TRUNK BODY MASS INDEX: A NEW REFERENCE FOR THE ASSESSMENT OF BODY MASS DISTRIBUTION.

BACKGROUND: Body mass index (BMI) has some limitations for nutritional diagnosis since it does not represent an accurate measure of body fat and it is unable to identify predominant fat distribution. AIM: To develop a BMI based on the ratio of trunk mass and height.
METHODS: Fifty-seven patients in preoperative evaluation to bariatric surgery were evaluated. The preoperative anthropometric evaluation assessed weight, height and BMI. The body composition was evaluated by bioimpedance, obtaining the trunk fat free mass and fat mass, and trunk height. Trunk BMI (tBMI) was calculated by the sum of the measurements of the trunk fat free mass (tFFM) and trunk fat mass (tFM) in kg, divided by the trunk height squared (m2)). The calculation of the trunk fat BMI (tfBMI) was calculated by tFM, in kg, divided by the trunk height squared (m2)). For the correction and adjustment of the tBMI and tfBMI, it was calculated the relation between trunk extension and height, multiplying by the obtained indexes.
RESULTS: The mean data was: weight 125.3±19.5 kg, height 1.63±0.1 m, BMI was 47±5 kg/m2) and trunk height was 0.52±0,1 m, tFFM was 29.05±4,8 kg, tFM was 27.2±3.7 kg, trunk mass index was 66.6±10.3 kg/m², and trunk fat was 32.3±5.8 kg/m². In 93% of the patients there was an increase in obesity class using the tBMI. In patients with grade III obesity the tBMI reclassified to super obesity in 72% of patients and to super-super obesity in 24% of the patients.
CONCLUSION: The trunk BMI is simple and allows a new reference for the evaluation of the body mass distribution, and therefore a new reclassification of the obesity class, evidencing the severity of obesity in a more objectively way.

INTRODUCTION

The World Health Organization (WHO) considers obesity as the greatest threat to public health nowadays. Approximately 400 million adults are obese and 1.6 billion overweight , .

Obesity is a multifactorial disease, mainly characterized by excessive body fat related to the development of important comorbidities such as type 2 diabetes mellitus, dyslipidemia, cardiovascular disease, arterial hypertension and metabolic syndrome , , , , . Severe obesity is characterized by excessive body fat, increased total body water and reduced lean mass .

Body mass index (BMI) is an anthropometric method developed in 1832 by the mathematician Adolphe Quételet, aiming to determine the ideal body mass of an individual . WHO recommends BMI in the diagnose of obesity . However, in recent years, there has been increasing debate about the development of different BMI cutoffs for different ethnic groups, due to the growing evidence that associations between BMI, body fat percentage and body fat distribution differ between populations and, therefore, the health risks increase below the 30 kg/m2 )cutoff , that defines obesity in the current WHO classification , .

Additionally, the use of BMI for nutritional diagnosis has limitations, once it does not represent a precise measure of body adiposity, being unable to differentiate fat free mass from fat mass , , , , and may underestimate the presence of obesity in about 40% of cases .

With the increasing importance of the diagnosis of obesity, it is necessary to re-evaluate the way in which body fat and its distribution are determined , since health risk is different depending on the location of the fat accumulation (i.e. in the upper or lower half of the body) , . The distribution of body fat, specifically visceral (or central) fat, seems to be the link between adipose tissue and insulin resistance, characteristic of metabolic syndrome. It is questioned the exclusive use of BMI in the classification of cardiovascular risk in obese individuals, taking into consideration that even populations with low BMI present a high prevalence of metabolic syndrome .

Visceral fat is more associated with metabolic complications than abdominal and peripheral subcutaneous fat. Men present, on average, 20% or more of total fat as visceral fat, while women, less than 10% . Thus, it is believed that an index based on the disposition of central body fat may be more specific to diagnose the obesity severity, due to the relevance of intra-abdominal adipose tissue, currently considered a multiple-function organ .

The aim of this study was to propose a body mass index based on the relationship between trunk mass and height.

METHODS

All participants signed the informed consent form. The study protocol was approved by the Ethics Committee from the Clinics Hospital from University of São Paulo (number 01038912.6.0000.0068).

A total of 77 patients were selected from January to October 2016, aged 18-60 years and BMI between 40-60 kg/m2, admitted to the Bariatric and Metabolic Surgery Unit of the Discipline of Digestive Tract Surgery, Clinics Hospital, Medicine School, University of São Paulo, São Paulo, SP, Brazil.

Twenty patients were excluded due to acute or chronic disease that caused excessive water retention (n=2), patients bedridden or with functional limitation (n=16) or previous bariatric surgery (n=2).

Anthropometric and body composition

Participants were weighed in light clothing, without carrying heavy objects, in orthostatic position, with the lower limbs parallel, without footwear, eyes straight ahead, with the upper limbs at the side of the body and without moving, at the center of a microelectronic scale installed on the smooth surface to avoid oscillation (InBody 230®, GE Healthcare, USA with 250kg capacity, with 100g intervals). The height was measured with the feet and heels parallel, shoulders and glutes leaning against the portable stadiometer graduated in millimeters (Sanny®, American Medical do Brasil Ltda). BMI was calculated using the cutoff points suggested by WHO , , .

Body composition was assessed using a noninvasive indirect bioimpedance method (InBody 230®), where the participant was positioned in orthostatic position, without moving or talking, on a platform with special supports for the bare feet (lower electrodes) and with the upper limbs extended holding two supports with the hands (upper electrodes). The scale used directly measured the impedance of each body segment at 20KHz and 100KHz sampling frequency, leading to highly accurate results. The chemical composition of the body fat free mass (FFM) was conventionally assumed to be constant, with a density of 1.1 kg/m3, with a temperature of 37° C and a water concentration of 73%. Thus, FFM of the upper limbs, trunk and lower limbs were calculated by multiplying the water volume of the upper extremities (the sum of the right and left), trunk, and lower limbs (the sum of the right and left extremities) by 1.37 .

The following data were obtained: trunk FFM (FFMt) and trunk fat mass (FMt), in absolute values ​​and percentage.

To obtain the trunk height, the patients remained with parallel lower limbs, without footwear. They were measured using an inelastic measuring tape with a two meter length. It was measured, by physical examination, the distance from the seventh cervical vertebra (C7), located in the back of the neck, to the floor and from the iliac crest (located at the back of the hip, by physical examination) to the floor, subtracting the second from the first measure, obtaining the trunk height.

The trunk BMI (BMIt) was calculated using the sum of the FFMt and trunk fat mass (FMt), in kg, divided by the square of the trunk height (m2).

The trunk fat BMI (BMIft) was calculated using FMt, in kg, by dividing it by the square of trunk height (m2).

Indexes correction factor

To correct and adjust the BMIt and BMIft indexes, the relationship between the trunk extension and the height was calculated, multiplying by the values obtained: a) BMIt correction factor: trunk (m)/height (m) x BMIt; b) BMIft correction factor: trunk (m)/height (m) x BMIft

RESULTS

The sample consisted of 57 patients (39 women). The mean weight and height were 125.3±19.5 and 1.63±0.09 kg, respectively. BMI showed an average of 47±5 kg/m2.

The mean patient´s trunk extension was 0.52 m, being 0.56 m in men and 0.49 m in women. The mean FFMt was 29.1 kg and the mean FMt was 27.2 kg (Table 1).

TABLE 1

Anthropometric values and trunk body composition

Variables (n=57)	Mean	± SD	Minimum	Maximum
Trunk (m)	0.52	± 0.1	0.29	0.68
Trunk FFM (kg)	29.1	± 4.8	20.3	43.5
Trunk FM (kg)	27.2	± 3.7	17.3	34.7
Trunk FFM + FM (kg)	56.2	± 7.7	38.7	75.1

FFM=fat free mass; FM=fat mass

The results of the BMI are shown in Table 2. Applying the index correction factor, the mean corrected BMIt was 66.62 kg/m² and 32.32 kg/m² for the corrected BMIft.

TABLE 2

Body mass indexes

BMI (n=57)	Mean	± SD	Minimum	Maximum
BMI (kg/m²)	47.0	± 5.0	39.4	58.9
Trunk BMI (kg/m²)	216.1	± 54.4	144.0	350.0
Corrected Trunk BMI (kg/m²)	66.6	± 10.3	36.5	87.0
Trunk fat BMI (kg/m²)	104.9	± 27.9	62.1	174.4
Corrected Trunk Fat BMI (kg/m²)	32.3	± 5.8	18.8	44.2

BMI=body mass index

Out of the 39 patients with obesity class III, BMIt reclassified 37 patients (95%): nine (24%) were classified as super obese (BMI>50 kg/m²) and 28 (72%) as super-super obese (BMI>60 kg/m²).

Out of the 16 super obese patients (28%), BMIt reclassified 13 patients (81%) as super-super obese.

Only four patients maintained the obesity classification after usinf BMIt, and only one reduced the obesity classification (Table 3).

TABLE 3

Patients body mass index reclassification after applying the correction factor

Patients (n=57)	Mean BMI (kg/m²)	Classification	Mean correctecd BMIt (kg/m²)	Reclassification
13	53.15	super obese	69.95	super super obese
3	54.65	super obese	55.68	super obese
28	45.25	class III	71.57	super super obese
9	43.58	class III	56.06	super obese
1	43.69	Class III	48.87	class III
1	48.06	class III	36.52	class II
2	39.68	class II	63.55	super super obese

BMI=body mass index; BMIt=trunk body mass index

DISCUSSION

One of the main objectives of determining body composition is to estimate the amount of body fat, related to the presence of systemic diseases, morbidity and mortality , . It should be emphasized that the simple measurement of body mass is not able to identify the lack or excess of body components (fat mass, muscle mass, water, and bone mass) .

BMI is recommended for its convenience, safety and simplicity . However, there are important limitations related to interpretations that should be considered, such as age, gender, and ethnicity , . In addition, BMI does not estimate body fat mass, thus limiting its accuracy in the diagnosis of obesity , .

There is no consensus on the best method for body evaluation in patients with severe obesity . In the literature, some studies suggest new parameters for the evaluation of body composition and classification of nutritional status by body fat percentage, such as body fat index (BFI), which uses only anthropometric measures such as hip circumference and stature , , and reciprocal ponderal index (RPI) in which are considered the individual height and weight .

BFI is a fast, inexpensive and non-invasive method that was developed with Mexican American adults to estimate percentage of body fat . Studies have shown that its performance was not consistent in other populations with different characteristics from those used in its development and validation . For Chinese population BFI underestimated the percentage of body fat when compared to bone densitometry measured by DEXA (dual energy X-ray absorptiometry). Thus, BFI is not better as an indicator of cardiovascular risk compared to BMI .

In a study with 102 Brazilian women with BMI 26.9±3.1 kg/m2, the percentage of body fat obtained by DEXA and BFI were compared, with averages 36.9% and 33.6%, respectively. BFI showed low agreement and accuracy, varying according to age, gender and ethnicity . A study with 433 patients with severe obesity compared BFI and noninvasive indirect bioimpedance with an already validated equation adapted for this population to calculate the percentage of fat, and found limitations in BFI method for this population .

Reciprocal ponderal index (RPI) , calculated by the equation: height (cm)/weight (kg) - , has as cutoff points >44: underweight, 41-44: normal and <41: overweight. It shows greater mathematical logic and less influence of extreme height, since weight is a cubic variable and height is linear, when compared to BMI . The use of RPI, which also does not discriminate fat free mass and fat mass, would, theoretically, have the same limitations as BMI , . However, when it is used for the diagnosis of overweight and obesity, compared to the percentage of body fat the result is lower, especially in women, and also, RPI is directly influenced by age and gender .

A study with 530 Japanese Brazilians with a prevalence of overweight and central adiposity (ratio between waist and hip circumference) of 22% and 67%, respectively, showed that individuals with central adiposity had higher glycemia, triglycerides, total cholesterol, low-density lipoprotein and lower high-density lipoprotein rates compared to those without overweight and central adiposity .

A review with 433 articles showed that non-invasive indirect bioimpedance (with specific equations) and BFI are inexpensive and non-invasive methods that are available and can be routinely used to estimate body fat .

Central obesity, characterized by the accumulation of trunk and abdomen fat, has as one of its components, visceral abdominal fat, which its thickness is of great importance as an indicator of cardiovascular risk .

The development of an index that is more objectively evidence the relation of trunk mass and fat distribution can contribute to obesity classification and its relationship with associated diseases. In this study 96% of the obese patients class III had increased obesity class (for super and super-super obesity), demonstrating the usefulness of using trunk BMI as a new proposal for the evaluation of obese patients in bariatric surgery programming.

CONCLUSION

The trunk body mass index is an accessible and practical anthropometric method, which allows the reclassification of BMI based on trunk mass distribution, evidencing more clearly the severity of obesity.