A method for preventing osteopenia, promoting bone tissue growth, ingrowth, and healing of bone tissue includes the step of applying a mechanical load to the bone tissue at a relatively low level on the order of between about 50 and about 500 microstrain, peak-to-peak, and at a relatively high frequency in the range of about 10 and about 50 hertz. Mechanical loading at such strain levels and such frequencies has been found to prevent bone loss and enhance new bone formation.

A method is provided for treating postural instability following a determination that a patient is experiencing postural instability. The method includes the steps of (a) providing a vibration table having a non-rigidly supported platform; (b) permitting the patient to rest on the non-rigidly supported platform for a predetermined period of time; and (c) repeating the steps (a) and (b) over a predetermined treatment duration. Step (b) includes the steps of (b1) measuring a vibrational response of the patient's musculoskeletal system using a vibration measurement device; (b2) performing a frequency decomposition of the vibrational response to quantify the vibrational response into specific vibrational spectra; and (b3) analyzing the vibrational spectra to evaluate at least postural stability. Preferably, the predetermined period of time is approximately 10 minutes and the predetermined treatment duration is at least four weeks.

The invention presents a method and device for increasing the fracture resistance of a bone tissue to a traumatic force. The method includes the step of selecting a nonphysiological impulse force having a location and direction resembling that of the traumatic force, but having a magnitude significantly smaller than the magnitude of the traumatic force. The impulse force is then repeatedly applied to the bone tissue, thereby stimulating the bone tissue to grow bone mass in critical areas where stresses from the traumatic force are largest. A device for applying the method includes an impulse force applicator for repeatedly applying the impulse force and a positioner for positioning the impulse force relative to the bone tissue.

Method and apparatus for testing an implant attached to a bone of a human or animal subject includes a member releasably attached to the implant. The member carries a transducer for exciting the member with a variable frequency AC signal, and a transducer for detecting a resonance frequency of the member. The detected resonance frequency is used to assess the degree of attachment of the implant to the bone.

A non-invasive method and apparatus for determining the dynamic biomechanical characteristics (frequency response functions and natural frequency) of a musculoskeletal structure is provided. The method generally comprises exciting the musculoskeletal structure over a broad range of frequencies with a low amplitude, high velocity impulsive input force, measuring the input force with a force transducer, detecting the output motion response with an output transducer, processing input force and output response data into time-signal histories with a data acquisition and analysis means or digital computer, transforming the time-signal histories from the time domain to the frequency domain by applying Fourier analysis; and calculating a frequency response function and the natural frequency from the input force and dynamic output response time-signal histories. Having identified the natural frequency of the musculoskeletal structure, the clinician can then mobilize the structure at that frequency in order to maximize the effectiveness of spinal therapy. The apparatus comprises an impact device, an input transducer, an output transducer, and a data acquisition and analysis means or digital computer. In particular, a hand-held, manually operated impact device for delivering a near optimal, low amplitude, high velocity, impulsive input force over a broad range of frequencies and characterized by a generally half-sinusoidal waveform is also provided.