An antenna guide assembly including a guide body having a proximal end defining at least one proximal entry, a distal end defining at least one distal port, and at least one guide passage extending between the proximal and distal ends. The at least one guide passage is configured to receive at least
An antenna guide assembly including a guide body having a proximal end defining at least one proximal entry, a distal end defining at least one distal port, and at least one guide passage extending between the proximal and distal ends. The at least one guide passage is configured to receive at least a portion of an antenna therethrough via the at least one proximal entry such that a distal portion of the antenna extends through and distally from the at least one distal port for insertion into tissue. A locking assembly disposed at the distal end of the guide body is configured to receive the distal portion of the antenna therethrough. The locking assembly is configured to selectively engage the distal portion of the antenna to prevent translation of the antenna within the at least one guide passage.
대표청구항▼
1. An antenna guide assembly, comprising: a guide body having a proximal end defining at least one proximal entry, a distal end defining at least one distal port, and at least one guide passage extending between the proximal and distal ends, the at least one guide passage configured to receive at le
1. An antenna guide assembly, comprising: a guide body having a proximal end defining at least one proximal entry, a distal end defining at least one distal port, and at least one guide passage extending between the proximal and distal ends, the at least one guide passage configured to receive at least a portion of an antenna therethrough via the at least one proximal entry such that a distal portion of the antenna extends through and distally from the at least one distal port for insertion into tissue;a locking assembly disposed at the distal end of the guide body and configured to receive the distal portion of the antenna therethrough, the locking assembly configured to selectively engage the distal portion of the antenna to prevent translation of the antenna within the at least one guide passage; andat least one retaining member including a threaded portion configured to couple the locking assembly to the at least one distal port of the guide body. 2. The antenna guide assembly of claim 1, wherein the locking assembly is disposed in a cavity defined by the guide body between a distal end of the at least one guide passage and the at least one distal port. 3. The antenna guide assembly of claim 1, wherein the locking assembly includes a release latch configured to selectively disengage the locking assembly from the distal portion of the antenna such that the antenna is translatable within the at least one guide passage. 4. The antenna guide assembly of claim 1, wherein the at least one guide passage defines an alignment channel configured to engage a portion of the antenna to orient the antenna for insertion into tissue. 5. The antenna guide assembly of claim 1, wherein the guide body is constructed from a polymer. 6. The antenna guide assembly of claim 1, further comprising at least one retaining member including a snap-fit member configured to couple the locking assembly to the guide body. 7. The antenna guide assembly of claim 1, wherein the guide body includes a first guide passage disposed parallel to a second guide passage, the first guide passage configured to receive at least a portion of a first antenna therethrough and the second guide passage configured to receive at least a portion of a second antenna therethrough. 8. The antenna guide assembly of claim 7, wherein each of the first and second guide passages define an alignment channel configured to engage a portion of the corresponding first and second antennas. 9. The antenna guide assembly of claim 8, wherein the alignment channel of the first guide passage is disposed at a first radial position relative to the first guide passage and the alignment channel of the second guide passage is disposed at a second radial position relative to the second guide passage, the second radial position the same as the first radial position such that the first and second antennas extend distally from the guide body in a parallel relationship. 10. The antenna guide assembly of claim 8, wherein the alignment channel of the first guide passage is disposed at a first radial position relative to the first guide passage and the alignment channel of the second guide passage is disposed at a second radial position relative to the second guide passage, the second radial position different than the first radial position such that the first and second antennas extend distally from the guide body in a non-parallel relationship. 11. An antenna guide assembly, comprising: a guide body including: a proximal end defining a first and second proximal entry;a distal end defining first and second distal ports;a first guide passage extending between the first proximal entry and the first distal port, the first guide passage defining a first alignment channel disposed parallel to, and radially about, an axis defined by the first guide passage, the first guide passage configured to receive at least a portion of a first antenna therethrough via the first proximal entry such that a distal portion of the first antenna extends through and distally from the first distal port for insertion into tissue; anda second guide passage extending between the second proximal entry and the second distal port, the second guide passage defining a second alignment channel disposed parallel to, and radially about, an axis defined by the second guide passage, the second guide passage configured to receive at least a portion of a second antenna therethrough via the second proximal entry such that a distal portion of the second antenna extends through and distally from the second distal port for insertion into tissue,wherein the first alignment channel of the first guide passage is configured to engage a portion of the first antenna and the second alignment channel of the second guide passage is configured to engage a portion of the second antenna to orient the first and second antenna with respect to the radial position of the first and second alignment channels;a first locking assembly disposed in a distal cavity of the guide body and configured to selectively engage the first antenna to prevent translation of the first antenna within the first guide passage; anda second locking assembly disposed in the distal cavity of the guide body and configured to selectively engage the second antenna to prevent translation of the second antenna within the second guide passage,wherein each of the first and second locking assemblies include a release latch configured to selectively disengage the first and second locking assemblies from the corresponding first and second antennas such that the first and second antennas are translatable within the corresponding first and second guide passages. 12. An antenna guide assembly, comprising: a guide body having a proximal end defining at least one proximal entry, a distal end defining at least one distal port, and at least one guide passage extending between the proximal and distal ends, the at least one guide passage configured to receive at least a portion of an antenna therethrough via the at least one proximal entry such that a distal portion of the antenna extends through and distally from the at least one distal port for insertion into tissue;a locking assembly disposed at the distal end of the guide body and configured to receive the distal portion of the antenna therethrough, the locking assembly configured to selectively engage the distal portion of the antenna to prevent translation of the antenna within the at least one guide passage; andat least one retaining member including a snap-fit member configured to couple the locking assembly to the guide body. 13. An antenna guide assembly, comprising: a guide body having a proximal end defining at least one proximal entry, a distal end defining at least one distal port, and at least one guide passage extending between the proximal and distal ends, the at least one guide passage configured to receive at least a portion of an antenna therethrough via the at least one proximal entry such that a distal portion of the antenna extends through and distally from the at least one distal port for insertion into tissue;a locking assembly disposed at the distal end of the guide body and configured to receive the distal portion of the antenna therethrough, the locking assembly configured to selectively engage the distal portion of the antenna to prevent translation of the antenna within the at least one guide passage; andat least one retaining member configured to couple the locking assembly to the guide body.
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