Index

Introduction
Methods
Results
Discussion
Conclusion
References

Abstract

Many studies have researched the influences of energy drinks (Edrinks) on the central nervous system, balance, and neuromuscular control. Understanding the neuromuscular adaptations that occur after drinking Celsius Edrinks on muscle fatigue and balance can be helpful when advising the use of Edrinks during physical activity. This study aims to understand the impact Celsius Edrinks has on neuromuscular adaptations in lower limb musculature during muscle fatigue, and balance in young, healthy adults. Two males and eighteen females were recruited for this study. The tibialis anterior, gastrocnemius, and Gluteus Medius neuromuscular data were captured with surface EMG electrodes. The number of single-leg heel raises repetitions and time to fatigue were recorded. Subjects were asked to perform single-leg heel raises to fatigue and single-leg balance activities pre-energy drink consumption, and the same tasks were repeated on the opposite not tested limb (post Edrinks consumption) to equate data points. Neuromuscular timing data suggested modifications on leg musculature. Although not significant, the amount of single-leg heel raises performed pre, and post-drink intake increased post-energy drink consumption. We infer that the ingredients in Celsius energy drinks, including caffeine, Taurine, and Guarana, alter nerve conduction velocity in lower limb musculature during exercise and balance activities. Future studies should research the influence of Celsius energy drinks in different scenarios and populations.

Keywords: Energy drink ingredients, Motor control, Muscle delay, Muscle fatigue, Static balance.

Received: 25 July 2022 / Revised: 8 September 2022 / Accepted: 23 September 2022 / Published: 5 October 2022

Contribution/ Originality

This work's main contribution is identifying minimal neuromuscular adaptations to a fatigue test after celsius energy drinks intake in healthy young adults. Particularly, this investigation identified trends towards nerve conduction velocity variations during exercises and balance activities associated to the different ingredients in said drink such as caffeine.

1. INTRODUCTION

An Energy Drink is a beverage typically containing stimulant ingredients, caffeine, and other additional dietary supplements. Energy drinks (Edrinks) are commonly marketed as products that boost energy by improving mental alertness and physical performance. In 1949, the first energy drink appeared in the United States after a chemist in Chicago created Dr. Enuf. However, energy drink popularity didn't take off until RedBull arrived in the United States in 1997. Since then, multiple brands have risen on the market; global energy drink sales reached $57.4 billion in 2020. The industry is expected to grow by a compound annual growth rate of 7% between 2020 and 2025 (Fontinelle, 2021). The issue is these beverages have been under the spotlight since they started gaining popularity. According to Harvard T.H. Chan School of Public Health, Energy Drinks may increase the risk of various health issues, such as poor mental health, tooth decay, diabetes, and high blood pressure. The Drug Abuse Warning Network report calculates that an energy drink includes 80 to 500 milligrams of caffeine, contrasted to about 100 mg in a 5-ounce cup. According to the Food and Drug Administration (FDA), the recommended amount of caffeine not associated with negative side effects is 400 mg daily. Studies have tied energy drinks to negative effects on the cardiovascular system, such as abnormal heart rhythms. It was also tied to an increase in blood pressure and the release of catecholamines, a stress hormone released by the adrenal gland. These hormones are considered a risk factor for cardiovascular complications (Svatikova et al., 2015). Regardless of the documented difficulties, The National Center for Complementary and Integrative Health declared that energy drinks are the most outstanding dietary supplement consumed by teens and young adults in the United States after multivitamins (NCCIH, 2018).

On the other hand, some of the ingredients such as Taurine, an amino acid found in most energy drinks, whose occurrence in these beverages is similar to caffeine, are associated with positive outcomes (Yunusa & Ahmad, 2012). Taurine improves endurance and reduces lactic acid build-up post-exercise. It also helps with nerve growth and is thought to activate the parasympathetic, leading to a decrease in heart rate. Some brands of energy drinks have Taurine as one of their ingredients, which significantly increased upper body muscle endurance (Forbes, Candow, Little, Magnus, & Chilibeck, 2007). An additional benefit of energy drinks is the correlation with favorable performance during physical activity. A randomized control trial tied Celcius energy drink to a decrease in fat mass and percentage of body fat and increases in VO2peak when used in conjunction to exercise (Lockwood et al., 2010). Another study showed significant improvements in time to exhaustion for endurance performance, which was on average 24.2% over controls, and the rate of perceived exertion was also lower in people who drank coffee. Higgins, Tuttle, and Higgins (2010). Some studies pointed out that consumption of 16oz of energy drinks causes an increased tendency to postural instability after consuming 16oz of energy drinks (Rosario, Collazo, Mateo, Gonzalez-Sola, & Bayron, 2017). Additionally, Rosario, Jamison, and Hyder (2020); Rosario, Clare, Lauren, and Ashley (2021) in their study, mentioned that energy drinks created neuromuscular adaptations in lower limb musculature (2020, 2021a) and gait modifications (2021b). The current study examines the effects of Celsius energy drinks on neuromuscular adaptation in the lower limb during muscle fatigue. Celsius beverages are gaining popularity among students by offering a healthier alternative with no sugar and no preservatives (https://www.celsius.com/). Celsius caffeine content is above average compared to most energy drinks, with 200mg per serving. Celsius advertised its science as backed by college studies showing that the drink can help reduce body fat and increase peak VO2 Max (Lockwood et al., 2010). Our study investigates the role of Celsius in lower limb neuromuscular adaptations during balance and muscle fatigue. We hypothesized that Celsius would provoke minimal neuromuscular change after muscle fatigue in young, healthy individuals.

2. METHODS

2.1. Participants

Participants were recruited by convenience sampling at Texas Woman’s University (TWU) - Dallas campus. Twenty total subjects (18 females and 2 males) participated in this study, with a mean age of 23.25 (+/- 1.59 years, Table 1a) and a BMI of 25.91 (+/- 4.93, Table 1a).

2.2. Study Criteria

Inclusion Criteria: Healthy participants were recruited from both genders at TWU between the ages of 22 and 28. This particular age range was selected based on the popularity of Edrinks among college students (Burrows, Pursey, Neve, & Stanwell, 2013).
Exclusion Criteria:Participants were excluded if they met any of the following criteria: allergy to any ingredients in Celsius energy drinks, or participants reported unwanted side effects following energy drink consumption in the past.

2.3. Procedures

The IRB approved this study, and all participants signed the informed consent before testing and screening. Subjects eligible to participate in the study were instructed to withhold the ingestion of stimulants, including coffee and/or energy drinks, for at least 12 hours prior to the date of data collection. At the beginning of data collection, demographic information and baseline vitals were collected. Participants' dominant leg was then determined by applying a perturbation from behind, and whichever leg was utilized during the stepping strategy was identified as the dominant leg. Muscle activation data was collected using the Delsys, Inc surface electromyography (EMG) system. The EMG surface electrodes were placed on the participants' Tibialis Anterior (TA), Gastrocnemius (GA), and Gluteus Medius (GMED) muscles. The subjects were randomly instructed which leg to place the sensors on first, to prevent every subject from placing the sensors on their dominant leg first. Balance data was collected using the Opal Mobility Lab system. The Mobility Lab sensors were placed around the participants' ankles, wrists, and lumbar spine.

Pre-Energy Drink Consumption: The subjects' baseline vitals, including heart rate, blood oxygen saturation, and blood pressure, were monitored in the resting, sitting position. Participants then had EMG electrode sensors placed on leg (tibialis anterior and gastrocnemius) and gluteal region (gluteus medius) in their proper positions. Subjects were asked to perform a maximal contraction assessment to get a baseline before the single-leg balance and muscle fatigue tests began. Before the muscle fatigue test, the subjects were then taken through the single-leg balance test.

Single leg balance test protocol: the participants were instructed to perform a single leg stance on a firm surface with eyes open for 10 seconds, and then a single leg stance on a foam surface for 10 seconds with eyes open. Next, the muscle fatigue test was conducted.

Muscle fatigue test protocol: the participants were instructed to perform as many calves raises (ankle pumps) as possible, and a metronome was used to set a consistent tempo for every participant. The subject could use two fingers to balance on a chair if needed, but was instructed not to put any weight through their fingers. The test was terminated when the subject could not complete more calf raises, if the subjects' tempo differed from the metronome, and/or if the participants' form began to deteriorate. After the muscle fatigue test, the single-leg balance test protocol was again conducted. Muscle activation was recorded using the EMG sensors, and balance data were collected using the Mobility Lab sensors.

Post-Energy Drink Consumption: Subjects consumed one 12 fl oz standard Celsius energy drink within 5 minutes. Each participant set a timer for 30 minutes after they finished their Celsius energy drink. After 30 minutes, each participant's vitals were recorded, including their heart rate, blood oxygen saturation, and blood pressure in the resting or sitting position. The EMG sensors were placed in their proper positions on the opposite leg than the one used for the pre-energy drink consumption tests. The maximal contraction assessment was repeated, and then the participants began the single-leg balance tests and muscle fatigue test protocol in the same order as pre-energy drink consumption.

Participants performed two single-leg balance tests, one muscle fatigue test before consuming an energy drink, two single-leg balance tests, and one muscle fatigue test after consuming the energy drink. Data on neuromuscular timing and strength were collected from all three muscles on both legs of every participant using the Delsys, Inc EMG system. In addition, balance data was collected on every participant using the Mobility Lab sensors during the single-leg balance tests Figure 1 summarizes the protocol.

Figure 1. Study protocol.

2.4. Data Analysis

Electromyography (EMG) was recorded using a surface electrode system (Delsys, Inc. Boston, MA) and processed by EMG analysis for all muscles. The EMG activity of the gluteus medius, tibialis anterior and gastrocnemius muscles was collected at 1,000 Hz with the electrodes placed according to the previously published protocol by Rosario, Pagel, Miller, and Weber (2022). Three data points were identified during the EMG trace and chosen for each muscle during all trials. The variables of interest in this endeavor are the time to onset muscle activation (onset), time to peak activation (TP), decay from peak activation, and duration of muscle activity. The EMG data collection was an average of 3 consecutive activation points for each muscle during all trials and tasks. For the data analysis, this study utilized (Statistical Package for the Social Sciences) SPSS (version 28) with a ANOVA analysis to compare the means for neuromuscular-time variables pre and post fatigue tests. This work examined the impact of Celsius energy drink on muscle performance on all variables of interest (onset, TP, decay, and duration) by comparing single leg stand balance pre and post fatigue and additionally utilizing the same comparative approach pre and post energy drink. In this investigation, we regard a p-value of < 0.05 as statistically significant. Finally, to compare pre and post energy intake data points this study performed a t-test for the repetitions of the calf rise, time to fatigue and heart rate. A p-value of < 0.05 as statistically significant.

3. RESULTS

Table 1a contains the study's demographics, including age, sex, BMI, and height for each energy drink group. All participants were students from the TWU Dallas physical therapy program. Females made up the largest population in this study: 18 females compared to 2 males. Each participant went through the same protocol. The average age of participants was 23.25 +/- 1.59, the average body mass index (BMI) was 25.91 +/- 4.93, 11 participants were right leg dominant, and nine were left leg dominant. Heart Rate (HR), blood pressure (BP), and oxygen saturation (O2 Sat) were measured for every participant at the beginning of the study and 30 minutes after consuming the energy drink. No participants were found to be hypertensive. However, as seen in Table 1b and Table 1c, the average heart rate for participants was lower 30 minutes after consuming the drink than at the beginning of the study. In addition, oxygen saturation was found to be within normal limits for all participants.

Table 1a. Demographic data of all participants.

Characteristics	Study Participants (n) = 20
Age	23.25 +/- 1.59 years
Gender	Male = 2; Female = 18
Height (inches)	64.75 +/- 2.63
Weight (pounds)	155.24 +/- 34.97
Leg Dominance	11 Right; 9 Left
BMI	25.91 +/- 4.93
Leg Dominance	R= 11 L=9

Table 1b. Demographic data of all participants pre drink.

Characteristics	Study Participants (n) = 20
Dominant leg tested Pre Drink	(n) = 8
Non-Dominant leg tested Pre Drink	(n) = 12
Systolic BP (mmHg) Pre Drink	121 +/- 12.48
Diastolic BP (mmHg) Pre Drink	84 +/- 9.23
O2 Sat (%) Pre Drink	98 +/- 0.87
Heart Rate (BPM) Pre Drink	86 +/- 13.358

Table 1c. Demographic data of all participants post drink.

Characteristics	Study Participants (n) = 20
Dominant leg tested Post Drink	(n) = 12
Non-Dominant leg tested Post Drink	(n) = 8
Systolic BP (mmHg) Post Drink	124.85 +/- 11.4
Diastolic BP (mmHg) Post Drink	87.2 +/- 9.13
Sat O2 (%) Post Drink	98.53 +/- 0.96
Heart Rate (BPM) Post Drink	78 +/- 10.54

Table 2a compares EMG timing (seconds) for GMED, GA, and TA during Single Leg Balance on Firm Surface Pre-Edrink and Pre/Post Ankle Pumps. Results of a MANOVA were performed to compare all variables. The significance level was set at p≤0.05.

Glut Med	Firm Surface, Pre-Edrink, and Pre-Ankle Pumps Means and SD	Firm Surface, Pre-Drink and Post-Ankle Pump Means and SD	P-Value
Onset	7.719 +/- 0.377	7.520 +/- 0.269	0.192
TP	0.260 +/- 0.126	0.313 +/- 0.068	0.252
Decay	0.301 +/- 0.071	0.330 +/- 0.136	0.550
Duration	0.561 +/- 0.159	0.644 +/- 0.113	0.195
Gastroc	Means and SD	Means and SD	P-Value
Onset	8.163 +/- 0.242	7.568 +/- 0.335	<0.001
**TP	0.510 +/- 1.059	0.399 +/- 0.133	0.745
Decay	0.326 +/- 0.099	0.279 +/- 0.087	0.272
Duration	0.057 +/- 0.961	0.678 +/- 0.189	0.737
Tibialis Ant	Means and SD	Means and SD	P-Value
Onset	7.702 +/- 0.383	7.594 +/- 0.437	0.562
**TP	0.347 +/- 0.138	0.340 +/- 0.107	0.893
Decay	0.396 +/- 0.219	0.676 +/- 1.108	0.443
Duration	0.743 +/- 0.311	0.260 +/- 1.331	0.279