NO763227L - ELECTROLITE MIXTURES AND BEVERAGES. - Google Patents

Description

Electrolyte mixtures and drinks.

The present invention relates to powder mixtures which can be reconditioned with water to form electrolyte drinks. The invention relates more particularly to flavoured, powder mixtures which can be reconditioned with water to form flavoured, hypotonic drinks which are characterized by rapid gastric emptying in the system whereby good availability of water and electrolytes in the system is achieved.

Such drinks are desired by all people who have undergone exercise, strenuous work or activity, but are particularly recommended for sportspeople who are busy in all sports and competitions. Athletes are particularly susceptible to training and warm-up difficulties, especially those who are not in top physical condition. The reason for such disturbances can be traced directly to dehydration and loss of electrolytes from the body. During training or competition, body activity increases greatly and this results in warming up. Only about 25% of the energy that is developed is converted into useful work, with the remaining 75% being developed as body heat and 80-90% of this body heat is lost by evaporation of sweat. Since regulation of body temperature precedes the maintenance of water and salt balance, sweating will occur and continue in an attempt to maintain normal body temperature and this can result in dehydration and clear electrolyte loss. The most important electrolytes affected are sodium, potassium, chloride and phosphate ions. It is not unusual for an athlete to lose approx. 5% of body weight during two football training sessions in one day.

As a result of these impacts on the body, three common training and warm-up related disorders can occur; heat cramps, heat exhaustion and/or heat stroke. Heat cramps are characterized by painful skeletal muscle contractions and are the result of large sodium and chloride ion losses in both the sweat and urine and a possible potassium ion deficit.

Heat exhaustion occurs when loss of water and salts is high, and results in a drop in blood pressure, low cardiac output and a high heart rate due to the decrease in blood volume and extra cellular fluid. The reduction in blood circulation leads to a rise in body temperature as the distribution of heat becomes more difficult. Cell metabolism is disturbed when large amounts of water and potassium ions are lost from the cells. This loss of water and potassium ions is critical because potassium is necessary for the maintenance of cardiac muscle and skeletal muscle fiber tonicity. Heat exhaustion symptoms include profuse sweating, fatigue, vomiting and fainting, all of which can occur when weight loss is around 5% of body weight or more.

Heat stroke is the most dangerous form of heat or heat injury. It is the result of high body temperatures in the range of 40.6 - 41.1°C and is classified as a medical emergency. At these temperatures, the heat regulation mechanism in the brain ceases due to cell damage which can become permanent if the temperature is not reduced quickly. Heat stroke symptoms include headache, lethargy, dizziness and dry skin. When the loss in body weight exceeds 10%, there is a high chance of circulatory failure and death. The body temperature must be reduced as quickly as possible and fluids should be administered intravenously and orally if possible.

These and other physical disturbances have long been regarded as highly undesirable effects of strenuous exercise or sports, and various methods have been proposed to reduce the danger in such cases, including the achievement of adequate physical fitness and the use of appropriate clothing and/or protective equipment . In recent years, the accepted rule that one should not drink large amounts of liquid to quench thirst during or immediately after vigorous activity has been questioned, and this has led to the introduction of various "thirst-quenchers" or so-called "electrolyte"- drinks. The purpose of such products is to return water and electrolytes to the system. The available products have serious shortcomings when it comes to fully satisfying this purpose. Some products are e.g. composed in such a way that their transfer from the stomach to the bloodstream is quickly prevented, while other preparations are inedible or leave a bitter aftertaste that results in one refusing rather than wanting to utilize such products, and one thus achieves insufficient amounts of water and electrolytes to replace the amounts that have been lost.

It is therefore an object of the invention to provide a dry mixture suitable for reconditioning with water into a drink which negates the above-mentioned negative aspects of the products that have been available up to now.

Another object is to arrive at a dry mixture suitable for reconditioning with water into a hypotonic drink, and which mixture is characterized by rapid gastric emptying resulting in rapid availability of water and electrolytes in the body.

A further object of the invention is to provide a dry mixture suitable for reconditioning with water into a flavoured, hypotonic drink with a relatively low content of sweeteners and with a satisfactory taste.

Another object is to provide a reconstituted flavored hypotonic beverage.

Other purposes and advantages of the present invention will be apparent to the person skilled in the art from the following description and examples.

According to the invention, the above-mentioned purposes and advantages are achieved by providing a dry mixture suitable for reconditioning with water or a reconditioned hypotonic drink comprising specific amounts of salt electrolytes and sweeteners and with a specific osmolality.

According to the invention, dry mixtures are produced which are suitable for reconditioning with water for hypotonic drinks.

An important characteristic of the drinks according to the invention is the drinks' tonicity or their so-called osmolality. In the following, these designations will be used interchangeably. Tonicity is a measure of the osmotic pressure of a solution in relation to the osmotic pressure of the blood fluids. An isotonic solution is a solution with the same tonicity (osmotic pressure) as a normal saline solution and therefore has the same tonicity as blood serum. A hypertonic solution is a solution with a higher tonicity than an isotonic solution, while a hypotonic solution is a solution with a lower tonicity than an isotonic solution. It has now been unexpectedly found that the tonicity of electrolyte drinks is particularly critical with respect to providing rapid gastric emptying or carrying the solution from the stomach into the blood stream. It thus appears that the tonicity (osmolality) of any drink in solution is directly related to the rate at which such a solution can be transported from the stomach to the bloodstream. Most commercially available electrolyte drinks are either isotonic or hypertonic and tend to be carried out or emptied relatively slowly from the stomach. In addition to the low availability of the necessary water and electrolytes in the body, the slower emptying or removal from the stomach also results in more fluid remaining in the stomach of those affected who must have a rapid intake of fluid, and this reduces the desire to consume additional fluid which in turn results in losing the opportunity for necessary water and electrolytes to enter the system to replace what has been lost as a result of sweating.

It has now unexpectedly been found that an osmolality of from approx. 80 to approx. 200 mOsm per liters to achieve the emptying or discharge of the solutions from the stomach into the blood stream in a rapid manner to provide the necessary electrolytes and water in the system. A preferred osmolality is from approx. 90 to approx. 130 mOsm. Most commercially available products have osmolalities significantly higher than these levels.

It has been found that by regulating the amount of electrolytes found in the mixtures according to the present invention and by limiting the amounts of sweeteners added to such mixtures, the osmolality of the resulting solutions can be maintained within the desired levels and thereby result in rapid gastric emptying and rapid availability of water and electrolytes in the system. It has also been found that by using amounts of sweeteners below what is normal in such mixtures, the osmolality of the resulting solutions can be regulated so that the rate of gastric emptying is not adversely affected while at the same time obtaining a good drink without a bitter taste.

The dry compositions according to the invention which are suitable for reconditioning with water should contain sodium, potassium, chloride and phosphate ions as electrolytes in amounts sufficient to provide suitable re-introduction of the normal levels of these components in the body as well as a specific amount of suitable sweeteners as well as citric acid, suitable flavorings and colourings. The sodium and potassium salts which are suitable for use in the present invention can e.g. be chlorides, citrates or phosphates, although it is desirable that at least some of these salts are chlorides and phosphates, because these would give chloride and phosphate ions in addition to adding sodium and potassium ions.

In order to achieve the object of the present invention, it is necessary that the electrolytes are present in specific amounts. The sodium ions should be found in the range from approx. 10 to approx. 3 5 mEq per litres, the potassium ions in the range from approx. 0.5 to approx. 20 mEq per litres, the chloride ion in the range from approx. 10 to approx. 35 mEq per liter and the phosphate ion in the range from approx. 1 to approx. 15 mEq per litres. Problems can arise if amounts of these electrolytes are used outside the given ranges; e.g. if an elevated sodium ion content is present in the dry mixture, the resulting solution will have a salty taste and may cause stomach irritation. If too much chloride ions or phosphate ions are present in the dry mixture, taste problems can occur with the resulting solutions.

The sweeteners that can be used in the present invention include both naturally occurring and artificial or non-caloric sweeteners. The naturally occurring sweeteners include sugars such as glucose, sucrose, lactose, maltose and the like. The total concentration for the naturally occurring sweeteners should be from approx. 1 to approx. 54 m. mol per liter because if amounts above 54 m.mol per liters is used, an unfavorable osmolality will be obtained. Glucose can thus e.g. used in an area from approx. 0 to approx. 10 g/litre and sucrose in the range from approx. 0 to approx.

20 g/litre as long as the total concentration is not exceeded

about. 54 m.mol per litres.

Parts of natural sweeteners can be replaced with artificial or low-calorie sweeteners such as saccharins, cyclamates, dipeptides such as "Aspartame" and the like. In particular, sodium or calcium saccharin can be used instead of some of the natural sweetener to provide the desired degree of sweetness without adversely affecting the osmolality, although using too much artificial sweetener can cause taste problems in the resulting drink.

It should be borne in mind that choosing the quantities of the above-mentioned components to be used requires a balance between the special features that are desired to be achieved. For example, to maintain the osmolality within the specific range to achieve rapid gastric emptying or excretion into the system, the amount of sweeteners must be limited and yet sufficient amounts must be used to provide a pleasant tasting beverage. If thus excess chloride or phosphate ion is used, taste problems may occur and this may result in the need for additional flavoring substances which may have an adverse effect on osmolality. The amounts of the necessary components in the mixtures according to the invention must therefore be carefully kept within the limits indicated above to achieve the desired results.

Other components which can be used in the mixtures and drinks according to the invention include such components which are normally found in such preparations, such as citric acid or salts thereof, ascorbic acid, flavourings, coloring agents and the like. The citric acid can be present in the range of from approx.

0 to 10 g/liter and is used as an adjuvant to develop the flavor of the mixture and the resulting beverage. Ascorbic acid is a source of vitamin C which is desirable. Flavors such as citrus flavor, e.g. orange, lemon, lemon-lime and the like,

and non-citrus flavors, e.g. strawberry, punch and the like, and colorants such as "FD&C" approved colors, e.g. "FD&C Red #40" and "FD&C Yellow #5" can be used to achieve the desired flavor and color in the resulting beverage.

The mixtures according to the invention can be prepared by ordinary mixing using standard equipment. The components are ground to a suitable size and are then mixed together in the required quantities to form the mixtures which can then be reconditioned with water as desired.

Special embodiments of the invention are illustrated in the representative examples given below.

Example I

A powder mixture according to the invention with an orange flavor was produced by grinding the components through a No. 4 sieve and then mix the components for about 10 min. in an "ABBE" mixer to obtain a dry mixture with the following composition:

Example II

A punch flavored powder mixture was prepared as indicated in Example I and had the following composition:

62.5 g of this mixture is reconstituted with 3.8 liters of water and a hypotonic drink with a pleasant punchy taste is then obtained.

Example III

The composition of Example I and four commercially available "thirst quenching" beverages designated A, B, C and D were reconstituted according to stated instructions. These drinks were then analyzed for sodium and potassium ion content by flame photometer, and for chloride ion content by potentiometric titration. The natural sweetener content was determined using standard glucose oxidation methods and the osmolality of each of the solutions was determined using the freezing point depression method. The results from these analyzes are shown in the table below

IN:

Although other compositions give similar amounts of sodium, potassium and chloride ions, it appears from the above results that only solution E, namely the composition from Example I, gives a low sugar concentration and an osmolality in the desired range for achieving the desired rapid gastric emptying of the solution resulting in rapid availability of water and electrolytes in the body.

Example IV

In order to demonstrate the rapid gastric emptying of the solutions of the present invention, resulting in the rapid availability of water and electrolytes in the body, the following experiments were performed. Six men ingested 400 ml of the solutions from example III as well as 400 ml of water, and the gastric residue was measured by inserting a tube into the stomach and removing the liquid that was there for 15 min. later, to determine the volume that was f emptied from1 the stomach. The results are set out in Table II below:

As can be seen from the above-mentioned results, the solution from example I, according to the invention, is depleted significantly faster than the commercially available electrolyte drinks A, B, C and D, and even faster than water alone. It is thus clear that the solutions according to the invention unexpectedly provide water and electrolytes in the body faster than known available products, and this, as mentioned above, is very desirable.

Claims (16)

1. Dry powder mixture suitable for reconditioning with water to form a hypotonic drink, characterized in that it comprises sodium ions, potassium ions, chloride ions and phosphate ions, as well as sweeteners, and in that it has an osmolality of from approx. 80 to approx. 200 mOsm. 2. Mixture according to claim 1, characterized in that the sodium ion content is from approx. 10 to approx. 35 mEq per litres, the potassium ion content from approx. 0.5 to approx. 20 mEq per litres, the chloride ion content from approx. 10 to approx. 35 mEq per litres, and that the phosphate ion content is from approx. 1 to approx. 15 mEq per litres. 3. Mixture according to claim 1, characterized in that the sweeteners are selected from the group consisting of naturally occurring and artificial or low-calorie sweeteners. 4. Mixture according to claim 3, characterized in that the sweetener is a naturally occurring sweetener. 5. Mixture according to claim 4, characterized in that the sweetener is selected from the group consisting of sucrose, glucose and mixtures thereof. 6. Mixture according to claim 1, characterized in that the sweetener is present in the range from approx. 1 to approx. 54 m.mol per litres. 7. Mixture according to claim 1, characterized in that the osmolality is from approx. 90 to approx. 130 mOsm. 8. Dry powder mixture suitable for reconditioning with water to form a hypotonic drink, characterized in that it comprises from approx. 10 to approx. 35 mEq per liter of sodium ion, from approx. 0.5 to approx. 20 mEq per liter of potassium ion, from approx. 10 to approx. 35 mEq per liter of chloride ion, from approx. 1 to approx. 15 mEq per liter phosphate ion and from approx. 1 to approx. 54 m.mol per liter of sweetener, and that it has an osmolality of from approx. 80 to approx. 200 mOsm. 9. Mixture according to claim 8, characterized in that the sweeteners are selected from the group consisting of naturally occurring and artificial or low-calorie sweeteners. 10. Hypotonic drink, characterized in that it comprises water and sodium ions, potassium ions, chloride ions and phosphate ions and sweeteners, and that it has an osmolality of from approx. 80 to approx. 200 mOsm. 11. Drink according to claim 10, characterized in that the sodium ion content is from approx. 10 to approx. 35 mEq per litres, the potassium ion content from approx. 0.5 to approx. 20 mEq per litres, the chloride ion content from approx. 10 to approx. 35 mEq per liter and that the phosphate ion content is from approx. 1 to approx. 15 mEq per litres. 12. Drink according to claim 10, characterized in that the sweeteners are selected from the group consisting of naturally occurring and artificial or low-calorie sweeteners. 13. Drink according to claim 12, characterized in that the sweetener is a naturally occurring sweetener. 14. Drink according to claim 13, characterized in that the sweetener is selected from the group consisting of sucrose, glucose and mixtures thereof. 15. Drink according to claim 10, characterized in that the sweetener is present in amounts of from approx. 1 to approx. 54 m.mol per litres. 16. Method for rapid administration of water and electrolytes to the body, characterized in that one administers a hypotonic drink comprising essentially from approx. 10 to approx. 35 mEq per liter of sodium ion, from approx. 0.5 to approx. 20 mEq per liter of potassium ion, from approx. 10 to approx. 35 mEq per liter of chloride ion, from approx. 1 to approx. 15 mEq per liter phosphate ion and from approx. 1 to approx. 54 m.mol per liter of sweetener, and which drink has an osmolality of from approx. 80 to approx. 200 mOsm.