge(s) may be inserted into at least one hinge recess so that the door may be securely locked via at least one locking mechanism. The orientation of the one or more elements of the securable pet door may be predetermined, securable, or customizable. The door may open from, slide into, revolve within, or move in some other non-limiting equivalent way from or relative to the frame. The frame may comprise at least one sensor. When the frame comprises at least one sensor, the sensor(s) may interface with at least one external device, such as a computing device, to actuate the at least one locking mechanism from a remote location.

The present disclosure provides for a securable pet door. The securable pet door may comprise at least one door, at least one knob, one or more windows, at least one frame, and/or at least one hinge. The knob may comprise a latch for secure closing. When the pet door comprises at least one hinge, the hinge(s) may be inserted into at least one hinge recess so that the door may be securely locked via at least one locking mechanism. The orientation of the one or more elements of the securable pet door may be predetermined, securable, or customizable. The door may open from, slide into, revolve within, or move in some other non-limiting equivalent way from or relative to the frame. The frame may comprise at least one sensor. When the frame comprises at least one sensor, the sensor(s) may interface with at least one external device, such as a computing device, to actuate the at least one locking mechanism from a remote location.

A horse covering using magnetic couplers is shown and described. The horse covering includes a blanket portion, having a front end, a rear end, and two sides. A first strap is secured to the rear end of the blanket portion. The first strap includes a first part of a magnetic coupler secured to the end of the first strap opposite the connection to the blanket portion. A second end of the magnetic coupler is secured to the blanket portion. A second strap secured to the front end of the blanket portion. The second strap has a first part of a magnetic coupler secured to the end of the second strap opposite the connection to the blanket portion. A second end of the magnetic coupler is secured to the blanket portion. The horse covering further includes two front leg straps one secured to each side of the blanket portion.

An apparatus includes a housing having an aperture extending through a wall of the housing, a carbon dioxide delivery device coupled to the housing through the aperture, a non-biological skin substitute substrate, and a heater coupled to the substrate.

An animal individual identification member includes a first base brought into contact with a body of an animal, a second base including an identification portion indicating identification information of the animal by a sequence of mutually different adjacent colors, and an adhesive layer which is located between the first base and the second base and bonds the first base and the second base. The first base, the second base, and the adhesive layer have identical resin skeletons.

An animal individual identification member includes a first base brought into contact with a body of an animal, a second base including an identification portion indicating identification information of the animal by a sequence of mutually different adjacent colors, and an adhesive layer which is located between the first base and the second base and bonds the first base and the second base. The first base, the second base, and the adhesive layer have identical resin skeletons.

An electronic monitor can monitor experimental animals in a cage. The cage has one or more walls that enclose a living space for the experimental animals. The electronic monitor is coupled to the cage. The electronic monitor may include a housing adapted to be mechanically coupled to the cage in a predefined position relative to the cage. A substantially sterile barrier is provided between the living space and the external environment in this coupled state. The walls of the cage may include a signal-interface section. An electromagnetic detector may be coupled to the housing to have a line-of-sight through the signal-interface section and into the living space of the cage. The electromagnetic detector is adapted to detect electromagnetic radiation that is transmitted through the signal-interface section. A controller processes a signal received from the electromagnetic detector to determine a status of the experimental animals or the living space.

Various examples are directed to livestock management systems and methods. A first user computing device may display a GUI comprising a first animal visual element. The first animal visual element may correspond to the first animal and indicate a first colostrum feeding of the first animal. When a user selects the first animal visual element, the user computing device may display a first colostrum input screen for receiving first colostrum data. The user computing device may also modify the first animal visual element to indicate the time status of the first testing action for the first animal.