This invention relates to generally to devices used to treat living bodies after surgery. This invention relates particularly to a noninvasive, pressure-actuated apparatus for applying percussions to a body to facilitate the redistribution of fat remaining after liposuction or to massage the body.
Liposuction involves inserting a cannula through small incisions in a body and vacuuming out fat cells. Typically the cannula is moved in a reciprocating motion in conjunction with a fan motion to remove the fat uniformly within a desired area. Ideally, deep pockets of fat, as opposed to the fat in the even superficial layer near the skin, is removed during liposuction. The fat remaining near the skin helps leave the skin with a smooth contour. However, sometimes the fat near the skin is absent naturally or removed during liposuction. To avoid contour irregularities such as dimpling or rippling, the fat that remains must be redistributed in a uniform manner, as well as replaced in some areas. To contour and give a better shape to a body, deep fat removed from one area may be deposited in another area.
Several methods have been developed to improve the texture of the skin and contour of the body after liposuction. Pressure dressings, girdles, or contouring garments are placed on a liposuction patient after surgery and may be worn for several days or weeks to help the skin adhere to the new shape and contract properly. It has been reported that liposuction patients have smoother skin if the skin is percussed, rolled or massaged by hand during or immediately after the surgery to redistribute the fat remaining after liposuction. These treatments have has other beneficial effects, as well, such as relaxing the patient. However, it is difficult for a practitioner to uniformly and continuously percuss or massage a patient at length, particularly in a relatively small area of the body, such as the area affected by liposuction. It is desirable to automate such a treatment.
Therefore, it is an object of this invention to provide an apparatus to massage a body be percussion. It is a further object of the invention to provide an apparatus that facilitates the redistribution of fat after liposuction.
The present invention is a hand-held percussive device for massaging a body and facilitating the redistribution of fat remaining after liposuction. A piston is driven by in a reciprocating motion externally against a patient's skin. The default position of the piston is in an “off” position, and the device is actuated when it is depressed against the skin of a patient. Preferably the piston is driven pneumatically and in the default “off” position the gas that drives the piston is exhausted through a port, away from the patient and practitioner. When the device is depressed against the skin of a patient, force is applied to the piston causing a floating valve that moves in concert with the piston to block the exhaust port. This redirects gas into the piston chamber and forces the piston out of the piston chamber. At its farthest extension, the floating valve unblocks the exhaust port, allowing the air to be redirected out, away from the piston allowing the piston to retract into the piston chamber. The cycle repeats itself as long as force is applied to the piston.
Referring to
The housing 11 also has an aperture to receive a floating valve 16, the aperture referred to herein as a valve chamber 17. The valve chamber 17 and piston chamber 14 are in fluid communication at opening A, as indicated in FIG. 7. The floating valve 16 is part of a valve assembly 18, further comprising a pin 19 that fits loosely through an aperture in the housing 30, through an aperture 20 in the floating valve 16 and protrudes into an aperture 21 in the piston 12. This valve assembly 18 thereby causes the floating valve 16 and the piston 12 to move cooperatively and to be retained within the housing 11. Preferably the pin 19 and piston aperture 21 are matedly threaded.
A series of substantially air-tight compartments are formed between the floating valve 16 and valve chamber 17 by seating several valve o-rings, 31, 32, 33, 34, and 35 in the detents formed by annular valve rings, 41, 42, 43, 44, 45, respectively, which have a smaller diameter than the floating valve 16.
Referring now particularly to
The speed at which the device operates is partially dependent on the pressure of the incoming gas. At sufficiently high speeds, the gas in the valve chamber 17 will not have time to flow to the primary exhaust port 63 before the floating valve 16 completely retracts. For this reason, a secondary exhaust port 64 is formed in the housing 11. The secondary exhaust port 64 allows gas in the valve chamber 17 to more quickly escape as the valve is displacing gas upon retraction.
While the preferred embodiment of the device is driven pneumatically, the reciprocating motion may also be driven electronically. In this embodiment, the piston 12 is in connection with an electrical source. A switch and means for biasing the piston in a reciprocal motion are in communication with the electrical source and the piston such that the electrical source and the switch cooperate to cause the piston to move in a reciprocating motion.
A head mount 22 is attached to the piston 12, preferably by a threaded screw 23 in piston/head mount aperture 38, although other means of attachment will suffice. A head 24 is attached to the head mount 22. The head 24 is preferably oval in cross-section, but may take on other shapes or have a larger or smaller diameter that the head 24 shown herein. Because they are attached to each other, the head 24 and head mount 22 move in concert with the piston 12. The head mount 22 has guides 36a, 36b, and 36c that slide in head mount guide apertures in the housing, 37a, 37b, and 37c, respectively.
The head 24 is also removable and may be interchanged with other heads. In the preferred embodiment, the head 24 is attached to the head mount 22 by a compression fit. As shown in
The device is pressure-actuated when the piston 12 is depressed as a result of pressing the head 24 against the patient's skin. The default position of the piston is in an “off” position, wherein the gas that drives the piston is exhausted through a port, away from the patient and practitioner. This starts the cycle describes above, namely that when the head is depressed against the skin of a patient, the floating valve blocks the exhaust ports, thereby redirecting air into the piston chamber and forcing the piston out of the piston chamber. At its farthest extension, the floating valve unblocks the exhaust port, allowing the air to be redirected out, away from the piston allowing the piston to retract into the piston chamber. The cycle repeats itself as long as force is applied to the piston.
While there has been illustrated and described what is at present considered to be the preferred embodiment of the present invention, it will be understood by those skilled in the art that various changes and modifications may be made and equivalents may be substituted for elements thereof without departing from the true scope of the invention. Therefore, it is intended that this invention not be limited to the particular embodiment disclosed, but that the invention will include all embodiments falling within the scope of the appended claims.
Number | Name | Date | Kind |
---|---|---|---|
1657765 | Pasque | Jan 1928 | A |
2211214 | Miller | Aug 1940 | A |
3955563 | Maione | May 1976 | A |
4513737 | Mabuchi | Apr 1985 | A |
4716890 | Bichel | Jan 1988 | A |
6228042 | Dungan | May 2001 | B1 |
6503211 | Frye | Jan 2003 | B2 |
Number | Date | Country | |
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20040049137 A1 | Mar 2004 | US |