Abstract:
A device for controlling the weight of a body comprises a hollow member having an expandable and a non-expandable portion to its exterior surface. The hollow member is selectively expanded and/or contracted following implantation in the abdominal cavity to direct pressure to the abdominal cavity, thereby restricting food intake without physically invading the abdominal cavity. The hollow member is preferably positioned superficial to the fascia, muscle, peritoneum and abdominal cavity of the abdominal region according to the method of the present invention to minimize the risks associated with traditional food intake restriction surgeries.

Description:
TECHNICAL FIELD  
       [0001]     This invention relates to weight control, and more particularly to a device and method for controlling body weight via indirect reduction of the volume of the abdominal cavity.  
       BACKGROUND  
       [0002]     Obesity is a chronic disease and constitutes a major health concern. In the United States alone obesity accounts for more than $100 billion in health care annually. Far from being a purely cosmetic issue, being obese or morbidly obese puts a person at an increased risk for developing and/or aggravating dozens of serious medical conditions. More than 30 obesity-related medical conditions are currently recognized. These include arthritis, several forms of cancer, carpal tunnel syndrome, cardiovascular disease, gallbladder disease, gout, hypertension, infertility, liver disease, low back pain, obstetric and gynecologic complications, sleep apnea, stroke, type-2 diabetes, and urinary stress incontinence.  
         [0003]     Obesity is commonly measured by using the Body Mass Index (BMI). In terms of BMI, obesity is defined as having a BMI of 30 kg/m 2 . Morbid obesity is defined as the condition of obesity coupled with one or more secondary debilitating factors, such as hypertension, cardiovascular disease and/or diabetes. A BMI of 40 kg/m 2  is generally recognized to constitute morbid obesity. Importantly, morbid obesity ranks second only to smoking as a preventable cause of death in the U.S.  
         [0004]     While obesity is recognized to be simply an imbalance between caloric intake and caloric burn rate, the factors producing obesity are varied and complex. Genetic, biological and even psychological influences can influence the condition. As a result, obesity is a disease that eludes simple treatment or attempts to shed weight.  
         [0005]     Weight loss is generally recommended for persons with obesity or morbid obesity. The loss of excess weight can improve the health of a person by lowering risks from obesity-related medical conditions. Methods of weight loss include dietary therapy, increased physical activity, behavior therapy, drug therapy, surgery or a combination of therapies.  
         [0006]     Attempts at sustained weight loss via non-surgical means within the population of the obese are overwhelmingly unsuccessful. Moreover, it is estimated that this disease has a recurrence rate in greater than 90%. Consequently, long-term results of conservative treatments for obesity are generally unsuccessful, and can actually prove detrimental by producing further loss of self-esteem with the regaining of weight.  
         [0007]     In contrast, surgery is a well-established method of long-term weight control for persons with obesity. Surgical procedures assist a person in losing weight by adjusting the way the body digests and/or absorbs calories. This is most often accomplished via surgically-implemented changes to the stomach and/or small intestine.  
         [0008]     One general category of obesity surgery targets the relative absorption of food. This type of procedure seeks to shorten the length of, or otherwise modify, the small intestine to limit the amount of foods that is ultimately absorbed by the body (malabsorption). Common examples of malabsorption procedures include: gastric bypass (e.g., Roux-en-Y gastric bypass); biliopancreatic diversion; and intestinal bypass.  
         [0009]     Other surgical methods address obesity via restriction of food intake. This type of surgical procedure seeks to alter the size (volume) of the stomach, therefore limiting the amount of food it can hold. The result is a premature feeling of satiety and a reduced intake of calories. Common examples of procedures producing food intake restriction include: vertical banded gastroplasty; gastric banding; and laparoscopic gastric banding.  
         [0010]     Through malabsorption, food intake restriction, or some combination of both, weight is reduced since less food either enters the stomach and/or less food remains in the small intestine long enough to be digested and absorbed.  
         [0011]     As with any surgical procedure, there are risks associated with obesity surgical procedures. Additionally, each procedure has an associated success rate that, to a certain extent, is dependent upon whether a person is willing to make certain lifestyle changes in association therewith. As a general rule, procedures that invasively alter the size or volume of the stomach carry with them increased risks, such as infections, leaking of stomach juices into the abdomen, injury to the spleen, band slippage, erosion of the band, breakdown of the staple line, and stomach pouch stretching from overeating. Such risks are due not only to the physical stapling, banding or other direct manipulation of the stomach, but also in part to the fact that the surgeon has to invade the skin, fat, fascia, muscle and peritoneum of the abdominal region to make physical contact with the abdominal cavity to conduct such procedures.  
         [0012]     In a previously unrelated area, tissue expanders have been employed in the context of cosmetic and reconstructive surgery where the need for additional tissue is present. Tissue expanders are implantable devices capable of expansion over time. They take advantage of the fact that tissue under prolonged physical stress will produce additional tissue. Such devices are used to dissect tissue, create cavities or pockets, or separate layers of soft tissue. In use for tissue dissection, for example, a surgeon makes a remote incision into the body and inserts a hollow tissue expander into the incision to a point where a space or cavity or pocket is desired. Fluid is then forced into the expander to cause it to expand and separate two layers of tissue to form the desired space or cavity or pocket. The dissection takes place along the edges of the incision and peripherally outward from the tissue expander.  
         [0013]     Although there have been many improvements in tissue expanders since their inception, use of tissue expanders to date has been limited to dissecting tissue, creating cavities or pockets, or separating layers of soft tissue, and the like.  
         [0014]     There remains a need for a device and method of addressing obesity that includes only minimally-invasive surgical procedures (thus avoiding many of the associated risks of surgical procedures that invasively alter the size of the stomach), but which produce success rates in terms of weight reduction and sustainability of same comparable to current, fully-invasive surgical procedures. Ideally, such a device and related method would reduce the volume of the abdominal cavity with a minimal amount of physical invasion of the abdominal cavity.  
       SUMMARY  
       [0015]     The present invention comprises a device and method for controlling body weight via indirect reduction of the volume of the abdominal cavity utilizing a specialized tissue expander. One embodiment of the present invention includes a device for producing intra-abdominal pressure from a point superficial to the fascia of the abdominal cavity to decrease the volume of the abdomen without physically invading the abdominal cavity. In an embodiment of the method of the present invention, an incision is made in the abdominal region of the body. Next an expandable device is placed into the incision to a point superficial to the fascia of the abdominal region. Following placement, the device is expanded to produce intra-abdominal pressure, effectively reducing the volume of the abdominal cavity. Importantly, such intra-abdominal pressure is created without physical invasion of the abdominal cavity.  
         [0016]     An embodiment of the device of the present invention is an expandable hollow member including means for expansion. Optimally, the hollow member includes both a rigid and a flexible region along its exterior surface. This feature, when the hollow member is oriented properly and expanded via the means for expansion, will direct the pressure created by the expansion of the hollow member towards the abdominal cavity. Such pressure will effectively reduce the volume of the abdominal cavity, causing the person to require less food to achieve a sense of satiety. The ingestion of less food by the person will also necessarily advantageously affect relative food absorption in the lower intestine.  
         [0017]     Once in place using the present invention method, the level of expansion of the device (hollow member) of the present invention can be selectively adjusted via the means for expansion without the need for additional surgery. If, for example, weight loss is occurring too rapidly for the person, the expansion can be reduced. The effect of the reduction of expansion will be a reduction of intra-abdominal pressure created by same, allowing the person to ingest a higher volume of food. If, on the other hand, weight loss is not progressing or has reached a plateau, expansion of the device can be increased, thereby increasing the intra-abdominal pressure created and reducing the volume of food needed by the person to feel “full.” 
         [0018]     The details of one or more embodiments of the invention are set forth in the accompanying drawings and the description below. Other features, objects, and advantages of the invention will be apparent from the description and drawings, and from the claims.  
     
    
     DESCRIPTION OF DRAWINGS  
       [0019]      FIG. 1  is a cross section of an abdominal cavity of a human illustrating normal anatomy of same;  
         [0020]      FIG. 2  is a cross section of an abdominal cavity of a human showing normal anatomy and including an embodiment of the system of the present invention (non-expanded);  
         [0021]      FIG. 3  is a flow chart outlining the steps of an embodiment of the method of the present invention; and  
         [0022]      FIG. 4  is a cross section of an abdominal cavity of a human showing normal anatomy and including an embodiment of the system of the present invention with the system (expanded).  
         [0023]     Like reference symbols in the various drawings indicate like elements. 
     
    
     DETAILED DESCRIPTION  
       [0024]     The present invention comprises a device and method for controlling body weight via indirect reduction of the volume of the abdominal cavity utilizing a specialized tissue expander.  FIG. 1 , a cross section of an abdominal cavity of a human exhibiting normal anatomy, illustrates a body  10 , said body including an abdominal region  20  having skin  30 , fat  40 , muscle  50 , fascia  60 , a peritoneum  70  and an abdominal cavity  80 . The abdominal cavity  80  comprises the stomach (not shown) which receives and processes food and other nourishment for the body  10 , passing same to the intestines (not shown) of the body  10 .  
         [0025]      FIG. 2  illustrates a cross sectional view of the abdominal region  20  of the body  10  including placement of an embodiment of an implantable food restriction device  90  of the present invention (in non-expanded mode). The implantable food restriction device  90  is preferably comprised of a hollow member  92  and means for expansion and contraction (not shown) of the hollow member  92 . The hollow member  92  preferably includes a relatively non-expandable portion  100  and a relatively expandable portion  110 . When placed in the abdominal region  20  of the body  10 , the relatively expandable portion  110  is oriented towards the abdominal cavity  80 , thereby positioning the relatively non-expandable portion  100  of the hollow member  92  away from the abdominal cavity  80  (i.e., towards the fat  40 ). Once placed within the abdominal region  20  and expanded (see  FIG. 4 ), the hollow member  92  will apply the force of pressure created from the expansion towards the fascia  60 , the muscle  50 , the peritoneum  70  and, ultimately, the abdominal cavity  80 , thereby reducing the relative volume of the abdominal cavity  80 . Although the hollow member  92  of the implantable food restriction device  90  of this embodiment is described as having a relatively expandable portion  110  and a relatively non-expandable portion  100 , it is noted that the implantable food restriction device  90  can utilize a hollow member  92  lacking the relatively expandable portion  110  and/or the relatively non-expandable portion  100 . Any expansion of the implantable food restriction device  90  will create intra-abdominal pressure that will reduce the relative volume of the abdominal cavity  80 . Therefore, any suitable design of the implantable food restriction device  90  is contemplated by this invention.  
         [0026]     The implantable food restriction device  90  includes means for expansion and contraction (not shown). Such means for expansion and contraction can be any suitable means for providing and extracting a liquid or gas from the hollow member in a manner that does not require additional surgical procedures. For example, one such means is a tube that is relatively hollow and flexible and which protrudes from, or is contained within, the body when attached to the hollow member  92  of the implantable food restriction device  90 . The tube is utilized to provide and extract liquids or gases from the hollow member  92 . If a liquid or gas is provided to the hollow member  92 , it expands and creates the intra-abdominal pressure that reduces the relative volume of the abdominal cavity  80 . The intra-abdominal pressure created by the hollow member  92  of the implantable food restriction device  90  can be controlled over time by providing and/or extracting a liquid or gas from the hollow member  92  in response to weigh loss progress of the body  10 . Although a tube means has been described herein, it is noted that any suitable means for providing/extracting a liquid or gas from the hollow member  92  of the implantable food restriction device  90  may be employed with the present invention.  
         [0027]     The food restriction device  90  of the present invention can be constructed of any suitable material(s), and is preferably constructed of a durable, relatively flexible material or materials capable of being safe use for prolonged periods of time within the human body, such as surgical grade plastics, polymers and the like. Additionally, the hollow member  92  of the food restriction device  90  may be sized and shaped in any suitable combination to produce the desired level of intra-abdominal pressure necessary to achieve desired weight loss by the body  10 . It is noted that varying sizes, shapes and combinations thereof of the food restriction device  90  may be employed as suggested by the individual needs of the body  10  in question to optimize the results achieved via use of the present invention.  
         [0028]     As illustrated in  FIG. 3 , one embodiment of the present invention surgical method for controlling weight of a body, said body including an abdominal region having skin, fat, muscle, fascia, a peritoneum and an abdominal cavity, comprises five primary steps. In Step  300  of the method, an incision is made into the abdominal region of a body. The incision can be made utilizing any traditional means for same, including via scalpel, laser, or other suitable cutting device. In Step  310 , an implantable food restriction device is provided, said implantable food restriction device having a hollow member and associated means for expansion and contraction. The hollow member of the implantable food restriction device is inserted in Step  320  into the incision created in step  300 . The food restriction device of the present invention may be inserted via any suitable method for same, including, without limitation, via endoscope or open method technique. In Step  330 , the implantable food restriction device is positioned to a point superficial to the abdominal cavity. In Step  340  the hollow member of the implantable food restriction device is selectively expanded or contracted via the means for expansion and contraction over a time period to exert pressure on the abdominal cavity. The result of exerting pressure on the abdominal cavity is to control the relative volume of same. Increased pressure on the abdominal cavity will reduce its relative volume, causing the body (e.g., person) to require less food to achieve a sense of satiety. The ingestion of less food by the body will also necessarily advantageously affect relative food absorption in the lower intestine. Importantly, the hollow member of the implantable food restriction device can be expanded or contracted without the need for additional surgery, allowing for highly flexible control over weight gain for the body. If, for example, weight loss is occurring too rapidly for the body, the expansion can be reduced. The effect of the reduction of expansion will be a reduction of intra-abdominal pressure created by same, allowing the person to ingest a higher volume of food (and also adjusting the relative food absorption rate in the lower intestine). The overall result will be a slow down in weight loss experienced by the body. If, on the other hand, weight loss is not progressing at a satisfactory rate (e.g., weight loss has reached a plateau), expansion of the device can be increased, thereby increasing the intra-abdominal pressure created, reducing the volume of food needed by the person to feel “full,” and advantageously affecting the relative food absorption rate in the lower intestine.  
         [0029]      FIG. 4  is an illustration of layers the abdominal region  20  of a body  10  including placement of an embodiment of the food restriction device  90  of the present invention (in expanded mode). As the hollow member  92  of the food restriction device  90  is expanded via the means for expansion and contraction (not shown), in a preferred embodiment the relatively expandable portion  110  of the hollow member  92  expands and directs the intra-abdominal pressure created by expansion of the food restriction device  90  towards the muscle  50  and the fascia  60  of the abdominal cavity  20 , which in turn apply pressure to the peritoneum  70  and, ultimately, the abdominal cavity  80 , the overall effect of which is to reduce the relative volume of the abdominal cavity  80  without the need for physical invasion of the abdominal cavity  80 . With the relative volume of the abdominal cavity  80  reduced, the body  10  will require less food to achieve a sense of satiety. Additionally, the ingestion of less food by the body  10  will also necessarily advantageously affect relative food absorption in the lower intestine. The combined effect of the foregoing will be a reduction in weight of the body  10 .  
         [0030]     In use, the food restriction device  90  is positioned to a point superficial to the abdominal cavity  80 . Specifically, in a preferred embodiment, the food restriction device  90  is positioned to a point superficial to the fascia  60  of the abdominal region  20 . This positioning of the food restriction device  90  is considered an optimal balance of the desired transfer of intra-abdominal pressure to the abdominal cavity  80  with the desire to have the least physical invasion of the abdominal region  20 . Although optimal positioning of the food restriction device  90  is described as being superficial to the fascia  60  of the abdominal region  20 , it is noted that the invention contemplates positioning of the food restriction device  90  at any point within the abdominal region  20  that reduces the relative volume of the abdominal cavity  80  via the production of intra-abdominal pressure without physical invasion of the abdominal cavity  80 .  
         [0031]     As can be appreciated, the change in relative volume of the abdominal cavity  80  created as a result of the food restriction device  90  of the present invention is directly related to the relative change in volume of the hollow member  92  of the food restriction device  90 . Therefore, if additional weight loss by the body  10  is desired, the relative volume of the hollow member  92  of the food restriction device  90  can be increased via the means for expansion and contraction. Conversely, if it is desired that the body  10  experience less weight loss (or have the rate of weight reduction slowed), the relative volume of the hollow member  92  of the food restriction device  90  can be reduced via the means for contraction and expansion.  
         [0032]     One significant advantage of the device and method of the present invention is that it does not invade the abdominal cavity  80 . The lack of physical invasion of the abdominal cavity  80  eliminates leaking of stomach juices into the abdomen, injury to internal organs (e.g., spleen) and further avoids complications associated with the use of devices within the abdominal cavity  20  such as staples, bands and the like, thus leading to quicker recovery times, reduced hospital stays and increased patient satisfaction.  
         [0033]     A number of embodiments of the invention have been described. Nevertheless, it will be understood that various modifications may be made without departing from the spirit and scope of the invention. For example, the device could be shaped or otherwise modified (e.g., in size) so as to more completely focus the pressure created via expansion of same. Accordingly, other embodiments are within the scope of the following claims.