Systems, devices and methods for analyte sensor insertion

What is claimed is: 1 . An applicator assembly for inserting an in vivo glucose sensor in a subject, the applicator assembly comprising: (1) a sharp carrier subassembly, comprising: a sharp comprising a sharp hub and a sharp distal tip; a plurality of proximally-extending sharp retention arms configured to retain the sharp hub; and one or more locking nubs protruding in an outward direction away from a central longitudinal axis of the sharp carrier subassembly; (2) a sensor electronics carrier configured to retain a sensor control device, the sensor electronics carrier comprising one or more carrier nub slots, wherein the one or more locking nubs of the sharp carrier subassembly are configured to be in fitted contact with the one or more carrier nub slots of the sensor electronics carrier; (3) the sensor control device, comprising sensor electronics and the in vivo glucose sensor, the in vivo glucose sensor comprising: a proximal portion coupled with the sensor electronics; and a distal portion configured to be positioned under a skin surface of the subject and in contact with a bodily fluid of the subject; and wherein the sharp carrier subassembly, the sensor electronics carrier, and the sensor control device are configured to advance from a proximal position to a distal position, wherein the sharp carrier subassembly is configured to rotate in response to a force applied along the longitudinal axis of the sharp carrier subassembly, wherein each of the one or more locking nubs is configured to slidably advance toward an open end of a corresponding each of the one or more carrier nub slots during rotation of the sharp carrier assembly, and wherein advancement of the each of the one or more locking nubs toward the open end causes the sharp carrier subassembly to disengage from the sensor electronics carrier and retract the sharp to a retracted position. 2 . The applicator assembly of claim 1 , wherein the each of the one or more locking nubs is disposed on an outer cylindrical surface of the sharp carrier subassembly. 3 . The applicator assembly of claim 2 , wherein the each of the one or more locking nubs is further disposed on a proximal portion of the sharp carrier subassembly. 4 . The applicator assembly of claim 1 , wherein the corresponding each of the one or more carrier nub slots comprises a cut-out in the sensor electronics carrier. 5 . The applicator assembly of claim 4 , wherein the cut-out comprises a first slot portion having the open end, and a second slot portion that is substantially perpendicular with the first portion. 6 . The applicator assembly of claim 4 , wherein the cut-out comprises an L-shaped cut. 7 . The applicator assembly of claim 1 , wherein the open end of the corresponding each of the one or more carrier nub slots is disposed on a proximal portion of the sensor electronics carrier. 8 . The applicator assembly of claim 1 , further comprising a retraction spring, wherein the retraction spring comprises: a proximal end coupled with a distally-facing surface of the sharp carrier subassembly; and a distal end coupled with a proximally-facing surface of the sensor electronics carrier. 9 . The applicator assembly of claim 8 , wherein the retraction spring is in a preloaded and compressed state prior to the advancement of the each of the one or more locking nubs toward the open end. 10 . The applicator assembly of claim 8 , wherein the retraction spring is configured to apply a force to the distally-facing surface of the sharp carrier subassembly to cause retraction of the sharp to the retracted position. 11 . The applicator assembly of claim 1 , wherein each of the proximally-extending sharp retention arms of the plurality of proximally-extending sharp retention arms comprises a distal end having a sharp retention clip. 12 . The applicator assembly of claim 11 , wherein the sharp retention clip comprises a proximal surface that is substantially perpendicular to the longitudinal axis of the sharp carrier subassembly. 13 . The applicator assembly of claim 12 , wherein the proximal surface is configured to abut a distally facing surface of the sharp hub. 14 . The applicator assembly of claim 1 , further comprising a sheath comprising a distal end for placement on the skin surface of the subject. 15 . The applicator assembly of claim 14 , further comprising an applicator housing configured to receive a manual force along the central longitudinal axis of the sharp carrier subassembly in the distal direction. 16 . The applicator assembly of claim 15 , wherein the housing and the sheath are configured such that the manual force causes the housing to advance in the distal direction relative to the sheath while the sheath remains on the skin surface of the subject. 17 . The applicator assembly of claim 14 , wherein the sheath is configured to remain on the skin surface of the subject while the distal portion of the in vivo glucose sensor is positioned under the skin surface of the subject. 18 . The applicator assembly of claim 1 , wherein the sensor electronics comprises one or more processors, memory, wireless communication circuitry, and a power supply. 19 . The applicator assembly of claim 18 , wherein the wireless communication circuitry is configured to transmit data indicative of the subject's glucose levels according to a Bluetooth® or Bluetooth® Low Energy communication protocol. 20 . The applicator assembly of claim 1 , wherein the sharp carrier subassembly, the sensor electronics carrier, and the sensor control device are further configured to advance along a linear path from the proximal position to the distal position.