RU2297792C1 - Method for establishing normative values of pulmonary ventilation function in practically healthy people - Google Patents

Abstract

FIELD: medicine, anthropometry, functional diagnostics, valeology.

SUBSTANCE: the present innovation deals with elaborating specified diagnostic criteria of the standard. Normative values of pulmonary ventilation function in practically healthy people should be established due to carrying out anthropometric survey. According to the data of the above-mentioned survey it is necessary to conduct somatotyping in males and females by 7 somatic types: nanosomal, microsomal, micromesosomal, mesosomal, macromesosomal, macrosomal and megalosomal. Then comes spirographic testing to detect: VCexp, FVCexp, FEV1/FVC and other parameters. Normative values of pulmonary ventilation function should be determined due to static processing of the obtained data, spirographic testing due to taking into account somatotyping, moreover, the standard for pulmonary ventilation function should be established for the concrete somatic type based upon the complex of spirographic values. The innovation enables to predict optimal state of pulmonary ventilation function in practically healthy people who are the representatives of the concrete somatic type.

EFFECT: higher efficiency.

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Description

The invention relates to medicine, namely to anthropometry, functional diagnostics, valeology, and is intended to develop refined diagnostic criteria for the norm. It will find application in medical and preventive work to establish normative indicators of the ventilation function of the lungs taking into account somatic types, to predict the optimal state of the ventilation function of the lungs in practically healthy people belonging to different somatic types.

Currently, an in-depth approach to the differentiation of norms and borderline conditions has necessitated a more clear definition of human normative indicators. This, in particular, refers to the normative indicators of the ventilation function of the lungs, which are traditionally established depending on the gender, age, height and body weight of the examined. However, taking into account the peculiarities of the biomechanics of breathing, the ventilation function of the lungs is largely determined by the somatotypic characteristics of a person (the severity of fat, muscle and bone mass of the human body; the perimeter of the chest).

The method allows the ratios of somatic types and indicators of ventilation function of the lungs to establish the normative indicators of ventilation function of the lungs taking into account somatic types and to predict the optimal state of ventilation function of the lungs in practically healthy people belonging to a specific somatic type.

The well-known "Method of assessing the optimal physical development of adolescent youths" (RF patent No. 2162295, IPC AB 5/00, publ. 01/27/2001), in which the optimality of physical development is assessed by the magnitude and ratio of the parameters of the absolute fat and absolute muscle mass of the body and predict level of physical performance.

Also known is the “Method of measuring lung compliance” (RF patent No. 2206264, IPC AB 5/08, publ. 06/20/2003), which allows for correct comparison of respiration mechanics in different groups of patients with various pathologies.

The well-known "Method for determining the biological age of a person" (RF patent No. 2228137, IPC AB 5/16, publ. 05/10/2004), in which anthropometric indicators are measured at all stages of ontogenesis and the biological age of various groups of people is determined by the derived formula.

However, the known methods do not solve the problem of establishing standards for ventilation function of the lungs of practically healthy people.

The well-known "Method of assessing the level of health of a student" (patent No. 2251962, IPC AB 5/00, 5/02, publ. 05/20/2005), which is selected as a prototype.

Pupils determine the weight and length of the body, the vital capacity of the lungs, systolic and diastolic blood pressure, and pulse recovery time after performing a standard load of PWC ₁₇₀ . The anthropometric indicator is calculated as mass / body length, the ventilation indicator as the lung capacity / body weight, cardiac index, specific performance as dynamometry / body weight, and the reserve indicator as the pulse recovery time after exercise. Each symptom is evaluated in points, the points obtained are summarized, and the level of health is estimated by the sum of the points.

The task of the invention is the development of diagnostic criteria for normal rates of ventilation function of the lungs and predicting its optimal condition, taking into account somatic types.

The stated objective is achieved by conducting an anthropometric and spirographic examination of practically healthy people, followed by somatotyping of men and women according to seven somatic types and on the basis of a set of registered spirographic indicators, shown in Tables 1 and 2, establish the norm of ventilation function of the lungs taking into account the specific somatic type .

The proposed method is as follows.

The method is based on the results of a survey of 167 practically healthy people (63 men and 104 women) aged 17-22 years, related to youthful and first adulthoods (in accordance with the age periodization recommended by the All-Union Symposium of the USSR Academy of Medical Sciences, Moscow, 1965 and the congress anthropologists, 1975).

The survey was conducted on the basis of the Department of Normal Anatomy of Rostov State Medical University (Rostov State Medical University) and the Department of Cardioreheumatology and Functional Diagnostics Rostov State Medical University, as well as the Department of Functional Diagnostics of the Rostov State Medical University clinic.

Anthropometric examination and somatotyping was carried out according to the methodology of Dorokhov R.N., Petrukhina V.G. (1989) (Dorokhov R.N., Petrukhin V.G. Methods of somatotyping children and adolescents // Medical and pedagogical aspects of training young athletes. - Smolensk, 1989. - S.4-14.). This methodology involves assessing the dimensions of an individual or determining the overall level of variation (HEM), the assessment of component (HEM) and proportional (HEM) levels of variation. During the examination, a standard anthropometric technique was used using the following equipment: a vertical anthropometer (a device for measuring the height of individual body points above the floor, accuracy up to 1 mm), standard medical scales (accuracy up to 10 g), caliper with a standard pressure of 10 g / mm square ( accuracy up to 0.1 mm), a centimeter medical tape (accuracy up to 0.1 mm), a sliding metal compass (accuracy up to 1 mm).

The examination was carried out in the morning in a special anthropometry office.

When assessing the overall level of variation (HUV), body length (DT) and body weight (MT) were measured. To assess the component level of variation (CV), the severity of fat (BM), muscle (MM) and bone (BM) body mass was determined. To assess the proportional level of variation (PUV), the length of the lower limb was determined.

After carrying out metric measurements, the overall level of variation (GUV) was estimated using special tables (Dorokhov R.N., Petrukhin V.G. Methods of somatotyping children and adolescents // Medical and pedagogical aspects of training young athletes. - Smolensk, 1989. - P. 4-14.), Allowing on the basis of DT and MT to determine the somatic type of the examined according to the GUV by the formula:

{(DT-Sdt) / Ddt + (MT-Smt) / Dmt} / 2,

where DT is the length of the body,

MT - body weight

SDT - the value of C for the length of the body,

DDT - the value of D for body length,

Smt - the value of C for body weight,

Dmt is the value of D for body weight.

The values of the values Sdt, Ddt, Smt, Dmt are given in additional tables (Dorokhov R.N., Petrukhin V.G. Methods of somatotyping children and adolescents // Medical and pedagogical aspects of training young athletes. - Smolensk, 1989. - P. 4- 14.) (in the line corresponding to the age of the examined one must find the values of C and D separately for length and body weight).

The technique makes it possible to differentiate between nanosomal (NaC), microsomal (MiC), micromesosomal (MiMeS), mesosomal (MeC), macromesosomal (MaMeS), macrosomal (MaC), and megalosomal (MeGS) somatic types.

Then, the component level of variation (CWV) of the subjects was evaluated, thereby determining the severity of fat (BM), muscle (MM) and bone (KM) body mass, and the proportional level of variation (PUV) of the subjects was evaluated, determining the length of the lower limb. The calculations were carried out according to special tables and formulas (Dorokhov RN, Petrukhin VG Methods of somatotyping children and adolescents // Medical and pedagogical aspects of training young athletes. - Smolensk, 1989. - S.4-14.).

To determine diagnostic criteria for norm indicators of lung ventilation function and to predict the state of lung ventilation function, taking into account the characteristics of the somatic type according to the method of Dorokhov RN, Petrukhina VG (1989) took into account indicators of the overall level of variation (GUV).

To determine the indicators of the ventilation function of the lungs, 167 healthy people (63 men and 104 women) belonging to various somatic types were performed spirography using the ETON-22 computer spirometric complex.

The examination was carried out in the morning (from 9.00 to 11.00), on an empty stomach, after a 20-minute rest. The examined men and women were recommended to refrain from smoking and drinking strong coffee at least 1 hour before the study. The examination was carried out in the sitting position of the patient.

The main spirometric indicators, which had somatotypically determined differences in the group of practically healthy people, were: vital capacity of the expiratory lungs (VEL), forced vital capacity of the expiratory lungs (VFV), forced expiratory volume in the first second FVC (FEV1), the ratio of FEV1 to FVC (% ) - Tiffno index (OFV1 / FZHEL), peak expiratory flow rate (POS), instantaneous expiratory flow rate 25% FVC (MOS25), instantaneous expiratory flow rate 50% FVC (MOS50), instant expiratory flow rate 75% VC (MOS75), the average space velocity in the range of exhalation from 25 to 75% (FVC SOS25-75), the average space velocity in the range of exhalation from 75 to 85% (FVC SOS75-85).

Statistical processing of the results taking into account the t-student criterion was carried out using a package of computer applications.

The results of the study demonstrated differences in the values of the ventilation function of the lungs in practically healthy people belonging to different somatic types. The normative indicators of the ventilation function of the lungs in men and women aged 17-22 for each of the 7 somatic types are shown in Tables 1 and 2. The somatotypic conditionality established by us for the values of indicators of the ventilation function of the lungs makes it possible to establish the optimal state of the ventilation function of the lungs and to differentiate it in the normal and borderline conditions of the respiratory system.

Table 1. Men SOMATIC TYPES INDICATORS Us MiS MiMeS MeC MeMaS MaS MeGS ZHELVYD ml 2790.0 ± 250.0 3778.9 ± 160.9 4517.8 ± 155.7 5038.9 ± 259.8 5183.8 ± 153.7 5429.3 ± 235.0 5032.5 ± 203.5 FZHELvyd, ml 2620.0 ± 290.0 3612.2 ± 184.0 3542.2 ± 320.7 4451.1 ± 421.4 4590.0 ± 161.3 5020.0 ± 197.4 4030.0 ± 521.1 FEV1, ml 2415.0 ± 315.0 3363.6 ± 199.4 3933.3 ± 234.6 4172.9 ± 155.8 4429.1 ± 126.2 4591.5 ± 169.7 3645.0 ± 215.0 FEV1 / FVC,% 91.9 ± 1.8 91.3 ± 4.2 91.3 ± 2.9 85.0 ± 4.5 93.4 ± 2.1 90.7 ± 1.7 82.9 ± 0.38 Pic, ml 5950.0 ± 250.0 7105.6 ± 433.7 8013.3 ± 379.3 8738.6 ± 525.3 9371.9 ± 435.4 9020.0 ± 550.6 4253.5 ± 2146.0 MOS25, ml 5375.0 ± 245.0 6517.8 ± 374.2 7b24.4 ± 399.3 8091.1 ± 414.0 8878.6 ± 391.7 8111.4 ± 448.3 5840.5 ± 1672.7 MOS50, ml 4270.0 ± 260.0 4252.5 ± 440.1 5891.1 ± 381.0 6050.0 ± 614.4 6891.3 ± 255.2 6532.9 ± 470.4 5857.5 ± 1073.4 MOS75, ml 2530.0 ± 200.0 2846.6 ± 223.7 3510.0 ± 333.6 3617.9 ± 662.0 4464.0 ± 270.4 3657.9 ± 289.1 2476.5 ± 933.9 SOS25-75, ml 4095.0 ± 205.0 4550.0 ± 328.8 5400.0 ± 265.8 5692.2 ± 463.9 6465.3 ± 266.2 5979.3 ± 422.0 5917.5 ± 1295.8 SOS75-85, ml 2045.0 ± 155.0 2520.0 ± 409.6 3165.6 ± 337.6 3630.0 ± 717.6 4004.0 ± 342.6 2999.3 ± 212.8 3627.5 ± 1159.2

Table 2. Women SOMATIC TYPES INDICATORS Us MiS MiMeS MeC MeMaS MaS MeGS ZHELVYD. ml 2980.0 ± 110.0 3211.7 ± 158.8 3502.0 ± 129.9 3480.0 ± 153.4 3836.5 ± 104.5 4428.0 ± 236.0 4220.0 ± 330.0 FZHELvyd, ml 2910.0 ± 35.0 2880.8 ± 232.1 3115.0 ± 196.0 2903.1 ± 163.5 3253.5 ± 144.5 3806.7 ± 268.3 3910.0 ± 490.0 FEV1, ml 2760.0 ± 35.0 2661.3 ± 226.9 2958.8 ± 112.0 2905.7 ± 161.0 3344.5 ± 193.7 3578.9 ± 224.9 3680.0 ± 260.0 FEV1 / FVC,% 94.85 ± 0.06 88.6 ± 5.1 89.3 ± 3.4 95.7 ± 2.1 93.5 ± 4.2 94.6 ± 1.8 94.7 ± 5.2 Pic, ml 6040.0 ± 485.0 6070.8 ± 494.6 6564.4 ± 407.9 6767.7 ± 391.0 7190.0 ± 235.7 7991.0 ± 437.6 6505.0 ± 755.0 MOS25, ml 4970.0 ± 180.0 6044.2 ± 391.3 6212.2 ± 395.8 6447.5 ± 360.9 6496.8 ± 245.8 7525.0 ± 420.0 6350.0 ± 700.0 MOS50, ml 3790.0 ± 165.0 4779.2 ± 322.4 5537.8 ± 400.9 5274.6 ± 329.2 5583.9 ± 194.1 5990.0 ± 334.6 5585.0 ± 155.0 MOS75, ml 2360.0 ± 125.0 3142.7 ± 229.6 3720.0 ± 459.5 3395.4 ± 316.4 3342.2 ± 255.6 3484.0 ± 258.4 3315.0 ± 585.0 SOS25-75, ml 3630.0 ± 185.0 4674.5 ± 243.9 5192.2 ± 444.1 4952.3 ± 341.6 5350.6 ± 229.9 5505.0 ± 287.2 5205.0 ± 145.0 SOS75-85, ml 1820.0 ± 65.0 2892.7 ± 309.1 3450.0 ± 525.1 3343.3 ± 403.1 3397.8 ± 270.0 3074.0 ± 229.3 2610.0 ± 240.0

Claims (1)

A method of establishing normative indicators of the ventilation function of the lungs of practically healthy people by conducting an anthropometric examination, according to the results of which somatotyping of men and women is carried out according to seven somatic types: nanosomal (NaC), microsomal (MiC), micromesosomal (MiMeS), mesosomal (MeC), macromesosomal ( MaMeS), macrosomal (MaS) and megalosomal (MeGS), then carry out spirographic examination, determining: ZHELVYD, FZHELvyd, OFV1, OFV1 / FZHEL, POS, MOS25, MOS50, MOS75, SOS25-75, SOS75-85, and the normative indicators whether the ventilation function of the lungs is determined by statistical processing of the obtained data, spirographic examination taking into account somatotyping, and the norm of the ventilation function of the lungs is set for a specific somatic type based on a complex of spirographic indicators: for men: ZHELVyd: for the somatic type of NaS - 2790.0 ± 250.0 ; for MiS - 3778.9 ± 160.9; for MiMeS - 4517.8 ± 155.7; for MeC - 5038.9 ± 259.8; for MeMaS - 5183.8 ± 153.7; for MaS - 5429.3 ± 235.0; for MeHS - 5032.5 ± 203.5; FZHELvyd: for the somatic type of NaS - 2620 ± 290.0; for MiS - 3612.2 ± 184.0; for MiMeS - 3542.2 ± 320.7; for MeC - 4451.1 ± 421.4; for MeMaS - 4590.0 ± 161.3; for MaS - 5020.0 ± 197.4; for MeHS - 4030.0 ± 521.1; FEV1: for the somatic type of NaC - 2415.0 ± 315.0; for MiS - 3363.6 ± 199.4; for MiMeS - 3933.3 ± 234.6; for MeC - 4172.9 + 155.8; for MeMaS - 4429.1 ± 126.2; for MaS - 4591.5 ± 169.7; for MeHS - 3645.0 ± 215.0; FEV1 / FVC: for the somatic type of NaS - 91.9 ± 1.8; for MiS - 91.3 ± 4.2; for MiMeS - 91.3 ± 2.9; for MeC - 85.0 ± 4.5; for MeMaS - 93.4 ± 2.1; for MaS - 90.7 ± 1.7; for MeHS - 82.9 ± 0.38; PIC: for the somatic type of NaC - 5950.0 ± 250.0; for MiS - 7105.6 ± 433.7; for MiMeS - 8013.3 ± 379.3; for MeC - 8738.6 ± 525.3; for MeMaS - 9371.9 ± 435.4; for MaS - 9020.0 ± 550.6; for MeHS - 4253.5 ± 2146.0; MOS25: for the somatic type of NaC - 5375.0 ± 245.0; for MiS - 6517.8 ± 374.2; for MiMeS - 7624.4 ± 399.3; for MeC - 8091.1 ± 414.0; for MeMaS - 8878.6 ± 391.7; for MaS - 8111.4 ± 448.3; for MeHS - 5840.5 ± 1672.7; MOS50: for the somatic type of NaC - 4270.0 ± 260.0; for MiS - 4252.5 ± 440.1; for MiMeS - 5891.1 ± 381.0; for MeCs - 6050.0 ± 614.4; for MeMaS - 6891.3 ± 255.2; for MaS - 6532.9 ± 470.4; for MeHS - 5857.5 ± 1073.4; MOS75: for the somatic type NaS - 2530.0 ± 200.0; for MiS - 2846.6 ± 223.7; for MiMeS - 3510.0 ± 333.6; for MeC - 3617.9 ± 662.0; for MeMaS - 4464.0 ± 270.4; for MaS - 3657.9 ± 289.1; for MeHS - 2476.5 ± 933.9; FZHEL SOS25-75: for the somatic type of NaS - 4095.0 ± 205.0; for MiS - 4550.0 ± 328.8; for MiMeS - 5400.0 ± 265.8; for MeC - 5692.2 ± 463.9; for MeMaS - 6465.3 ± 266.2; for MaS - 5979.3 ± 422.0; for MeHS - 5917.5 ± 1295.8; FZHEL SOS75-85: for the somatic type of NaS - 2045.0 ± 155.0; for MiS - 2520.0 ± 409.6; for MiMeS - 3165.6 ± 337.6; for MeC - 3630.0 ± 717.6; for MeMaS - 4004.0 ± 342.6; for MaS - 2999.3 ± 212.8; for MeHS - 3627.5 ± 1159.2; for women: ZHELVYD: for the somatic type of NAC - 2980.0 + 110.0; for MiS - 3211.7 + 158.8; for MiMeS - 3502.0 ± 129.9; for MeC - 3480.0 ± 153.4; for MeMaS - 3836.5 ± 104.5; for MaS - 4428.0 ± 236.0; for MeHS - 4220.0 ± 330.0; FZHELvyd: for the somatic type of NaS - 2910.0 ± 35.0; for MiS - 2880.8 ± 232.1; for MiMeS - 3115.0 ± 196.0; for MeC - 2903.1 ± 163.5; for MeMaS - 3253.5 ± 144.5; for MaS - 3806.7 ± 268.3; for MeHS - 3910.0 + 490.0; FEV1: for the somatic type of NaS - 2760.0 ± 35.0; for MiS - 2661.3 ± 226.9; for MiMeS - 2958.8 ± 112.0; for MeC - 2905.7 ± 161.0; for MeMaS - 3344.5 ± 193.7; for MAC - 3578.9 ± 224.9; for MeHS - 3680.0 ± 260.0; FEV1 / FVC: for the somatic type of NaS - 94.85 ± 0.06; for MiS - 88.6 ± 5.1; for MiMeS - 89.3 ± 3.4; for MeCs, 95.7 ± 2.1; for MeMaS - 93.5 ± 4.2; for MaS - 94.6 ± 1.8; for MeHS - 94.7 ± 5.2; PIC: for the somatic type of NaS - 6040.0 ± 485.0; for MiS - 6070.8 ± 494.6; for MiMeS - 6564.4 ± 407.9; for MeCs - 6767.7 + 391.0; for MeMaS - 7190.0 + 235.7; for MaS - 7991.0 + 437.6; for MeHS - 6505.0 + 755.0; MOS25: for the somatic type of NaC - 4970.0 + 180.0; for MiS - 6044.2 + 391.3; for MiMeS - 6212.2 + 395.8; for MeC - 6447.5 + 360.9; for MeMaS - 6496.8 + 245.8; for MaS - 7525.0 + 420.0; for MeHS - 6350.0 + 700.0; MOS50: for the somatic type of NaC - 3790.0 + 165.0; for MiS - 4779.2 + 322.4; for MiMeS - 5537.8 + 400.9; for MeC - 5274.6 + 329.2; for MeMaS - 5583.9 + 194.1; for MaS - 5990.0 + 334.6; for MeHS - 5585.0 + 155.0; MOS75: for the somatic type of NaC - 2360.0 + 125.0; for MiS - 3142.7 + 229.6; for MiMeS - 3720.0 + 459.5; for MeC - 3395.4 + 316.4; for MeMaS - 3342.2 + 255.6; for MaS - 3484.0 + 258.4; for MeHS - 3315.0 + 585.0; FZHEL SOS25-75: for the somatic type of NaS - 3630.0 + 185.0; for MiS - 4674.5 + 243.9; for MiMeS - 5192.2 + 444.1; for MeC - 4952.3 + 341.6; for MeMaS - 5350.6 + 229.9; for MaS - 5505.0 + 287.2; for MeHS - 5205.0 + 145.0; FZHEL SOS75-85: for the somatic type of NaS - 1820.0 + 65.0; for MiS - 2892.7 + 309.1; for MiMeS - 3450.0 + 525.1; for MeC - 3343.3 + 403.1; for MeMaS - 3397.8 + 270.0; for MaS - 3074.0 + 229.3; for MeHS - 2610.0 + 240.0.