Effectiveness of a polyphenolic extract (Lippia citriodora and Hibiscus sabdariffa) on appetite regulation in overweight and obese grade I population: an 8-week randomized, double-blind, cross-over, placebo-controlled trial

The study consisted of a randomized controlled trial, double-blind, cross-over clinical trial with two branches depending on the product consumed experimental (Lc-Hs) or placebo (Pla) and single center (Fig. 1).

The present study had a length of 150 days divided into two allocations of 60 days separated by a wash-out period of 30 days. In the first phase subjects consumed the Lc-Hs or Pla and after the wash-out period the treatments were crossed. Each subject was assigned a code generated by a software generator (Epidat v4.1 Epidat, Spain) and was randomized in a 1:1 ratio to either of the two treatments (Lc-HS or placebo). Both the researchers and the subjects did not know which treatment subjects received.

A total of 36 healthy subjects of both sexes participated in the study, of which 33 completed the intervention and were included in the final analysis as depicted in Fig. 2 (2 of the participants were unable to attend the appointment at the appropriate time and 1 did not want to continue with the study for personal reasons). Participants were recruited disseminating information on the study through talks in women’s centers, senior centers, neighborhood associations, and mass media. All subjects selected for possible inclusion were cited for a first face-to-face selection visit (15 days prior to the start of the study), where they were fully and in-depth informed of all pertinent aspects of the study (nature and objectives), as well as the possible risks involved, including written information and opinion favorable of the ethics committee. If the subject decided to participate in the study, their informed consent was obtained, freely granted and in writing before the realization of any study-related activity.

Subjects had to meet all inclusion criteria (age between 18 and 65 years old, both sexes, body mass index (BMI) between 25 and 34.9 kg/m², weight maintained in the last three months, do not modify nicotinic habits and absence of disease) and any of the exclusion criteria (chronic diseases, illness, thyroid dysfunction, allergies to any components of the study product, carrying out or intend to carry out any type of diet during the study and participants that are in pregnancy state). A total of 33 overweight and obese subjects; 17 males and 16 females were part of the study, with a mean age of 33.76 ± 12.23 years, a weight of 82.54 ± 11.38 kg, a BMI 28.20 ± 2.47 and 30.65 ± 8.39% of fat mass at baseline. Once the participant signed the informed consent and was included in the study (after analyzing the aforementioned criteria), the researchers indicated the protocol to follow to the participants and were instructed to take two capsules a day.

The study protocol was approved by the Institutional Review Committee of the Universidad Católica San Antonio (Murcia, Spain; CE011815). Furthermore, the study was conducted in accordance with the Declaration of Helsinki [Randomized Trial Registration Number (Clinicaltrials): NCT04105192].

Lc-Hs (MetabolAid^®, Monteleloeder S.L., Alicante, Spain) and Pla presented similar pharmaceutical form. Lc-Hs was composed by a mixture of extracts from Lippia citriodora and Hibiscus sabdariffa, while Pla contained crystalline microcellulose. The administration was oral consisting on 2 capsules/day, each capsule containing 250 mg of either Lc-Hs (the two capsules correspond to the daily dose of 325 mg Lc and 125 mg Hs) or Placebo, before breakfast during a period of 60 days. At the end of each allocation, subjects were asked to return the empty blisters to check compliance of supplementation protocol. Same procedure was repeated after the cross-over.

The composition of the formula and HPLC data has been published in previous reports [9, 17]. Briefly, Lemon verbena and Hibiscus extracts, standardized in verbascoside and anthocyanins, respectively, are mixed in a 65–35% ratio.

Four major phenolic compounds are identified, i.e. two anthocyanins, delphinidin-3-O-sambubioside and cyanidin-3-O-sambubioside (from the Hibiscus extract) and two phenylpropanoids, verbascoside, and isoverbascoside (from the Lemon verbena extract). Total anthocyanins represent 3.5% of the total dry weight with delphinidin-3-O-sambubioside constituting 2.27% (65% of total anthocyanidins) and cyanidin-3-O-sambubioside comprising 1.23% (35% of total anthocyanidins). Regarding phenylpropanoids, 16% w/w, verbascoside represents the major compound and constitutes 15% (93.75% of total phenylpropanoids) and isoverbascoside represents 1% (6.65% of total phenylpropanoids). Figure 3 below taken from Herranz-Lopez et al. [17].

Comparative analysis was performed in a previously published report, by analyzing the effect of Lemon verbena extract, Hibiscus extract, its combination (the studied ingredient), and Garcinia cambogia, in high-fat diet-fed mice [9]. Garcinia cambogia is a widely extended plant extract consumed for its weight loss properties. The published study revealed that the combination of Lemon verbena and Hibiscus extracts, in the proportions found in the present ingredient, provide numerous benefits over Garcinia cambogia and the extracts in isolation. This includes lower body weight gain in presence of a high-fat diet, higher adiponectin expression, and lower leptin expression; all using a lower concentration of ingredient (100 mg/kg vs 245 mg/kg with Garcinia cambogia).

Other authors have also reported the effect of Hibiscus and Lemon verbena on some of the analyzed hormones, such as Hibiscus on leptin expression [27], or Lemon verbena activating AMPK [28], which is known to have an important role in controlling appetite in the hypothalamus [29]. Furthermore, high polyphenolic intake has been associated with weight loss, particularly anthocyanins and flavonols [30].

Subjects came to laboratory several times. Study design is depicted in Fig. 1. In each phase, subjects visited to the laboratory two times. At baseline of each phase (Visit 1, Visit 3), blood samples (3 mL) were obtained from the antecubital veins of subjects to determinate hormonal and biochemistry (lipid and glucidic profile and safety parameters) analysis. After blood extraction, each subject received the product to consume (Lc-Hs or Pla) and an accelerometer was placed on the non-dominant wrist (ActiGraph wGT3-BT. ActiGraph, Pensacola, FL, USA) to evaluate their physical activity. The monitor was configured to save data for 3 consecutive days. The participant wore it all the time except during water-based activities. The intensity of physical activity (sedentary, light, moderate and vigorous) was determined using Freedson's algorithm and categories [31]. Physical activity was expressed in METs/day. The software used in the accelerometer data analysis was ActiLife 6 (ActiGraph, Pensacola, FL; USA).

Once the product was delivered and the subjects were instructed, all participants were measured for standing height using ISAK protocols [32]. Subsequently, a foot-to-foot bioimpedance (Tanita BC-420M. Tanita Corporation, Arlington Heights, IL, USA) was performed to evaluate possible changes in body composition (weight, BMI, fat mass, and muscle mass). Subjects had to arrive after a 12 h fasting period, only allowing water intake until the previous 3 h. In case of smokers, the last cigarette should have been smoked at least 1 h before extraction. Moderate–high-intensity exercise could not be performed in the previous 24 h. The standardized conditions with respect to body position, previous exercise, dietary intake and body hydration have been respected [33]. At the end of each phase (Visit2, Visit4), blood collection (3 mL), evaluation of physical activity and body composition analysis were performed again.

To determine the efficacy of Lc-Hs, ad-libitum appetite test and visual analog scale (VAS) were performed at the end of the two phases (Visit 2 and Visit 4). During these visits, subjects came to the laboratory on fasted and took the product 30 min before eating a standardized breakfast. Before the participants attended visits Visit 2 and Visit 4, considering their breakfast time, the time from which they could not eat food was calculated. When they arrived at the established time, they were asked the time of the last meal and it was verified that they complied with the established recommendations. After subjects ate, blood samples (3 mL) were taken and VAS were filled by subjects at baseline, which would continue until 270 min (after consumption of the breakfast) at different times (0, 15, 30, 60, 90, 120, 180, 240, 270). Participants had to eat all breakfast and had a maximum time of 15 min. At minute 240, an ad-libitum buffet was served to quantify an ad-libitum intake. Nutritional value of the food served was determined using Dietsource v3.0 software (Novartis Medical Nutrition S.A., 1997–2003 which uses a table of composition of Spanish foods [34]. The breakfast was composed by bread (50 g), ham (30 g), cheese (25 g), pineapple juice (200 mL) and non-flavored yogurt (125 g), presenting a nutritional value of 417 kcal, 47 g of carbohydrates, 2 g of fiber, 21 g of protein and 15 g of lipids.

Later, in the ad-libitum meal, the subjects chose the type of food (fresh potato omelette with onion, meatballs with tomato, peas with ham, bolognese macaroni, vegetable stew and white toast), and this was weighed before and after the buffet lunch intake. They had a maximum time of 30 min for the ad-libitum buffet. Therefore, energy and macronutrients intake were determined for every volunteer from the quantitative measurement of food ingested.

Visual analog scales (VAS) were used to evaluate Appetite Score (AS) after the intake of every product under investigation. Subjects reported their state of hunger, satiety and fullness on a 100 mm VAS by placing a vertical line on a scale. The VAS ranged from “not at all” and “extremely” and was divided in four questions to assess hunger (how hungry do you feel?), desire to eat (how strong is your desire to eat?) fullness (how full do you feel?) and prospective food consumption (PFC) (how much food do you think you can (or you want) eat?). AS was calculated as the average of the four individual scores: \(\left( {{\text{Satiety}}\; + \;{\text{fullness}}\; + \;{\text{PFC}}\; + \;\left( {100 - {\text{hunger}}} \right)} \right)/4\). That formula and the interpretation of the results were adapted from previous studies [35], concluding that lower AS corresponds to greater fullness.

VAS for each of the evaluated components of appetite, were completed by subjects in the following times: before and immediately after the intake of product under investigation, and at 10″, 20″, 30″, 40″, 50″, 60″, 120″, 180″, 240″ (immediately before ad-libitum meal) and 270″ post-intake of foods under investigation (immediately after consumption of ad-libitum meal) (Fig. 4) [36, 37].

In the measurement of AS, the area under the curve was calculated by summarizing the mean scores of pairs of adjacent time points and then calculating a weighted mean (weighted by the time difference of two time points). AS was calculated at every measurement interval, and the change in AS was calculated as the difference between AS baseline and AS of each subsequent measurement using the following formula: \({\text{Decrease}}\;{\text{of}}\;{\text{appetite}}\; = \;{\text{AS}}\;{\text{pre - intake}} - {\text{AS}}\;{\text{post - intake}}\); in which the average AS 60 min post-intake was represented by the area under curve (AUC) at AS (time 0, 10, 20, 30, 40, 50 y 60). AUC was measured by the area under the curve of time course of AS from minute 0 to 60 post-intake of product.

Satiety evaluation, using VAS was carried out for each product in every volunteer who attended the present research. The later term effect on satiety of a food was determined from VAS, and the energy composition of products contained in the ad-libitum food consumption test, using the formula of satiety quotient (SQ). The implementation of SQ is an additional aid to the determination of the satiating capacity of food, and provides information on the capacity of a food, a nutraceutical or a short-term appetite control drug [38].

SQ was calculated by the subtraction of the value AS before the intake of the product under study, minus the average of AS in the 60 min after intake of the product. This difference was divided by the energy values of the ingested ad-libitum food. By convention, the result of SQ is multiplied by 100 to obtain a more manageable range of values. Therefore, the resulting formula was: SQ (% mm/Kcal) = Decrease of appetite (defined as: (AS pre-intake − Average AS 60 min post-intake)/Energy of products under investigation (kcal) × 100), following the protocol used by Drapeau et al. [39, 40] only adapting the scale from 150 to 100 mm. As shown in the following meta-analysis, different types of scales can be used without affecting SQ [41]. Regarding the interpretation of SQ values, higher SQ, greater satiety.

Blood samples were collected in hemograme (tube w. K3 EDTA for 3 mL lavender cap 13 × 75 mm; Vacutest) and biochemistry (tube with gel and clot activate Vol 3.5 mL 13 × 75 mm; Vacutest) tubes and centrifuged (4500 rpm, 5 min, 4 °C) and then stored at − 80 °C and subsequently analyzed to monitor satiety hormones [insulin, leptin, adiponectin, ghrelin, peptide tyrosine-tyrosine (PYY) and Glucagon-like Peptide-1 (GLP-1)], glycemic profile [glycemia, insulinemia, glycated hemoglobin, peripheral insulin resistance (HOMA-R)] and lipid profile (total cholesterol, LDL cholesterol, HDL cholesterol, triglycerides). The methods used to analyze satiety hormones were: leptin [Human Adiponectin ELISA Kit; catalog no: RD195023100; sensitivity 26 ng/mL; lower limit of detection 0.1 µg/mL; inter-assay variation 5.6%; intra-assay variation 5.9%; BioVendor Research & Diagnostic Products (Brno, Czech Republic, Europe)], adiponectin [Human Leptin ELISA Kit; catalog no: RD191001100; sensitivity 0.2 ng/mL; lower limit of detection 1 ng/mL; inter-assay variation 6.7%; intra-assay variation 4.9%; BioVendor Research & Diagnostic Products (Brno, Czech Republic, Europe)], Ghrelin [Human GHRL (Ghrelin) ELISA Kit; catalog no: E-EL-H1919 96T; sensitivity 0.1 ng/mL; lower limit of detection 0.16 ng/mL; inter-assay variation 4.7%; intra assay variation 4.5%; Elabscience biotechnology Inc (Wuhan, Hubei, China)], peptide tyrosine-tyrosine [Human PYY (Peptide YY) ELISA Kit; catalog no: E-EL-H1237 96T; sensitivity 18.65 pg/mL; lower limit of detection 31.25 pg/mL; inter-assay variation: 5.1%; intra-assay variation 5.2%; Elabscience biotechnology Inc (Wuhan, Hubei, China)], Glucagon-Like Peptide-1 [Human GLP-1 (Glucagon Like Peptide-1) ELISA Kit; catalog no: E-EL-H0148 96T; sensitivity 0.19 ng/mL; lower limit of detection 0.31 ng/mL; inter-assay variation 5.5%; intra-assay variation 5.9%; Elabscience biotechnology Inc (Wuhan, Hubei, China)]. BA400 automatic clinical chemistry analyzer (BioSystems S.A, Costa Brava, Barcelona, Spain) was used to obtain the glycemic and lipidemic values.

Due to the high predictive capacity, the main variable for the study of satiety was SQ. This quotient relates food intake to motivation to eat in the period after food intake, a relationship that cannot be determined by individual analysis of the amount of food consumed or ratings of motivation to eat. Interestingly, the treatment with the Lc-Hs extract resulted in enhanced SQ, leading to higher value compared with subjects from Pla treatment (p < 0.0001). Therefore, SQ reported from the Lc-Hs treatment was 5.53 ± 2.91%mm/kcal compared to the subjects from Pla treatment who reported minor value (3.36 ± 2.33%/kcal) (Fig. 5).

The remaining parameters to determine satiety also showed interesting results, being improved after treatment with Lc-Hs. Both Lc-Hs and Pla treatments showed similar appetite sensation (AS) and satiety sensation parameters at baseline. However, after VAS accomplishment by subjects, results showed that subjects treated with Lc-Hs felt fuller compared to those treated with Pla. After a standardized breakfast intake at baseline (min − 30), VAS scales were given to the subjects. During the first monitoring 2 h, it was found significant difference at the different control times during the scales, comparing Lc-Hs and Pla treatments [min 0: Pla (44.78 ± 6.92%) compared to Lc-Hs (34.78 ± 8.82%) (p < 0.0001), min 15: Pla (43.77 ± 8.06%) compared to Lc-Hs (34.2 ± 8.75%) (p < 0.0001), min 30: Pla (40.58 ± 9.33%) compared to Lc-Hs (32.54 ± 8.90%) (p < 0.001), min 60: Pla (44.01 ± 7.93%) compared to Lc-Hs (38.13 ± 9.29%) compared to Lc-Hs (p < 0.005), min 90: Pla (50.31 ± 8.2%) compared to Lc-Hs (45.53 ± 8.97%) (p < 0.002), min 120: Pla (55.7 ± 7.42%) compared to Lc-Hs (53.09 ± 9.2%) compared to Lc-Hs (p < 0.018)]. The evolution of AS and satiety is depicted in Fig. 6.

According to the aforementioned data, a large decrease evaluating the average of AS during the first hour was observed in subjects treated with Lc-Hs compared to those treated with Pla (p < 0.0001). Specifically, AS decreased from 73.09 ± 12.89% to 34.65 ± 14.98% in Lc-Hs and from 69.44 ± 14.76% to 42.76 ± 13.21% in Pla. That variation is depicted Fig. 5.

AUC scores also showed the same correlation than the observed for satiety and AS. In this case, analyzing different periods of the test, increased AUC was observed in subjects treated with Pla compared to those treated with Lc-Hs. During the first hour (p < 0.0001), AUC was higher in Pla subjects (2565.72 ± 792.33% min⁻¹), while Lc-Hs treatments showed minor AUC (2078.67 ± 898.99% min⁻¹). However, the differences in AUC were decreasing as the minutes passed. Therefore, in the interval from min 60 to min 240 (p = 0.249) AUC of Pla (10,638.92 ± 2413.30% min⁻¹) and Lc-Hs (102,565.65 ± 2940.48% min⁻¹) treatments showed to be close. Finally, due to the marked difference between treatment treatments in the first 60 min, the overall AUC from baseline to min 240 (p < 0.014) was 9136.65 ± 2261.46% min⁻¹ for Pla and 8279.73 ± 2745.71% min⁻¹ for Lc-Hs.

It was observed that Lc-Hs treatment reported enhanced satiety and minor appetite than subjects treated with Pla, indicating better satiety response. Furthermore, despite the similar values observed of both treatment treatments observed in the interval from min 60 to min 240, the marked difference observed during the first hours lead to statistically significant differences along the following 4 h (Fig. 6).

Finally, the caloric consumption during ad-libitum meal at the end of the 4 h, showed minor (p < 0.004) energy consumption for subjects treated with Lc-Hs (774.44 ± 247.77 kcal) compared to those treated with Pla (849.52 ± 246.54 kcal) (Fig. 7). These data together with SQ, reflect the relevance of AS and satiety as key factors in the number of calories consumed in a meal and the consequent feeling of satiety after that meal. Macronutrients content after ad-libitum intake was similar in both treatments, leading to non-significant differences between them. The intake of protein, carbohydrates and fats in Pla treatment was 32.4 ± 16.59, 141.75 ± 75.21 and 44.3 ± 18.65 g, respectively. In turn, the Lc-Hs treatment reported 34.95 ± 18.84 g of protein 140.95 ± 81.85 g of carbohydrates and 46.30 ± 20.84 g of fats. The differences observed in macronutrients may be attributed due to inclusion of dietary fiber (mainly cellulose) as carbohydrates.

Finally, the differences regarding sex reported interesting conclusions. Actually, there are differences by sex but they are not statistically evident. As the population between men and women rises, the number of volunteers in each group becomes too small and significant differences are lost.

The mean AUC at 240 min shows that the decrease after the consumption of Lc-Hs is not significant in men (p = 0.58) and if it is significant in women (p = 0.015). But when comparing these differences, they are not significant (p = 0.152) given the small number of volunteers in each group. In summary, for leptin and GLP-1, the levels were higher in women than in men. The modifications observed when the experimental product is consumed in men is not significant for either of the two incretins, but in women it is. However, when comparing men with women, no differences were observed (p > 0.05). Moreover, Ghrelin did not show any difference between sexes (p > 0.05).

To carry out a hormonal analysis of satiety, both a long-term control during the study (before and after 60 days of product consumption) and a short-term control during the test were carried out.

Baseline values were similar in both treatments for all hormones (p > 0.05). Table 2 shows the values obtained for long-term hormonal analysis. Anorexigenic hormones as insulin, adiponectin and PYY did not showed statistically significant intra-treatment variation, neither in Lc-Hs or Pla treatments (p < 0.05). However, leptin showed significant differences between Lc-Hs and Pla treatments (p < 0.047), leading to minor leptin synthesis in Lc-Hs subjects (12.06 ± 2.05 ng/mL) than Pla treatment (12.60 ± 2.02 ng/mL). In case of GLP-1, significant differences were observed comparing both Lc-Hs and Pla treatments separately, leading to higher synthesis after the treatment of Lc-Hs treatment (p < 0.05). However, there was not found any difference in subjects treated with Pla. On the other hand, the orexigenic hormone ghrelin—commonly known as the hunger hormone [42]—did not suffer statistically significant variation in neither Lc-Hs nor Pla during the study. However, a downward trend was observed in the subjects from the Lc-Hs treatment. In addition, the determination of insulin followed similar trend than the glycemic curve, according to plasmatic glucose concentration.

To the best of our knowledge, this is the first study to relate satiety measured by both hormones and satiety scales at different times during a stablished time period between meals. Considering evolution is important due to certain hormones such as ghrelin or GLP-1 have short active life span, regulating the amount of food consumed in a certain meal. Analyzing the evolution at different times during the test, there was not found significant difference between treatments in most of hormones (Fig. 8). However, plasmatic variation of adiponectin varied significantly at minute 180 during the test (p < 0.05), leading to higher concentration in subjects treated with Pla (8.77 ± 0.55 µg/mL) than Lc-Hs treatment (8.21 ± 0.5 µg/mL). GLP-1 values were normalized from baseline. Figure 8 shows the treatment with Lc-Hs as determinant factor for the increase of GLP-1 from min 15 (Δ 12.39%) Lc-Hs (1.33 ± 0.21) Pla (1.20 ± 0.19) until the end of the test (Δ 22.36%) Lc-Hs (1.26 ± 0.17) Pla (1.03 ± 0.16).

Obese and overweight population is commonly diagnosed with metabolic syndrome, so clinical and biochemical parameters need to be closely monitored. Table 3 shows glycemic and lipidemic profile of subjects at baseline and at the end of the study (long-term) from both treatments. At baseline, no significant differences were observed between treatments (p > 0.05) and remained stable after 8 weeks, so no significant changes were observed for the glycemic values during the study. Regarding HBA1c, the only remarkable variation occurred intra-treatment in the Lc-Hs treatment only (p < 0.009).

In turn, lipid profile showed minor but remarkable changes. There is a downward trend for cholesterol and LDL values after the consumption of the product under study. The plasmatic variation of LDL cholesterol was significantly minor in subjects from Lc-Hs treatment compared to Pla (p < 0.032). On the other hand, HDL cholesterol increased after the treatment with Lc-Hs compared to Pla, showing statistically significant differences (p < 0.008). However, triglyceride and total cholesterol values, remained at similar values than observed at baseline, regardless the treatment.

Biompedance is a fast, secure, non-invasive and easy to apply method to evaluate body composition [43]. Biompedance values began in similar conditions for both treatments at baseline. BMI evolution did not show significant differences during the study, going from 28.03 ± 2.53 kg/m² to 28.12 ± 2.56 kg/m² in Pla and from 28.26 ± 2.52 kg/m² to 27.98 ± 2.62 km/m² showing a downward trend in Lc-Hs (Fig. 9).

According to the scientific literature, it is convenient to evaluate body weight in its different components, especially separate fat mass and fat-free mass (FFM) [44]. Figure 9 depicts evolution of fat mass and FFM, respectively.

The results showed a reduction in fat mass in Lc-Hs treatment and maintenance of FFM and BMI compared to Pla.

In order to reduce the error caused by personal differences in physical activity, sedentary subjects were exclusively recruited. The measurement of METs min/day by the accelerometer revealed that subjects from both placebo and experimental treatments maintained the same physical activity during the study. Regarding Pla treatment, values ranged (p = 0.418) from 1.7 ± 0.3 MET/min/day at baseline to 1.8 ± 0.3 MET/min/day at the end of the study. In turn, the experimental treatment showed similar values (p = 0.842) both at baseline (1.7 ± 0.4 MET/min/day) and at the end of the study (1.7 ± 0.3 MET/min/day). That fact supports that changes observed in subjects consuming the Lc-Hs extract may be a consequence of such consumption and not a change in physical activity habits.