Abstract: An intervertebral spacer and stabilization implant includes a plate having sockets configured for retaining a fastener passable through the socket and into an adjacent vertebral body. One or more connecting projections extend from a side of the plate, to mate with projections extending from a spacer body. A plurality of teeth project from at least one of the upper or lower surfaces of the spacer body, and a chamber is formed through the spacer body to enable bone fusion between the vertebrae. The combined plate and spacer may be inserted to lie completely within the intervertebral space, or a portion of the plate may overlie a vertebral body.

Abstract: Interspinous process implants are disclosed. Also disclosed are systems and kits including such implants, methods of inserting such implants, and methods of alleviating pain or discomfort associated with the spinal column.

Abstract: The present disclosure generally relates to semiconductor structures and, more particularly, to twisted wordline structures and methods of manufacture. The memory array structure includes: a plurality of bitcells comprising memory elements and access transistors; a plurality of bitlines and wordlines which interconnect the bitcells; a plurality of dummy bitcells which intersect with the bitlines and wordlines; and a plurality of twisted wordline strap cells which twist wordlines in the dummy bitcells and connect a higher metal layer in the bitcells to a gate structure of the access transistor.

Abstract: Methods of forming a gate cut isolation for an SRAM include forming a first and second active nanostructures adjacent to each other and separated by a space; forming a sacrificial liner over at least a side of the first active nanostructure facing the space, causing a first distance between a remaining portion of the space and the first active nanostructure to be greater than a second distance between the remaining portion of the space and the second active nanostructure. A gate cut isolation is formed in the remaining portion of the space such that it is closer to the second active nanostructure than the first active nanostructure. The sacrificial liner is removed, and gates formed over the active nanostructures with the gates separated from each other by the gate cut isolation. An SRAM including the gate cut isolation and an IC structure including the SRAM are also included.

Abstract: Interspinous process implants are disclosed. Also disclosed are systems and kits including such implants, methods of inserting such implants, and methods of alleviating pain or discomfort associated with the spinal column.

Abstract: Methods of forming a gate cut isolation for an SRAM include forming a first and second active nanostructures adjacent to each other and separated by a space; forming a sacrificial liner over at least a side of the first active nanostructure facing the space, causing a first distance between a remaining portion of the space and the first active nanostructure to be greater than a second distance between the remaining portion of the space and the second active nanostructure. A gate cut isolation is formed in the remaining portion of the space such that it is closer to the second active nanostructure than the first active nanostructure. The sacrificial liner is removed, and gates formed over the active nanostructures with the gates separated from each other by the gate cut isolation. An SRAM including the gate cut isolation and an IC structure including the SRAM are also included.

Abstract: Interspinous process implants are disclosed. Also disclosed are systems and kits including such implants, methods of inserting such implants, and methods of alleviating pain or discomfort associated with the spinal column.

Abstract: The present disclosure relates to a structure including a non-fixed read-cell circuit configured to switch from a first state to a second state based on a state of a memory cell to generate a sensing margin.

Abstract: Structures and static random access memory bit cells including complementary field effect transistors and methods of forming such structures and bit cells. A first complementary field-effect transistor has a first storage nanosheet transistor, a second storage nanosheet transistor stacked over the first storage nanosheet transistor, and a first gate electrode shared by the first storage nanosheet transistor and the second storage nanosheet transistor. A second complementary field-effect transistor has a third storage nanosheet transistor, a fourth storage nanosheet transistor stacked over the third storage nanosheet transistor, and a second gate electrode shared by the third storage nanosheet transistor and the fourth storage nanosheet transistor. The first gate electrode and the second gate electrode are arranged in a spaced arrangement along a longitudinal axis. All gate electrodes of the SRAM bitcell may be arranged in a 1CPP layout.

Abstract: Structures and static random access memory bit cells including complementary field effect transistors and methods of forming such structures and bit cells. A buried cross-couple interconnect is arranged in a vertical direction beneath a first field-effect transistor and a second field-effect transistor. The buried cross-couple interconnect is coupled with a gate electrode of the first field-effect transistor, and the buried cross-couple interconnect is also coupled with a source/drain region of the second field-effect transistor.

Abstract: Structures and static random access memory bit cells including complementary field effect transistors and methods of forming such structures and bit cells. A first complementary field-effect transistor has a first storage nanosheet transistor, a second storage nanosheet transistor stacked over the first storage nanosheet transistor, and a first gate electrode shared by the first storage nanosheet transistor and the second storage nanosheet transistor. A second complementary field-effect transistor has a third storage nanosheet transistor, a fourth storage nanosheet transistor stacked over the third storage nanosheet transistor, and a second gate electrode shared by the third storage nanosheet transistor and the fourth storage nanosheet transistor. The first gate electrode and the second gate electrode are arranged in a spaced arrangement along a longitudinal axis. All gate electrodes of the SRAM bitcell may be arranged in a 1CPP layout.

Abstract: A distraction screw includes a proximal portion secured to a first vertebra, a distal portion secured to a second vertebra and an intermediate portion. The intermediate portion is coupled to the proximal and distal portions and is positioned in an intervertebral space. The intermediate portion is configured and adapted to enable distraction of the first vertebra relative to the second vertebra.

Abstract: Structures for a non-volatile memory and methods for forming and using such structures. The structure includes a bitcell having a non-volatile memory element and a transmission gate. The transmission gate includes an n-type field-effect transistor and a p-type field effect transistor. The n-type field-effect transistor has a first drain region, a first source region, and a first gate electrode. The p-type field-effect transistor has a second drain region, a second source region coupled in parallel with the first source region, and a second gate electrode. The first drain region of the n-type field-effect transistor and the second drain region of the p-type field-effect transistor are coupled in parallel with the non-volatile memory element.

Abstract: Structures for a bitcell of a non-volatile memory and methods of fabricating such structures. A field-effect transistor of the bitcell includes a gate having gate electrodes that are arranged in a four contacted (poly) pitch layout. An interconnect structure is arranged over the field-effect transistor, and a memory element arranged in the interconnect structure. The memory element is connected by the interconnect structure with the field-effect transistor.

Abstract: Structures and static random access memory bit cells including complementary field effect transistors and methods of forming such structures and bit cells. A first complementary field-effect transistor has a first storage nanosheet transistor, a second storage nanosheet transistor stacked over the first storage nanosheet transistor, and a first gate electrode shared by the first storage nanosheet transistor and the second storage nanosheet transistor. A second complementary field-effect transistor has a third storage nanosheet transistor, a fourth storage nanosheet transistor stacked over the third storage nanosheet transistor, and a second gate electrode shared by the third storage nanosheet transistor and the fourth storage nanosheet transistor. The first gate electrode and the second gate electrode are arranged in a spaced arrangement along a longitudinal axis. All gate electrodes of the SRAM bitcell may be arranged in a 1CPP layout.

Abstract: Disclosed are structures with a complementary field effect transistor (CFET) and a buried metal interconnect that electrically connects a source/drain region of a lower-level transistor of the CFET with another device. The structure can include a memory cell with first and second CFETs, where each CFET includes a pull-up transistor stacked on and having a common gate with a pull-down transistor and each pull-down transistor has a common source/drain region with a pass-gate transistor. The metal interconnect connects a lower-level source/drain region of the first CFET (i.e., the common source/drain region of first pass-gate and pull-up transistors) to the common gate of the second CFET (i.e., to the common gate of second pull-down and pull-up transistors). Formation methods include forming an interconnect placeholder during lower-level source/drain region formation.

Abstract: A distraction screw includes a proximal portion secured to a first vertebra, a distal portion secured to a second vertebra and an intermediate portion. The intermediate portion is coupled to the proximal and distal portions and is positioned in an intervertebral space. The intermediate portion is configured and adapted to enable distraction of the first vertebra relative to the second vertebra.

Abstract: A method of forming a buried local interconnect is disclosed including, among other things, forming a first sacrificial layer embedded between a first semiconductor layer and a second semiconductor layer, forming a plurality of fin structures above the second semiconductor layer, forming a mask layer having an opening positioned between an adjacent pair of the fin structures, removing a portion of the second semiconductor layer exposed by the opening to expose the first sacrificial layer and define a first cavity in the second semiconductor layer, removing portions of the first sacrificial layer positioned between the first semiconductor layer and the second semiconductor layer to form lateral cavity extensions of the first cavity, forming a first liner layer in the first cavity, and forming a conductive interconnect in the first cavity over the first liner layer.

Abstract: Structures for a non-volatile memory and methods for forming and using such structures. The structure includes a bitcell having a non-volatile memory element and a transmission gate. The transmission gate includes an n-type field-effect transistor and a p-type field effect transistor. The n-type field-effect transistor has a first drain region, a first source region, and a first gate electrode. The p-type field-effect transistor has a second drain region, a second source region coupled in parallel with the first source region, and a second gate electrode. The first drain region of the n-type field-effect transistor and the second drain region of the p-type field-effect transistor are coupled in parallel with the non-volatile memory element.

Abstract: A method of forming a buried local interconnect is disclosed including, among other things, forming a first sacrificial layer embedded between a first semiconductor layer and a second semiconductor layer, forming a plurality of fin structures above the second semiconductor layer, forming a mask layer having an opening positioned between an adjacent pair of the fin structures, removing a portion of the second semiconductor layer exposed by the opening to expose the first sacrificial layer and define a first cavity in the second semiconductor layer, removing portions of the first sacrificial layer positioned between the first semiconductor layer and the second semiconductor layer to form lateral cavity extensions of the first cavity, forming a first liner layer in the first cavity, and forming a conductive interconnect in the first cavity over the first liner layer.