RU2675999C1 - Method for determining the "weight plato" phenomenon during diet therapy for obesity - Google Patents

Abstract

FIELD: medicine.SUBSTANCE: invention relates to medicine and can be used to determine the phenomenon of "weight plateau" in the course of diet therapy for obesity. Measure the body weight of the patient once a week during the entire course of diet therapy. Calculate the difference in weight loss from week to week. When the difference in weight loss for two consecutive weeks is less than 0.2 kg, the level of actual basal metabolism is measured using indirect calorimetry or bio-impedance analysis. Determine the normal body weight of the patient according to the Brock-Brugsch formula. Calculate the X value (%) of excess of body weight over normal body weight according to the stated formula, rounding it up to the nearest number divisible by 5. Calculate the level of normal basal metabolism according to the Harris-Benedict formula for men and for women. According to the gender tables 1 and 2 contained in the description, a sigma corridor is determined for the calculated Y value in relation to σ and 2σ in accordance with the previously obtained value of X. Give a conclusion about the presence of a "weight plateau", if the desired value of Y is less than μ-2σ.EFFECT: method allows you to accurately determine the true phenomenon of "weight plateau" in the course of diet therapy for obesity due to the evaluation of the complex of the most significant parameters.1 cl, 2 tbl, 2 ex

Description

The invention relates to medicine and can be used to determine the phenomenon of "weight plateau" during diet therapy for obesity.

"Weight plateau" is a pronounced stop in weight loss during the treatment of obesity, which limits the possibility of prolonged weight loss. It is important to identify it in a timely manner for the correction of subsequent diet therapy. The phenomenon of “weight plateau” can be true - due to changes in the magnitude of the main metabolism, and it can be false - due to insufficient patient compliance with the prescribed dietary recommendations.

There is a method of assessing the phenomenon of "weight plateau", according to which the patient’s body weight is measured once a week during the entire course of diet therapy, the difference in weight loss from week to week is calculated; if the difference in weight loss over two consecutive weeks is less than 0.2 kg, then a “weight plateau” is diagnosed (1). The disadvantage of this method is that it does not take into account the dynamics of the basal metabolism, and, therefore, does not reveal the truth or falsehood of the "weight plateau", and gives an evaluation criterion in absolute values, which is unacceptable for patients with different degrees of obesity. This method is taken as a prototype.

It is worth noting that the exact formulaic methods for determining the phenomenon of "weight plateau" are currently not known.

The aim of the invention was to determine the true phenomenon of "weight plateau" during diet therapy for obesity.

This goal is achieved by the fact that when the difference in weight loss for two consecutive weeks is less than 0.2 kg, the level of actual basal metabolism (OO _fact , kcal / day) is measured using indirect calorimetry or bioimpedance analysis; determine the normal body weight of the patient (MT _norms , kg) according to the Brock-Brugsch formula; calculate the value X (%) of the excess of MT _fact over MT _norms by the formula: X = (MT _fact –MT _norms ) × 100 / MT _norms , rounding it to the nearest multiple of 5; calculate the level of normal basal metabolism (OO _norms , kcal / day) according to Harris-Benedict formulas: for men OO _norms = 66.5 + (13.7 × MT _norms ) + (5 × P) - (6.8 × V ), for women, OO _norms = 655 + (9.6 × MT _norms ) + (1.8 × P) - (4.7 × B), where P is height (cm), B is age (years); calculate the value of Y - the difference between OO _norms and OO _fact by the formula: Y = (OO _fact -OO _norms ) × 100 / OO _norms ; determine the sigmal corridor for the calculated value of Y in relation to σ and 2σ in accordance with the previously obtained value of X from the gender tables; give a conclusion on the presence of a “weight plateau” if the desired value of Y is less than μ-2σ.

The present method was developed by us as a result of the study. The sample used data from 54 women and 54 men aged 20 to 60 years (in increments of 5 years). At the first stage of creating the method, the basis was the Harris-Benedict formula (4) for calculating the basal metabolism, while taking into account gender, weight (kg), height (cm) and age (years). For men and women, the tables were displayed separately. Normal weight was calculated on the basis of height and age using the Brock-Brugsch formula (5). The growth was average for the European population of men (160-185 cm, step 5 cm) and women (155-180 cm, step 5 cm). The excess weight was calculated by the weight norm from 5 to 100% in increments of 5%, which allowed us to obtain the value X (%) of the excess of MT _fact over MT _norms . Accordingly, each theoretical anthropometric version had its own main exchange according to the Harris-Benedict formula (both at the norm of weight and at each percent excess).

The next step was to determine how much the OO _fact in the cases of excess weight differs from the OO of the _{norms of the} norm of weight in each particular case of gender, height and age. This value was designated Y.

At the final stage, the sample means μ and the sample standard deviations σ were calculated from the Y value for each case of excess body weight, since this set is symmetric. The development of the formula for calculating the reference points for determining the “weight plateau” was carried out in the Microsoft Office application package (MS Excel) using the embedded formula capabilities. Statistical values of Y with sigmal corridors μ ± σ and μ ± 2σ represent the recommended intervals of the fraction of the difference in the comparison of the formula-based OO _norms when calculating due weight with the OO _fact data obtained in fact in practical dietetics using indirect calorimetry or bioimpedance analysis, respectively, for men and women. Based on the calculated values, the following gender tables were formed: “Recommended difference between the calculated and actual basic exchange for determining the presence of a“ weight plateau ”for men” (table 1) and “Recommended difference between the calculated and actual basic exchange for determining the presence of a“ weight plateau ”for women” (table 2).

Based on the study, we came to the conclusion that the value of Y, falling into the sigmal corridor μ ± σ, indicates normal values of the basal metabolic rate, in the corridor from μ-σ to μ-2σ and from μ + σ to μ + 2σ - to allowable deviations. Values of Y below μ-2σ confirm an undesirable slowdown in basal metabolism, which may serve as a criterion for determining the true “weight plateau” in a patient.

The result of the implementation of this method is the minimization by practitioners of substantiated difficulties in establishing the truth or falsehood of the phenomenon of "weight plateau"; there are still no clear boundaries for determining this state. The proposed method is diagnostic and can clearly help the attending physician exercise proper control of the patient’s main metabolism and timely adjust the design of dietetic treatment.

The method is implemented as follows:

If the difference in weight loss for two consecutive weeks is less than 0.2 kg, the level of actual basal metabolism (OO _fact , kcal / day) is measured using indirect calorimetry or bioimpedance analysis; determine the normal body weight of the patient (MT _norms , kg) according to the Brock-Brugsch formula; calculate the value X (%) of the excess of MT _fact over MT _norms by the formula: X = (MT _fact –MT _norms ) × 100 / MT _norms , rounding it to the nearest multiple of 5; calculate the level of normal basal metabolism (OO _norms , kcal / day) according to Harris-Benedict formulas: for men OO _norms = 66.5 + (13.7 × MT _norms ) + (5 × P) - (6.8 × V ), for women, OO _norms = 655 + (9.6 × MT _norms ) + (1.8 × P) - (4.7 × B), where P is height (cm), B is age (years); calculate the value of Y - the difference between OO _norms and OO _fact by the formula: Y = (OO _fact -OO _norms ) × 100 / OO _norms ; determine the sigmal corridor for the calculated value of Y in relation to σ and 2σ in accordance with the previously obtained value of X from the gender tables; give a conclusion on the presence of a “weight plateau” if the desired value of Y is less than μ-2σ.

The method is demonstrated by clinical examples:

Example 1

Patient A., 31 years old (B), height (P) 160 cm, body weight (MT _fact ) 83.5 kg, undergoes a course of diet therapy for obesity II tbsp. Over the past 2 consecutive weeks, body weight decreased less than 0.2 kg, and therefore it was decided to diagnose the presence of a "weight plateau". Indirect calorimetry was used to determine the main OO exchange of _{fact of} 1435 kcal / day.

The normal body weight MT _norms for this patient according to the Brock-Brugsch formula is 60 kg; the value X of the excess of the MT _fact over the MT _norms by the formula (83.5-60) × 100/60 = 39.2% (we round to the nearest multiple of 5 - in this case, the number 40).

According to the calculation according to the Harris-Benedict formula, the OO of the _norms should have been equal to: 655+ (9.6 × 60) + (1.8 × 160) - (4.7 × 31) = 1373.3 kcal / day.

The value Y of the difference in the OO _fact from the OO _norms according to the formula: Y = (1435-1373.3) × 100 / 1373.3 = 4.5. In the gender table (for women) in line 40 we find the corresponding sigmal values for μ ± σ and μ ± 2σ.

The permissible difference in OO _fact and OO _norms can be no lower than 15.5 for μ-2σ, and in fact we have 4.5, which is less - which means that at this stage of therapy this patient has a significant decrease in basal metabolism. Thus, the true “weight plateau” is confirmed and nutritional correction is recommended. Against the background of the modification of diet therapy over the next 4 weeks, body weight decreased by about 0.5 kg per week, which confirmed the accuracy of the diagnostic search and the taken therapeutic measures.

Example 2

Patient N., 27 years old (B), height (P) 187 cm, body weight MT _fact 105 kg, undergoes a course of diet therapy for obesity II tbsp. Over the past 2 consecutive weeks, body weight decreased less than 0.2 kg, and therefore it was decided to diagnose the presence of a "weight plateau". Using bioimpedance analysis, the main exchange of OO _fact 2244 kcal / day was determined.

The normal body weight MT _norms for this patient according to the Brock-Brugsch formula is 77 kg; the value X of the excess of MT _fact over MT _norms according to the formula (105-77) × 100/77 = 36.4% (we round to the nearest multiple of 5 - in this case, this number is 35).

According to the calculation according to the Harris-Benedict formula, the OO of the _norms should be equal: 66.5+ (13.7 × 77) + (5 × 187) - (6.8 × 27) = 1872.8 kcal / day.

The Y value of the difference in the OO _fact from the OO _norms according to the formula: Y = (2244-1872.8) × 100 / 1872.8 = 19.8. In the gender table (for men) in line 35 we find the corresponding sigmal values for μ ± σ and μ ± 2σ.

The permissible difference between the OO _fact and the OO _norms can be no lower than 18.2 for μ-2σ and 19.4 for μ-σ, but in fact we have 19.8, which is in the sigmal corridor μ ± σ - which means that at this stage of therapy this patient has no decrease in basal metabolic rate. Thus, the true “weight plateau” is excluded and no nutritional correction is required, however, the results indicate insufficient patient compliance with the prescribed dietary recommendations (false “weight plateau”), and there is a need for situational psychological support. Against the background of previous diet therapy and connected psychotherapy, over the next 4 weeks, body weight decreased by about 0.4 kg per week, which confirmed the accuracy of the diagnostic search and the taken therapeutic measures.

The method for determining the phenomenon of "weight plateau" during diet therapy for obesity helps to establish its truth or falsehood, which dictates the need for appropriate corrective therapeutic measures. It can be used in therapeutic, endocrinological and nutritional practice.

Literature

1. Ginzburg M.M., Kozupitsa G.S., Kryukov N.N. Obesity and metabolic syndrome (Impact on health status, prevention and treatment). - Samara, 1999 .-- 51 p. (S. 51).

2. Snow M. Nutritional Assessment with Indirect Calorimetry. Guideline - Medgraphics, 2007. - 20 p.

3. Nikolaev D.V., Smirnov A.B., Bobrinskaya I.G., Rudnev S.G. Bioimpedance analysis of the composition of the human body. - M .: Nauka, 2009 .-- 392 p.

4. Harris J.A., Benedict F.G. A biometric study of basal metabolism in man. - Washington, D.C .: Carnegie Institute, 1919. - P. 279.

5. The formula for ideal weight // Wefit [Electronic resource]. - URL: http://wefit.ru/formula-idealnogo-vesa/.

Claims (4)

A method for determining the phenomenon of "weight plateau" during diet therapy in obesity, which includes measuring the patient’s body weight (MT _fact , kg) once a week for the entire course of diet therapy, calculating the difference in weight loss from week to week, characterized in that the difference in weight loss over two consecutive weeks of less than 0.2 kg measure the level of actual basal metabolism (OO _fact , kcal / day) using indirect calorimetry or bioimpedance analysis; determine the normal body weight of the patient (MT _norms , kg) according to the Brock-Brugsch formula; calculate the value X (%) of the excess of MT _fact over MT _norms by the formula: X = (MT _fact –MT _norms ) × 100 / MT _norms , rounding it to the nearest multiple of 5; calculate the level of normal basal metabolism (OO _norms , kcal / day) according to Harris-Benedict formulas: for men OO _norms = 66.5 + (13.7 × MT _norms ) + (5 × P) - (6.8 × V) , for women, ОО _norms = 655 + (9.6 × MT _norms ) + (1.8 × Р) - (4.7 × В), where Р - height (cm), В - age (years); calculate the value of Y - the difference between OO _norms and OO _fact by the formula: Y = (OO _fact -OO _norms ) × 100 / OO _norms ; from the gender tables 1 and 2 contained in the description, determine the sigmal corridor for the calculated value of Y in relation to σ and 2σ in accordance with the previously obtained value of X; give a conclusion on the presence of a “weight plateau” if the desired value of Y is less than μ-2σ.