Abstract: A self-retaining artificial spinal disc is formed of a flexible material and has a peripheral lip or meniscus extending from its top and/or bottom surface. The meniscus/menisci encircle portions of vertebrae adjacent the implant site, to enhance retention of the artificial spinal disc when seated in the spinal column. The meniscus/menisci for example snugly overlie the vertebral portions, and foster a suction seal between the disc and the adjacent vertebrae. The disc may be formed as an integral whole, or as two half-discs joinable by gluing, melting or like methods. In a related method, a self-retaining artificial spinal disc is formed in layers, by pouring and drying measures of liquid disc solution in a mold. A meniscal extension is formed from the disc body. Drugs or salts may be added to the disc layers, for example to provide an artificial spinal disc with time-release antibiotics or a desired porosity.

Abstract: Apparatuses and methods for determining particle shed rates of implantable or inter-dwelling devices are disclosed. Durability test apparatuses with integrated particle counters produce time-dependent particle shed rate profiles. The apparatuses are designed to accommodate pulsatile flow, resembling a heartbeat at the implantable device. In an embodiment, the pulsatile flow is converted to a steady flow before fluid enters the integrated particle counter.

Abstract: An ultrasound calibrator apparatus and method for calibrating ultrasound equipment. The apparatus includes a pair of opposed bellows oscillatorily transferring a fluent medium back and forth through a channel with a well-defined cross-sectional area such that the flow velocity therethrough is known. A probe in communication with ultrasound equipment to be tested is submerged in a reservoir which is situated in close proximity to the channel such that the flow velocity can be measured therewith. The ultrasound equipment is then adjusted to correct the discrepancies between the known and measured velocities so as to calibrate the ultrasound equipment.

Abstract: A dynamic vascular compliance tester (change in radius with change in pressure) comprises an oscillatorily driven bellows to simulate pulsing a fluid pressure within a test specimen and a method of use thereof. The tester includes a high frequency pressure transducer and a pair of linear voltage-to-displacement transducers ("LVDT") providing outputs that are utilized cooperatively to determine the compliance of a test specimen. A first LVDT measures the volume of fluid in each pulse provided by the bellows and a second LVDT measures the change in length of the test specimen during the pulse. The tester also includes an offset drive mechanism that is operably adjustable such that the volume of fluid passing into the test specimen can be altered as desired.