An energy delivery system comprises a transmission member and an antenna at a distal end of the transmission member. The antenna includes a first conductive arm, an insulator extending around the first conductive arm, and a second conductive arm. The second conductive arm includes a coil. The system also comprises a barrier layer surrounding the transmission member and antenna. The barrier layer extends from a proximal portion of the transmission member to a distal portion of the antenna. The system also comprises a jacket surrounding the barrier layer and forming a fluid channel for receipt of a cooling fluid.

An ablation probe (100; 200) comprising: an applicator (102; 202) arranged to apply radiation to heat surrounding tissue; a feeding cable (104; 204) arranged to supply electromagnetic energy to the applicator; a coolant flow path (106, 108) forming a coolant supply circuit; a tubular member (112; 212) housing at least part of the feeding cable (104; 204), wherein a part of the coolant flow path is defined by a space between the feeding cable and the tubular member; and a coupling body (114). The coupling body comprises: a cavity (116) in which the applicator (102; 204) is at least partly encapsulated; a coupling interface (118) at which the coupling body (114) is coupled to the tubular member; and a pointed distal tip (H4a) adapted for piercing tissue.

Various aspects of the present disclosure are directed toward apparatuses, systems, and methods that may include a microwave ablation probe. The microwave ablation probe may include a feedline having an inner conductor, an outer conductor and a dielectric; and an antenna including a helical arm, the helical arm being electrically connected to the outer conductor of the feedline at a junction point, and a linear arm, the linear arm being electrically connected to the inner conductor of the feedline.

Provided in accordance with the present disclosure are systems and methods for identifying a percutaneous tool in image data. An exemplary method includes receiving image data of at least a portion of a patient's body, identifying an entry point of a percutaneous tool through the patient's skin in the image data, analyzing a portion of the image data including the entry point of the percutaneous tool through that patient's skin to identify a portion of the percutaneous tool inserted through the patient's skin, determining a trajectory of the percutaneous tool based on the identified portion of the percutaneous tool inserted through the patient's skin, identifying a remaining portion of the percutaneous tool in the image data based on the identified entry point and the determined trajectory of the percutaneous tool, and displaying the identified portions of the percutaneous tool on the image data.

Surgical visualization systems and related methods are disclosed herein, e.g., for providing visualization during surgical procedures. Systems and methods herein can be used in a wide range of surgical procedures, including spinal surgeries such as minimally-invasive fusion or discectomy procedures. Systems and methods herein can include various features for enhancing end user experience, improving clinical outcomes, or reducing the invasiveness of a surgery. Exemplary features can include access port integration, hands-free operation, active and/or passive lens cleaning, adjustable camera depth, and many others.

Described herein are various implementations of systems and methods for treating back pain (e.g., chronic low back pain) caused by different (e.g., independent) sources of pain, such as pain originating or stemming from intervertebral discs, from vertebral endplates, and/or from intraosseous locations within one or more vertebral bodies. For example, methods for treating back pain (e.g., chronic low back pain) may involve both vertebral fusion (e.g., arthrodesis or spondylodesis to fuse adjacent vertebrae) and neuromodulation (for example, ablation of nerves within or surrounding one or more of the adjacent vertebrae). The neuromodulation may facilitate treatment of pain that is generated by insertion of fusion hardware.

A microwave applicator for insertion into living body tissue for use in microwave coagulation and ablation treatments includes a microwave transmission line extending between an attachment end of the applicator and an antenna toward an insertion end of the applicator with an outer conductive sleeve forming an enclosed cooling fluid space around the transmission line. Circulation of cooling fluid is guided in the cooling fluid space by a guide sleeve. A fluid circulation system provides a plurality of fluid supply connectors and fluid return connectors which can be connected and used with any number of applicators between one and the number of the fluid supply connectors provided by the system. A portion of the applicator inserted into the tissue can stick to the tissue to stabilize the applicator during treatment. A warning marking on the applicator can be used during track ablation to prevent ablation of the patient skin tissue.

Disclosed are a fast planning system and method applicable to ablation therapy. The system comprises an input device, a calculation device and an output device, the calculation device obtains a boundary of the tumor and an actual position of an ablation probe relative to a tumor through the input device, the quantitative relationship between the ablation range and the ablation parameters of the ablation probe, and maximum ablation range parameters of the ablation probe. The system obtains the ablation parameters of the ablation probe by means of the calculation device based on the obtained information, outputs the ablation parameters by means of the output device, and obtains a revised planning suggestion. The present invention resolves the issue of incomplete ablation in a clinical ablation operation possibly resulting from deviation of an actual probe insertion position from a probe insertion position planned prior to the operation, and is conducive to achieving precision control over thermal dosage at a focal region and ensuring the effectiveness of ablation therapy.

Various aspects of the present invention are directed towards apparatuses, systems, and method that may include a tissue ablation system. The tissue ablation system may include an ablation device, an ablation generator, and a controller configured to initiate a pre-ablation procedure in a medium, and during the pre-ablation procedure monitor temperature data and/or power data.

An electrosurgical instrument having a radiating tip portion capable performing tissue ablation using microwave energy and electroporation (e.g. non-thermal irreversible electroporation) in a minimally invasive manner. The electrosurgical instrument may be used to perform microwave ablation and electroporation separately (e.g. sequentially) or simultaneously. The radiating tip portion may be dimensioned to be suitable for insertion into a pancreas via a surgical scoping device, to provide a rapid and accurate alternative to known RF ablation techniques. By enabling tumours within the pancreas to be treated using a minimally invasive procedure, it may be a viable option to use ablation and/or electroporation treatment for both curative as well as palliative reasons.