These teachings include accessing energy dosing information along with at least one quality-of-care model that correlates at least one categorical energy-based treatment patient quality-of-care outcome with at least one resultant energy-based treatment description. The model can be created via probabilistic mapping that maps patient impact information to dose impartation information to infer non-biological impact to a patient. A patient treatment plan can be optimized for a particular patient as a function of the foregoing information to provide corresponding resultant benefit trade-of evaluation information. This benefit trade-off evaluation information can be displayed to a user to permit the user to explore the benefit trade-off evaluation information to thereby identify a resultant energy-based treatment plan having a selected balance between dosing a treatment target with energy and a quality-of-care impact on the particular patient.

The invention relates to a system for assisting in planning a focal therapy treatment of a structure (1) within a patient body (2) by applying a treatment quantity using one or more devices (4a,b,c) operated in one or more device positions. The system comprises a unit (10) configured to generate a constraint function representing clinical objectives relating to the treatment quantity, a selection unit (11) configured to determine, for each of at least some non-selected candidate device positions, a sum of negative derivatives of the constraint function with respect to the treatment parameter associated with the respective device position and to select a device position for use in the treatment based on a comparison of the determined sums, and an optimization unit (12; 408) configured to determine at least one optimized treatment parameter for the selected device position based on the constraint function.

Provided herein are methods relating to administering a dendritic cell activating therapy as an adjunct to radiation therapy or an energy-based therapy for treating a tumor or cancer in an individual.

Provided herein are methods relating to administering a dendritic cell activating therapy as an adjunct to radiation therapy or an energy-based therapy for treating a tumor or cancer in an individual.

An implantable device has a body that is substantially rigid and has a predetermined shape. The body is further bioabsorbable and has a density less than or equal to about 1.03 g/cc. When the device is implanted in a resected cavity in soft tissue, it causes the cavity to conform to the predetermined shape. The implantable device is further imageable due to its density being less than that of soft tissue such that the boundaries of the tissue corresponding to the predetermined shape can be determined.

An implantable device has a body that is substantially rigid and has a predetermined shape. The body is further bioabsorbable and has a density less than or equal to about 1.03 g/cc. When the device is implanted in a resected cavity in soft tissue, it causes the cavity to conform to the predetermined shape. The implantable device is further imageable due to its density being less than that of soft tissue such that the boundaries of the tissue corresponding to the predetermined shape can be determined.

Embodiments herein relate to medical device systems including electric field shaping elements for use in treating cancerous tumors within a bodily tissue. In an embodiment, a medical device system for treating a cancerous tumor is described. The medical device system can include one or more electric field generating electrodes and an electric field shaping element configured to be implanted along with the one or more electric field generating electrodes. The electric field shaping element can be made from a material that alters the spatial area of tissue exposed to the electric field. Other embodiments are also included herein.

Embodiments herein relate to medical device systems including electric field shaping elements for use in treating cancerous tumors within a bodily tissue. In an embodiment, a medical device system for treating a cancerous tumor is described. The medical device system can include one or more electric field generating electrodes and an electric field shaping element configured to be implanted along with the one or more electric field generating electrodes. The electric field shaping element can be made from a material that alters the spatial area of tissue exposed to the electric field. Other embodiments are also included herein.

An system, and method are disclosed for harmonic modulation of standing wavefields for spatial focusing, manipulation, and patterning of particles, cells, powders, aerosols, colloids, and solids using a multifrequency wave source, a chamber a control module and an analysis module to generate standard wavefields useful for tissue engineering, micro fabrication, therapeutic treatment, and diagnostic tests.

Disclosed is a microwave treatment apparatus which treats the surface of the skin or subcutaneous tissues using a combination among a microwave frequency electric field generated by microwaves, low-frequency electric spark discharge and low-temperature ionized gas flow.