Abstract: An ultrasound transducer assembly includes a housing; a wedge-shaped acoustic modal convertor (AMC) in the housing with a first surface exposed by an opening in the housing, and a second surface that meets the first surface at a tip located in the housing, and extends from the tip at an angle into the housing, wherein the second surface has a recessed portion formed therein, wherein the second surface of the AMC is oriented at a specific oblique angle to the first surface of the AMC; and a piezoelectric ultrasound transducer disposed in the recessed portion of the second surface of the AMC, wherein the piezoelectric ultrasound transducer is connected to an electrically tuned circuit that resonates at a specific frequency and has a finite bandwidth.

Abstract: A method for generating a spatial distribution of acoustic transmitting frequencies by a time modulated array (TMA) of transducers includes generating, by a tapped delay line, a plurality of pulsed sampling signals, wherein each pulsed sampling signal includes a series of frequency harmonics and successive signals of the plurality of pulsed sampling signals are separated by a predetermined delay time; mixing each of the plurality of pulsed sampling signals with a time-limited information signal wherein a plurality of mixer output signals is generated; bandpass filtering each of the plurality of mixer output signals; generating a first plurality of simultaneous TMA beams from the plurality of filtered and weighted output signals by driving a plurality of acoustic transducers in a spatial array of acoustic transducers, wherein each beam of the first plurality of simultaneous beams is associated with one of a plurality of transmitting carrier frequencies

Abstract: A method for ultrasound stimulation of musculo-skeletal tissue structures includes generating a plurality of acoustic spatial-temporal modes comprised of a sinusoidal-complex, wherein the sinusoidal-complex has a modulation envelope that enhances spatial-temporal measurement accuracy at a site of a multi-layered biological tissue structure, and a pulse repetition frequency and duty cycle that are osteogenic at the site of the multi-layered biological tissue structure, beam steering the acoustic spatial-temporal modes to the site of the multi-layered biological tissue structure to promote tissue healing, and producing bi-modal stress levels in the multi-layered biological tissue structure that are sufficient to generate bone fracture healing.

Abstract: A method and kit for therapeutically treating bone and tissue injuries using ultrasound. The method includes the steps of introducing an ultrasound contrast agent into the patient, preferably, the patient's blood stream, and impinging ultrasonic waves in proximity to an injury. The ultrasound contrast agent facilitate in lowering the cavitation threshold, i.e., the energy required for the cavitation, to a level attainable by the ultrasonic waves to induce acoustic intracellular microstreaming to accelerate the healing process. The method further includes the steps of maintaining the resonance bubble frequency of the microbubbles of the ultrasound contrast agent from 0.5 MHz to 10 MHz; maintaining the acoustic transmit frequency of the ultrasound waves from 10 kHz to 10 MHz; and maintaining the acoustic spatial average-temporal average (SATA) intensity of the ultrasonic waves from 5 to 500 mW/cm2.

Abstract: A modal converter having at least one ultrasonic transducer or at least one array of such transducers positioned on the modal converter at various angles relative to a tissue surface and bone tissue surface, such that some combination of one or more of the following occur: longitudinal waves are produced perpendicular to the bone surface, longitudinal waves propagate along the surface of the skin after incidence at the skin tissue surface, and both longitudinal and shear waves propagate along the surface of the bone after incidence at the bone tissue surface. Illuminating an open tissue wound and bone fracture site with these acoustic modes enhances and promotes angiogenesis and the biological endostial or periostial healing phases, or both, of the bone fracture healing process. The spatial and temporal distribution of acoustic waves directed to the treatment area via the ultrasonic transducers and the modal converter may be controlled.

Abstract: The invention relates to apparatus and method for ultrasonically and electromagnetically treating tissue to treat, for example, traumatized tissue or a bone injury. The apparatus includes at least one ultrasonic transducer assembly and at least one electromagnetic coil-assembly configured to cooperate with a placement module for placement in proximity to the treatment area. The apparatus also utilizes a portable main operating unit constructed to fit within a pouch or carrying case worn by the patient. In operation, at least one ultrasonic transducer and at least one electromagnetic coil are activated by transmitting control signals to the placement module from the main operating unit. The activation of the at least one ultrasonic transducer causes ultrasonic waves to be propagated toward the treatment area which are modulated by electrostatic and magnetic forces generated by the at least one electromagnetic coil.

Abstract: Ultrasound bandages and ultrasound transducer array bandages are provided herein to accelerate the healing of wounds by positioning the ultrasound transducer array bandages adjacent to a wound and generating ultrasonic pulses. The ultrasonic bandages generally include a backing layer and a transducer material disposed on at least a portion of the adhesive layer. The ultrasound transducer array bandages generally include a backing layer and an array comprising a plurality of transducer materials arranged in adjacent relation to define spaces therebetween, the array being disposed on at least a portion of the backing layer.

Abstract: Ultrasound bandages (10) and ultrasound transducer array bandages are provided herein to accelerate the healing of wounds by positioning the ultrasound bandages (10) and ultrasound transducer array bandages adjacent to a wound and generating ultrasonic pulses. The ultrasound bandages (10) generally include (a) a backing layer (12), (b) an adhesive layer (14) applied to, and substantially coextensive with the backing layer (12), and (c) a transducer material (16) disposed on at least a portion of the adhesive layer (14). The ultrasound transducer array bandages generally include (a) a backing layer (13), (b) an adhesive layer applied to, and substantially coextensive with, the backing layer, and (c) an array comprising a plurality of transducer materials arranged in adjacent relation to define spaces therebetween, the array being disposed on at least a portion of the adhesive layer.

Abstract: The invention relates to apparatus and method for ultrasonically stimulating cartilage growth. The apparatus includes at least one ergonomically constructed ultrasonic transducer configured to cooperate with a placement module or strip for placement in proximity to an area where cartilage growth is desired. The apparatus also utilizes a portable, ergonomically constructed main operating unit constructed to fit within a pouch worn by the patient. In operation, at least one ultrasonic transducer positioned in proximity to an osteochondral site is excited for a predetermined period of time. To ensure that at least one ultrasonic transducer is properly positioned, and to insure compliance with a treatment protocol, a safety interlock is provided to prevent inadvertent excitation of the at least one ultrasonic transducer.

Abstract: The invention relates to apparatus and method for ultrasonically stimulating cartilage growth. The apparatus includes at least one ergonomically constructed ultrasonic transducer configured to cooperate with a placement module or strip for placement in proximity to an area where cartilage growth is desired. The apparatus also utilizes a portable, ergonomically constructed main operating unit constructed to fit within a pouch worn by the patient. In operation, at least one ultrasonic transducer positioned in proximity to an osteochondral site is excited for a predetermined period of time. To ensure that at least one ultrasonic transducer is properly positioned, and to insure compliance with a treatment protocol, a safety interlock is provided to prevent inadvertent excitation of the at least one ultrasonic transducer.

Abstract: A system (10) having a processor, a memory, generates low frequency ultrasound signals to be applied to tissue (14) to generate a weighted sum of tissue ramp, step, and impulse signatures. The system (10) analyzes the tissue signatures to determine the low frequency target profile which is used to generate a graphic representation of the tissue as well as to estimate the volume of the tissue; to classify the tissue (14) as to type, and condition of the tissue using a set of stored tissue data. The classifier may include a neural network (34), and/or a nearest neighbor rule processor (36). The system (10) performs as a non-invasive acoustic measurement, an imaging system, and method which uses Synthetic Structural Imaging (SSI) techniques to provide unique information concerning the size, shape of biological structures for classification, visualization of normal, abnormal tissues, organs, biological structures, etc.

Abstract: A kit of elements including an ultrasonic generator (12), transducers (402) with connecting cables (407, 408), and a means (405, 406) for locating the transducers over areas of the body containing cartilage, is provided with the surgical instruments for post-surgical application to ultrasonically stimulate the cartilage growth, thus relieving the effects of surgical intervention.

Abstract: The invention relates to apparatus and method for therapeutically treating reflex sympathetic dystrophy using ultra sound. The apparatus includes at least one ergonomically constructed ultrasonic transducer configured to cooperate with a placement module or strip for placement in proximity to pain receptors of the sympathetic nervous system. The apparatus also utilizes a portable, ergonomically constructed main operating unit constructed to fit within a pouch worn by the patient. In operation, at least one ultrasonic transducer positioned in proximity to the pain receptors of the sympathetic nervous system is excited for a predetermined period of time. To ensure that at least one ultrasonic transducer is properly positioned, and to insure compliance with a treatment protocol, a safety interlock is provided to prevent inadvertent excitation of the at least one ultrasonic transducer.

Abstract: A kit of elements including an ultrasonic generator, transducers with connecting cables, and a means for locating the transducers over areas of the body containing cartilage, is provided with the surgical instruments for post-surgical application to ultrasonically stimulate the cartilage growth, thus relieving the effects of surgical intervention.

Abstract: A controller for driving an ultrasonic transducer is disclosed and includes a processor, responsive to a feedback signal, for generating control signals to an output driver which is responsive to the control signals, to cause the ultrasonic transducer to generate ultrasound having a power level corresponding to the control signal. The controller is preferably attached to a sensing circuit to determine the amount of ultrasound conductive gel associated with the ultrasonic transducer, and for generating the feedback signal therefrom. The controller includes data logging capabilities to record treatment data and prevent unnecessary extended treatment. The controller creates an environment for safer ultrasonic self-treatment by patients. The microprocessor used in the controller can be used to warn of a low battery condition or insufficient amount of ultrasound conducting gel.

Abstract: A non-invasive bone condition data acquisition system performs sensitive and reliable clinical data acquisition, localization and classification of bone disease, particularly osteoporosis. The bone condition data acquisition system measures a correlation between a wideband AE signature and a spatially localized bone microarchitecture, which is used to determine fracture risk. The bone condition data acquisition system includes processors and memory for analyzing AE signals from bone tissue to generate information-bearing attributes, for extracting a set of times-of-arrival and a feature vector from the attributes, for utilizing the set of times-of-arrival to derive the locations of the AE events, and for responding to the feature vector to classify the bone using a neural network and a nearest neighbor rule processor.

Abstract: A transducer for non-invasive transcutaneous transmission of pulsed ultrahigh-frequency acoustic radiation, in body tissue and/or fluids adjacent a bone fracture is "on target" when a fraction of the propagated energy within the longitudinal-response lobe of the transducer encounters a crack or other open feature of the fracture, where a gap or space exists between closely spaced fracture walls. The ultrahigh-frequency acoustic radiation sees this "on target" feature as the entrance to a waveguide, whereby pulsed ultrahigh-frequency acoustic radiation is guided within the crack. When this acoustic radiation encounters a gap of at least a quarter wavelength (at the ultrahigh frequency), a standing wave condition establishes itself, with dissipation of the ultrahigh frequency and with demodulation to establish a therapeutically beneficial low-frequency acoustic condition, within the fracture, and acting where most needed, namely, on and between wall regions of adjacent fragments of the broken bone.