Abstract: Methods and devices are described for the regulation of bone morphogenetic protein gene expression in bone cells via the application of fields generated by specific and selective electric and electromagnetic signals in the treatment of diseased or injured bone. By gene expression is meant the up-regulation or down-regulation of the process whereby specific portions (genes) of the human genome (DNA) are transcribed into mRNA and subsequently translated into protein. Methods and devices are provided for the targeted treatment of injured or diseased bone tissue that include generating specific and selective electric and electromagnetic signals that generate fields optimized for increase of bone morphogenetic protein gene expression and exposing bone to the fields generated by specific and selective signals so as to regulate bone morphogenetic protein gene expression in such bone tissue.

Abstract: Methods and devices are described for the regulation of Transforming Growth actor (TGF)-?1, ?2, and/or ?3 protein gene expression in bone cells and other tissues via the capacitive coupling or inductive coupling of specific and selective electric fields to the bone cells or other tissues, where the specific and selective electric fields are generated by application of specific and selective electric and electromagnetic signals to electrodes or one or more coils or other field generating device disposed with respect to the bone cells or other tissues so as to facilitate the treatment of diseased or injured bone and other tissues. By gene expression is meant the up-regulation or down-regulation of the process whereby specific portions (genes) of the human genome (DNA) are transcribed into mRNA and subsequently translated into protein.

Abstract: A method of determining the voltage and current output required for the application of specific and selective electric and electromagnetic signals to diseased articular cartilage in the treatment of osteoarthritis, cartilage defects due to trauma or sports injury, or used as an adjunct with other therapies (cell transplantation, tissue-engineered scaffolds, growth factors, etc.) for treating cartilage defects in the human knee joint and a device for delivering such signals to a patient's knee. An analytical model of the human knee is developed whereby the total tissue volume in the human knee may be determined for comparison to the total tissue volume of the diseased tissue in the animal model using electric field and current density histograms.

Abstract: A technique and device for preventing and/or treating osteoporosis, hip and spine fractures, and/or spine fusions by incorporating at least one conductive coil (110) into a garment (90) adapted to be worn adjacent to the patient's skin over a treatment area and applying an electrical signal to the coil effective to produce a magnetic flux the penetrates the treatment area so as to produce an electric field in the bones and the treatment area.

Abstract: A portable device for applying therapeutic electrical signals and/or electromagnetic fields to a patient's knee for the treatment of osteoarthritis and other diseases, defects and injuries. The device is operable in several modes to deliver signals to the patients knee so as to cause an electric and/or electromagnetic field to be generated that selectively up-regulates gene expression of Aggrecan and Type II Collagen while simultaneously selectively down-regulating the gene expression of metalloproteases. The device includes a signal generator that generates compound electric signals including a 60 kHz sine wave having a peak to peak voltage of approximately 4.6 V to 7.6 V and a 100% duty cycle signal that is generated for approximately 30 minutes and a 50% duty cycle signal that is generated for approximately 1 hour after the 100% duty cycle signal.

Abstract: A method of determining the voltage and current required for the application of specific and selective electric and electromagnetic signals to diseased articular cartilage in the treatment of osteoarthritis, cartilage defects due to trauma or sports injury, or used as an adjunct with other therapies (cell transplantation, tissue-engineered scaffold, growth factors, etc.) for treating cartilage defects in the human hip joint and a device for delivering such signals to a patient's hip. Anatomic, analytical, and planar circuit models are developed to determining the impedances, conductivities, and current flows in the human hip joint and its surrounding soft tissues and skin that are required to produce a 20 mV/cm electric field in the synovium and articular cartilage of the human hip. The voltage of the signal applied to the surface electrodes or to a coil(s) or solenoid is varied based on the size of the hip joint; larger hip joints require larger voltages to generate the effective electric field.

Abstract: A technique and associated device for stimulating multiple electrodes with multiple electrical signals in multiple regions of the spine without injury to the patient. The electrodes are applied to respective sides of the patient's spine, and a first electrical signal is applied to any electrodes in a treatment area of the lumbar region of the patient's spine, a second electrical signal is applied to any electrodes in a treatment area of the thoracic region of the patient's spine, and a third electrical signal is applied to any electrodes in a treatment area of the cervical region of the patient's spine to induce osteogenesis in at least one of the respective treated area's of the patient's spine. The first, second, and third electrical signals respectively generate different electrode currents in the respective treated areas and are ideally selected to create current densities that are approximately equal in respective treatment areas.

Abstract: A portable device for applying therapeutic electrical signals and/or electromagnetic fields to a patient's knee for the treatment of osteoarthritis and other diseases, defects and injuries. The device is operable in several modes to deliver signals to the patients knee so as to cause an electric and/or electromagnetic field to be generated that selectively up-regulates gene expression of Aggrecan and Type II Collagen while simultaneously selectively down-regulating the gene expression of metalloproteases. The device includes a signal generator that generates compound electric signals including a 60 kHz sine wave having a peak to peak voltage of approximately 4.6 V to 7.6 V and a 100% duty cycle signal that is generated for approximately 30 minutes and a 50% duty cycle signal that is generated for approximately 1 hour after the 100% duty cycle signal.