A method and system for noninvasive face lifts and deep tissue tightening are disclosed. An exemplary method and treatment system are configured for the imaging, monitoring, and thermal injury to treat the SMAS region. In accordance with an exemplary embodiment, the exemplary method and system are configured for treating the SMAS region by first, imaging of the region of interest for localization of the treatment area and surrounding structures, second, delivery of ultrasound energy at a depth, distribution, timing, and energy level to achieve the desired therapeutic effect, and third to monitor the treatment area before, during, and after therapy to plan and assess the results and/or provide feedback.

An apparatus and corresponding method of use relate to diagnostic ultrasound probing. In particular, the apparatus is suitable for ultrasound guidance for musculoskeletal (MSK) injections. The apparatus is a palm-wearable device configured to removably and replaceably receive and hold a sensor device. The palm-wearable device enables a user to have one hand for manipulating the sensor device and a free hand for performing other tasks such as a MSK injection.

The present invention relates to an ultrasound calibration device comprising a body portion having at least one echogenic fiducial; a marker portion having at least one tracking marker which can be detected by a medical tracking system; and a hook-shaped mounting portion extending from the body portion.

The present invention also relates to a method for calibrating an ultrasound probe, comprising the steps of filling a container with a fluid, in particular a physiologic salt solution; placing an ultrasound calibration device in accordance with the invention into the container; comparing, with the aid of a medical navigation system, a calculated position of at least one fiducial with a determined position of the at least one fiducial which is determined using a tracked ultrasound probe.

An ultrasound probe which is connected to an ultrasound diagnosis apparatus includes an acoustic element for converting an electric signal and an ultrasound to each other, an electric signal processing circuit electrically connected to the acoustic element, a case for storing the acoustic element and the electric signal processing circuit, an acoustic element board for electrically connecting the acoustic element to the electric signal processing circuit, and a partition part which is arranged to contact with the case and separates the acoustic element and the electric signal processing circuit. A space on the side of the acoustic element in the case separated by the partition part is filled with a first material having lower thermal conductivity than that of a material for forming an inner wall surface of the case. Accordingly, the heat generated by a circuit unit such as the electric signal processing circuit can be more efficiently dissipated.

Provided is a pulmonary edema monitoring apparatus, which is always attached to the body and is capable of continuously monitoring whether a pulmonary edema occurs, for a patient with advanced disease or a shock patient. This pulmonary edema monitoring apparatus includes: an ultrasound frequency module which is attached to the chest of a patient, generates an ultrasound, and receives a reflection wave reflected from the inside of a human body; and a control module which measures the intensity (this is referred to as “ultrasound radio frequency data”) of the reflection wave, determines whether a pulmonary edema occurs on the basis of an increasing rate of the ultrasound radio frequency data according to a degree of multiple reflection, and provides an alarm.

An improved ultrasound probe (100) has an ultrasound transducer as a body (10) and is capable of accurate positioning on target operative regions of a patient after being improved. The ultrasound probe (100) at least comprises the body (10) and an engagement member (20); the body (10), at an end thereof, comes into contact with patient skin (S), and is provide, on a side surface thereof, with a groove (11) extending from the end that can contact the patient skin (S); the engagement member adjoins the groove (11) of the body (10), allowing one side surface of an article to be disengaged from or engaged in the groove (11), and the engagement member (20) is located at a first location and a second location relative to the groove (11); the article is engaged in the groove (11) when the engagement member (20) is located at the first location relative to the groove (11), and on the contrary, the article is disengaged from the side surface of the body (10) when the engagement member (20) is located at the second location relative to the groove (11).

A handheld-type probe is used, the probe including: a grip portion; a plurality of detection elements configured to receive an acoustic wave and output an electrical signal; a detection surface where the plurality of detection elements are disposed; and a light-absorber supporting member where a light absorber is disposed, the light absorber absorbing light emitted from a light source and generating an acoustic wave.

A system for sensing a position of an ultrasound imaging device includes an ultrasound (US) imaging device, and a position sensor mount, and a position sensor. The position sensor mount includes an elastic body portion, a first rigid shell disposed on a distal portion of the elastic body portion, a second rigid shell disposed on a proximal portion of the elastic body portion, and a first adhesive disposed on the first rigid shell. The position sensor is mounted on the first rigid shell and configured to sense position information of the US imaging device in a coordinate system. The US imaging device is received by the position sensor mount and circumscribed by the first adhesive.

A probe for an ultrasonic diagnostic apparatus which is used for performing a test upon a subject is provided. The probe includes a case which forms an exterior of the probe, a piezoelectric object which is provided on an inside of the case and which generates an ultrasonic wave, a sound absorbing layer which is provided at a rear surface of the piezoelectric object and which prevents the ultrasonic wave from being delivered to a rear portion of the piezoelectric object, an acoustic matching layer which delivers the generated ultrasonic wave to a subject by matching a sound impedance of the piezoelectric object with a sound impedance of the subject, and a sound lens which concentrates the generated ultrasonic wave and radiates the concentrated ultrasonic wave toward the subject.

An ultrasound probe is provided for multi-faceted exams, such as for triage and emergency. The probe can include different transducer arrays, such as a linear, a curved linear, and a sector array that are combined into a single hand held unit with a wireless display. Related methods are provided, such as a method for automatically selecting the appropriate array for the user to scan with based on the intended exam and/or location of the probe on the body of a patient.