A compression garment having one or more flex frames that can be shortened or lengthened to apply or release a compressive force to the limb or other anatomical feature of a user. The compression garment can have a wire made of shape memory material (shape memory alloy). A controller of the compression garment can supply an electrical input to the wire, generating heat that can cause the wire to contract such that the flex frame deflects to a shorter length to apply a compressive force to the limb or other anatomical feature of the user. The one or more flex frames can be contracted in unison or in sequence to direct the flow of bodily fluids in the limb or other anatomical feature of the user.

A compression garment apparatus for a body part of an human and/or animal having a flexible backing, attaching means, a segmented flex frame, and a shape memory alloy on the segmented flex frame. The shape memory alloy can be connected to two terminals on the frame forming a circuit. A controller can be connected to the terminals applying current to the shape memory alloy at defined intervals providing intermittent, sequenced, or continuous compression therapy.

A compression garment having one or more flex frames that can be shortened or lengthened to apply or release a compressive force to the limb or other anatomical feature of a user. The compression garment can have a wire made of shape memory material (shape memory alloy). A controller of the compression garment can supply an electrical input to the wire, generating heat that can cause the wire to contract such that the flex frame deflects to a shorter length to apply a compressive force to the limb or other anatomical feature of the user. The one or more flex frames can be contracted in unison or in sequence to direct the flow of bodily fluids in the limb or other anatomical feature of the user.

A non-invasive method and device for promoting a localized change in a flow of blood through a blood vessel in a limb segment of a body by a series of electrically stimulated contractions of muscle tissue in the limb segment, the method including the steps of: (a) providing a device including: (i) first, second and third electrodes, each adapted to operatively contact the limb segment; (ii) a signal generator, operatively connected to the electrodes, adapted to produce a series of electrical impulses to the limb segment via the electrodes, and (iii) a control unit adapted to control the signal generator to produce the series of electrical impulses; (b) positioning the electrodes on the limb segment, wherein the first electrode is positioned on a lower end of the lower leg, the second electrode is positioned on the lower leg, and the third electrode is positioned on an upper end of the lower leg, whereby the first and third electrodes are disposed on opposite ends of the lower leg, and the second electrode and one of the first and third electrodes are disposed on a same end of the lower leg; (c) effecting a sequence of muscular contractions of the lower leg, by operations including: (i) applying a first electrical impulse between the electrodes on the same end of the lower leg to induce a first muscular contraction of a first portion of the tissue; and (ii) applying at least a second electrical impulse between the first and third electrodes to induce a longitudinal muscular contraction of a second portion of the muscular tissue; and (d) repeating operations (i) and (ii), to repeatedly induce the contractions, to effect the increased flow of blood.

The dry-immersion bed of the present invention is suitable for intensive care units (ICUs) and fulfills the function of providing treatment for diseases such as capillary leak syndrome. The dry immersion bed fulfills the function of recovering cardiovascular physiology by normalizing the systemic distribution of water, albumin and electrolytes, and improving lymphatic drainage, venous return, cardiac output, cell metabolism and immunity.

A medical apparatus has a base portion shaped and configured to engage a proximal portion of a user's limb, a mobile portion shaped and configured to engage a distal portion of the user's limb, and a motor assembly configured to selectively rotate the mobile portion relative to the base portion. Related methods are disclosed herein.

Disclosed are handicap apparatus using (a) one or more resilient, snap-on bumper structures, (b) unique tips covers, (c) leg elevating units, (d) resilient structures having a density that provides a softer exterior and a harder interior. The handicap apparatus includes crutches, canes, wheelchairs, scooters, and walkers.

A therapy system includes a patient support apparatus and a pneumatic therapy device that is coupleable to the patient support apparatus. The therapy device may receive power and air flow from the patient support apparatus.

A medical device providing a combination of thermal and DVT therapies to a patient. The components, arrangement of components, function of the device as a whole, and methods of use of the device are all devised to maximize therapeutic effectiveness. Effectiveness in this context is measured by the ability to provide a controlled application of the recommended thermal treatment including time, temperature, compression, and number of cycles with specified cycle duration.

A method of treatment includes using an electrical energizing source coupled to a current conducting coil to cause the current conducting coil to produce pulsed electromagnetic fields. A conducting membrane is placed adjacent the current conducting coil and an insulating coupling interface is placed adjacent the membrane, such that the membrane is between the current conducting coil and the insulating coupling interface. One portion of the pulsed electromagnetic fields is intercepted by the membrane so that the membrane oscillates to generate acoustic waves to tissue adjacent the insulating coupling interface and another portion of the pulsed electromagnetic fields propagates through the insulating coupling interface to the tissue.