VERY IMPORANT article on how the Lap band SHOULD WORK -- by surgeon who created the...
on 11/2/13 2:18 am, edited 11/2/13 2:23 am
Thought I would share this very important article on how the band works, from a scientific standpoint, and what causes complications.
I know this post is a bit too late for many, but it is VERY important information on how the lap band REALLY works from the founder of the "Green Zone".
Too bad this article was not available to me over 8 years ago when I got my band placed. This article also show how the band.
http://bariatrictime...1/#comment-2133
Gastric Banding and the Fine Art of Eating
BT Online Editor | September 22, 2011
by Paul O’Brien, MD
Dr. O’Brien is from the Centre for Obesity Research and Education (CORE), Monash University, Melbourne, Australia.
Bariatric Times. 2011;8(9):18–21
Funding: No funding was received for the preparation of this article.
Financial Disclosure: Dr. Paul O’Brien is the Emeritus Director of the Centre for Obesity Research and Education (CORE) at Monash University, which receives a grant from Allergan for research support. The grant is not tied to any specified research projects and Allergan has no control of the protocol, analysis and reporting of any studies. CORE also receives a grant from Applied Medical toward educational programs. Dr. O’Brien has written a patient information book entitled The Lap-Band Solution: A Partnership for Weight Loss, which is given to patients without charge, but some are sold to surgeons and others for which he receives a royalty. Dr. O’Brien is employed as the National Medical Director for the American Institute of Gastric Banding, a multicenter facility, based in Dallas, Texas, that treats obesity predominantly by gastric banding.
Abstract
The author reviews the physiology of eating and what the adjustable gastric band does to the function of the distal esophagus and upper stomach of the patient. The author also provides the “Eight Golden Rules” on proper eating habits for patients of laparoscopic adjustable gastric banding, including what, when, and how they should eat, in order to achieve optimal weight loss results.
Introduction
Laparoscopic adjustable gastric banding (LAGB) has been shown to enable patients with obesity to achieve substantial, durable, and safe weight loss,[1,2] which can help reduce or resolve multiple diseases,[3] improve quality of life, and prolong survival in patients with obesity.[4] LAGB is a weight loss surgical procedure performed solely for the purpose of affecting a key physiological function in weight loss, appetite control. In 2005, we conducted a randomized, blinded, crossover trial that showed that the LAGB controls the appetite.[5]
However, if the LAGB is not placed properly or if the patient does not eat properly, it will not perform at an optimal level. For example, if the band is placed too loosely, then it will not provide the proper level of reduced satiety and appetite, and likely will have little effect on the patient’s weight and health. If the band is placed too tightly or if patient eats too fast or takes large bites of food, slips and enlargements can occur, leading to reflux, heartburn, vomiting, and sometimes the need for revision. Optimally, the band should be adjusted so that it squeezes the stomach at just the right pressure. If the patient eats correctly and the band is placed correctly, the LAGB should adequately control the patient’s appetite, resulting in optimal weight loss.
The Physiology of LAGB
Dr. Paul Burton, a bariatric surgeon at the Centre for Obesity Research and Education, Melbourne Australia, has studied the physiology and the pathophysiology of the LAGB closely. He used high-resolution video manometry, isotope transit studies, endoscopy, and contrast imaging to understand what happens during eating in normal controls, eating in patients who are doing well after LAGB, and eating in patients who have symptoms of reflux, heartburn, and/or vomiting after LAGB.[7–15] In Burton’s series of articles, he concluded that in LAGB, it is not the band that fails, but rather the patients *****ceive the band and, more importantly, the doctors who care for them.
Many years ago at the Centre for Obesity Research and Education (CORE), my colleagues and I developed the Green Zone chart, a conceptual way of identifying the optimal level of band restriction (Figure 1). When a patient is in the yellow zone, it is an indication that the band is too loose.
When in the yellow zone, a patient may be eating too easily, feeling hungry, and not losing weight. When a patient is in the green zone, he or she does not feel hungry, is satisfied with small amounts of food, and is achieving weight loss or maintaining a satisfactory level of reduced weight.
When a patient is in the the red zone, it is an indication that the band is too tight. The patient experiences reflux, heartburn, and vomiting. The range of food the patient in the red zone can eat after undergoing LAGB is limited and he or she may start to eat abnormally (so-called maladaptive eating), favoring softer, smoother foods like ice cream and chocolate. While in the red zone, patients will not lose weight as effectively and they may even gain weight.
Burton measured the pressure within the upper stomach beneath the band in numerous patients when they were in the green zone. He found the optimal pressure was typically 25 to 30mmHg. The art of adjustment is to find the level of fluid in the band that achieves that pressure range. That level of pressure generates a background sense of satiety that persists throughout the day. The patient, when correctly adjusted, normally will not feel hungry upon waking in the morning, and throughout the day should feel much less hungry than he or she did before band placement. In my experience, it is common for LAGB patients to have no feeling of hunger in the morning. Then, during the day, a modest level of hunger will develop, which a small meal should satisfy.
One of the key lessons learned from Burton’s studies was that each bite of food should pass across the band completely before another bite is swallowed. There is no pouch or small stomach above the band and there should never be food sitting there waiting.
The esophagus is a powerful muscular organ that typically generates pressures of 100 to 150mmHg, but it is capable of generating pressures above 200mmHg. Esophageal peristalsis squeezes the bite of food down toward the band and then progressively squeezes that bite across the band. Each bite must be squeezed across the band before the next bite starts to arrive. Figure 2 shows a bite in transit across the band.
A single bite of food, chewed well until it is mush, will move down the esophagus by peristalsis. At the level of the band, the esophageal peristalsis will squeeze that bolus of food across the band. It takes multiple squeezes (usually 2–6 squeezes or peristaltic waves) to get that bite of food across in a patient with a well-adjusted band (Figure 2).
Those squeezes generate a feeling of not being hungry and stimulate a message that passes to the hypothalamus to indicate that no more food is needed. If a single bite of food is able to generate between two and six waves of signal, a meal of 20 bites may generate 100 or more signals.
This is enough to satisfy a person and is enough to signal him or her to stop eating.
We recognize two terms for appetite control, satiety and satiation. Satiety refers to the background control of hunger that is present throughout the day regardless of eating. In the LAGB patient, satiety is generated by the band exerting a constant compression on the cardia. Satiation is the early control of hunger that comes with eating. In the LAGB patient, satiation is generated by the squeezing of the bolus of food across the band during a meal. Each squeeze adds to the satiation signal.
There are sensors in the cardia of the stomach that detect this squeezing. The exact nature of these sensors is still to be confirmed but they must be either hormonal or neural. We know that satiety and satiation are not mediated by one of the hormones currently known to arise from the upper stomach.[16] Ghrelin is a hormone that stimulates appetite. A number of hormones that can be derived from the cardia of the stomach are known to reduce appetite. None of these hormones are found to be raised in the basal state after gastric banding and none can be shown to rise significantly after each meal.[16]
Vagal afferents are plentiful in the cardia, and one group of afferents has a particular structure that lends itself to recognizing the compression of the gastric wall associated with squeezing of the bite of food across the band. In my opinion, the intraganglionic laminar endings, better known as IGLEs, are the most likely candidate as mediator of the background of satiety throughout the day and the early satiation after a meal.
The IGLEs lie attached to the sheath of the myenteric ganglia and are known to detect tension within the wall of the stomach. They are low-threshold and slowly adapting sensors and therefore are optimal for detecting continued compression of cardia of the stomach over a 24-hour period. The several squeezes that go with the transit of each bite stimulate the IGLEs further. The signal passes to the arcuate nucleus of the hypothalamus and the drive to eat is reduced.
The lower esophageal contractile segment. Burton developed the concept of the lower esophageal contractile segment (LECS). It is made up of four parts: the esophagus, the lower esophageal sphincter, the proximal stomach (including the 1cm or so above the band and the 2cm of stomach behind the band), and the band itself (Figure 3).
As the esophagus squeezes the bolus of food down toward the band, the lower esophageal sphincter relaxes as this peristaltic wave approaches. It then generates an after-contraction, which can maintain some of the pressure of the peristaltic wave as a part of the food bolus is squeezed into that small segment of upper stomach. The upper stoma*****luding the area under the band, is sensitive to these pressures. It generates signals to the hypothalamus.
These signals may be hormonal but are more likely to be neural. A correctly adjusted band will generate a basal intraluminal pressure of 25 to 30mmHg, providing a resistance to flow. The segment of the bolus that is squeezed through generates more signals from that area. Keeping the LECS intact is a key requirement for success with the gastric band. Bad eating habits (e.g., insufficient chewing, eating too quickly, taking bites that are too large) hurt the LECS. If those bad habits go on for long enough, stretching occurs and the power of peristalsis is lost, leading to the return of hunger (Figure 4).[11,12]
The Fine Art of Eating
A quality aftercare program is essential to successful weight loss in patients after LAGB. Before making the decision to proceed with LAGB in patients, I promise my patients three things: 1) to place the band in the optimal position safely and securely, 2) that they will have permanent access to a skilled aftercare program, and 3) that I will give them the information they need to obtain the best possible weight loss from the band. In return, I ask for three commitments from my patients: 1) that they follow the rules regarding eating after undergoing the procedure, 2) that they follow the rules regarding exercise and activity, and 3) that they always come back for follow up no matter how many years have passed.[6]
The “Eight Golden Rules.” At my facility, we summarized guidelines for eating after LAGB into what we call the “Eight Golden Rules” (Table 1). These rules are included in a book and DVD given to every patient who undergoes LAGB at the facility.[6] The rules are also posted on www.lapbandaustralia.com.au and are reinforced at most aftercare visits.
These eight golden rules must become part of each patient’s life. The effect of the LAGB procedure on hunger facilitates a patient’s adherence to the rules, making it more likely that he or she will follow them. However, achieving positive results with LAGB requires a working partnership between the physician and patient. Adhering to these rules is the patient’s part of the partnership, and he or she ultimately is responsible for the success or failure of weight loss following LAGB.
What to eat. After undergoing LAGB, patients should eat small amounts of “good food,” meaning food that is protein rich, of high quality, and in solid form. Each meal should consist of 125mL or 125g (i.e., about half of a cup of food). This measure of “half a cup” is a concept rather than a real measure of food, as some foods, such as vegetables and fruit, are composed largely of water and this has to be allowed for in some way. Thus, I allow exceeding the “half a cup” limit a little for vegetables and fruit.
We instruct patients to put each meal on a small plate and to use a small fork or spoon. The patient should not expect to finish all of the food on the plate, but rather he or she should plan to stop when he or she is no longer hungry. Any food left on the plate should be discarded.
Protein-rich foods. Protein is the most important macronutrient in the food a LAGB patient eats. At our clinic, we recommend that our patients consume approximately 50g of protein per day. We have measured protein intake of our patients (Table 2) and have monitored their blood levels. We have not seen any protein malnutrition after LAGB, indicating that a daily intake of about 50g a day is sufficient. Table 2 shows the energy and macronutrient intake of 129 consecutive patients measured before and at one year after LAGB. Note the mean energy intake is reduced by approximately 1500kcals.[17]
The best source of protein is meat; however, red meats, such as beef and lamb, tend to be difficult to break up with chewing in order to be sufficiently turned into mu**** is much easier to break up fish with chewing, and many fish are high in protein, including shellfish. Chicken, duck, quail, and other birds can also be cooked to be easily chewed to mush before being swallowed. Eggs and dairy, including cheese and yogurt, are also excellent protein sources.
For nonanimal sources of protein, a patient should consider lentils, chickpeas, and beans. Half of the “half a cup” allotment per meal should comprise protein-rich food. The other half should be made up of vegetables and/or fruits. I recommend to my patients that they eat more vegetables than fruit because vegetables have less sugar. Any space left in the “half a cup” can be used for the starches, (e.g., bread, pasta, rice, cereals, potatoes), though I recommend to my patients that they eat a minimal amount from this group of foods as they tend to provide no important nutritional benefit.
High-quality foods. High-quality food are foods that are minimally processed, natural, and whole. We encourage our patients to look for quality over quantity—for example, they might try sashimi-grade tuna, smoked salmon, duck breast, lobster, or even a simple poached egg. It is also important to remind your patients that there is no limit to the amount of herbs and spices that can be used to enhance the flavors of their foods.
Solid foods. The patient should choose solid foods over liquids whenever possible. Liquids pass too quickly across the palate and, more importantly, too quickly across the band. There is no need for the esophagus to squeeze liquid, and without the squeeze, there is no stimulation of the IGLEs and no induction of satiety; therefore, eating calorie-containing liquids may negatively impact a patient’s weight loss.
When to eat. After undergoing LAGB, a patient should eat three or less times per day. If the patient is in the green zone, meaning that the band is adjusted correctly, there should be no need for him or her to eat between meals. In fact, even three meals a day may be more than needed for satiety. In my experience, patients have little interest in eating in the morning. By late morning or early afternoon, patients may start to notice some hunger, which indicates that it is time to have a first small meal. In the evening, patients may have another meal. Most importantly, patients should be instructed that a meal missed is not to be replaced later on. The typical human body is satisfied with a maximum of three meals per day but often is happy to accept two or even one meal per day.
Patients should be reminded that there should be no snacking between meals. If a patient finds that he or she is hungry by late afternoon, encourage him or her to eat something small and of high quality, such as a piece of fruit or some vegetables, just to tide him or her over until the evening meal. The patient should then visit the clinic to check whether or not he or she is in the Green Zone. It is important that the patient adhere to the aftercare program to monitor whether or not he or she is in the green zone. If not in the green zone, the patient will need to have fluid in the band increased or decreased.
How to eat. Take a small bite and chew well. The “half a cup” of food should be placed on a small plate. The patient should use a small fork or a small spoon to eat. A single bite of food should be chewed carefully for 20 seconds. This provides the opportunity to reduce that bite of food to mu**** also provides the important opportunity for the patient to actually enjoy the taste, the texture, and the flavor of the food. Encourage your patients to enjoy eating more than they ever have. After chewing the food until it is mush, the patient should swallow that bite.
Swallow, then wait a minute. The patient must wait for that bite to go completely across the band before swallowing another bite. Normally, it will take between two and six peristaltic waves passing down the esophagus, which can take up to one minute. This is probably the biggest challenge of educating the patient who has undergone LAGB. You must instruct the patient to eat slowly—chew well, swallow, and then wait one minute.
A meal should not go on for more tha