Evaluating the effect of a water exercise routine on the postural stability of the elderly

Mira, Natali Olaya; Soto Cardona, Isabel Cristina; Martínez Osorno, Laura Vanesa; Mercado Díaz, Darwin Raúl; Henao Ceballos, Luisa María; Mira, Natali Olaya; Soto Cardona, Isabel Cristina; Martínez Osorno, Laura Vanesa; Mercado Díaz, Darwin Raúl; Henao Ceballos, Luisa María

doi:10.25100/cm.v52i3.4537

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Colombia Médica

On-line version ISSN 1657-9534

Colomb. Med. vol.52 no.3 Cali July/Sept. 2021 Epub June 11, 2021

https://doi.org/10.25100/cm.v52i3.4537

Original article

Evaluating the effect of a water exercise routine on the postural stability of the elderly

Natali Olaya Mira¹
http://orcid.org/0000-0001-6915-7784

Isabel Cristina Soto Cardona²
http://orcid.org/0000-0003-0797-9752

Laura Vanesa Martínez Osorno³
http://orcid.org/0000-0002-5576-3836

Darwin Raúl Mercado Díaz³
http://orcid.org/0000-0003-2207-7896

Luisa María Henao Ceballos³
http://orcid.org/0000-0002-5302-5135

^¹ Instituto Tecnológico Metropolitano, Facultad de Ciencias Exactas y Aplicadas, Biomedical Research and Innovation Group - GI2B. Medellín, Colombia.

^²Instituto Tecnológico Metropolitano, Facultad de Ciencias Exactas y Aplicadas, Biomechanical and Rehabilitation Laboratory. Medellín, Colombia.

^³Instituto Tecnológico Metropolitano, Facultad de Ciencias Exactas y Aplicadas, Biomedical Engineering Program. Medellín, Colombia.

Abstract

Background:

Postural stability enables humans to maintain the center of mass of their body within their base of support. Nevertheless, over time, such stability is affected by different factors such as age, repetitive strain, and accidents. Although studies in this field have investigated the effectiveness of hydrotherapy, only a few of them have explored its influence on postural stability, which is reflected in a lack of research that estimates its impact on rehabilitation.

Aim:

To determine the immediate and final effects of an aquatic routine protocol on the postural stability of elderly subjects.

Methods:

The postural stability of 20 adults over 60 years of age was analyzed using electromyographic and baropodometric methods. Electromyographic signals were obtained from the tibialis anterior, soleus, both gastrocnemius, vastus medialis, and biceps femoris to calculate the coactivation percentage of the muscles in charge of postural stability. The baropodometric data were collected to analyze the area of the stabilometric ellipse, mean plantar pressure, and weight distribution percentage.

Results:

The outcome of both methods revealed improvements in the elderly patients after the aquatic routine protocol was applied, which indicates that the type of water exercises implemented in this study has positive effects on their postural stability.

Conclusion:

The postural stability of the elderly participants was improved after each session because their stability index decreased along with the electrical activity of some muscle pairs, their body weight was better distributed, and the area of body oscillation was reduced. However, this effect was immediate and not final.

Keywords: postural balance; stabilometry; electromyography; hydrotherapy

Resumen

Antecedentes:

La estabilidad postural permite a los humanos mantener el centro de masa de su cuerpo dentro de su base de apoyo. Sin embargo, con el tiempo, dicha estabilidad se ve afectada por diferentes factores como la edad, el esfuerzo repetitivo y los accidentes. Si bien los estudios en este campo han investigado la efectividad de la hidroterapia, solo algunos de ellos han explorado su influencia en la estabilidad postural, lo que se refleja en la falta de investigaciones que estimen su impacto en la rehabilitación.

Objetivo:

Determinar los efectos inmediatos y finales de un protocolo de rutina acuática sobre la estabilidad postural de adultos mayores.

Métodos:

Se analizó la estabilidad postural de 20 adultos mayores de 60 años mediante métodos electromiográficos y baropodométricos. Se obtuvieron señales electromiográficas del tibial anterior, sóleo, gastrocnemio, vasto interno y bíceps femoral para calcular el porcentaje de coactivación de los músculos encargados de la estabilidad postural. Los datos baropodométricos se recolectaron para analizar el área de la elipse estabilométrica, la presión plantar media y el porcentaje de distribución del peso corporal.

Resultados:

Ambos métodos mostraron mejoras en los pacientes luego de la aplicación del protocolo de rutina acuática, lo que indica que el tipo de ejercicios acuáticos implementados en este estudio tiene efectos positivos en su estabilidad postural.

Conclusión:

La estabilidad postural de los participantes mejoró después de cada sesión porque su índice de estabilidad disminuyó junto con la actividad eléctrica de algunos pares de músculos, su peso corporal se distribuyó mejor y se redujo el área de oscilación corporal. Sin embargo, este efecto fue inmediato y no definitivo.

Palabras clave: Balance postural; estabilometría; electromiografía; hidroterapia

Remark

1) Why was this study conducted?

This study was carried out to test the effect of an aquatic exercise routine on the stability of the elderly by two different methods: stabilometry and electromyography.

2) What were the most relevant results of the study?

Both methods revealed immediate improvements in the postural stability of the elderly after the application of the routine aquatic protocol.

3) What do these results contribute?

In the decision-making of physiatrists, physiotherapists and other related health personnel when prescribing therapies in the elderly population. They can give priority to those activities that involve aquatic exercises when it is necessary to improve the postural stability of this population in the rehabilitation processes.

Introduction

As a result of better treatments to cure diseases and multiple other reasons, most people’s life expectancy has been extended to 60 years or more. The number of seniors will almost double in the coming years ¹, and they will suffer from conditions such as balance disorders, which lead to musculoskeletal disorders (MSDs) and are generally degenerative. This situation poses serious problems for public health and the overall quality of life ⁽²^,³ because such medical conditions significantly increase the cost of rehabilitation processes if they are not timely prevented or treated ⁴.

Water exercises have proven to be effective and efficient to restore body functions in the short term ⁵^,⁶ because the movements are slower and more predictable than on the ground, providing more significant sensory-motor feedback, balance, stability, and coordination, and facilitating postures such as a standing position ⁷. Nevertheless, few studies so far have examined the influence of water on postural stability, and most of them are anecdotal or biased due to a lack of standardized protocols to evaluate its impact on rehabilitation ⁸.

This study evaluates the postural stability of elderly individuals based on their muscle coactivation and baropodometric variables to assess the immediate and final effects of implementing a water exercise protocol.

In this study, two techniques were employed to assess postural stability. First, muscle coactivation (i.e., the simultaneous contraction of agonist and antagonist muscles) was measured using electromyography ⁹, and its role in maintaining articular stability was demonstrated ¹⁰. Second, a baropodometric platform was used to measure the area of stabilometric ellipse, mean plantar pressure, and weight distribution percentage on the footprint ¹¹; therefore, it was proven that the second technique can be used for quantifying postural control ¹²^,¹³.

Materials and Methods

Type of study

This was a prospective cohort pilot study conducted with a single group of elderly individuals. Participants were recruited from INDER Medellín, an active senior group. The protocol was followed in 12 one-hour sessions over four weeks, and it was finished when the subject abandoned or finished the study.

Population

None of the participants had been diagnosed with joint disorders in lower limbs such as arthrosis or arthritis, disc wounds with radiating pain to lower limbs from L3-S1, neuropathies, neurological disorders (ataxia or multiple sclerosis), cerebellar problems, epilepsy, vertigo, diabetes, peripheral venous insufficiency, severe kidney disease, urinary and/or anal incontinence, open wounds, or amputation of lower limbs. The subjects had to attend the twelve sessions to be included in this study even after being selected. Before their voluntary participation, they signed an informed consent approved by the Ethics Committee of Instituto Tecnológico Metropolitano, which observes the principles established in the Declaration of Helsinki (DoH), as recommended by the World Medical Association ¹⁴.

Exercise protocol

This exercise protocol was followed in a 1.63-meter-deep sports pool at Instituto Tecnológico Metropolitano. The water exercise routine for lower limbs was focused on postural stability and divided into 12 one-hour sessions over four weeks. In each of the four weeks, participants performed different exercises (at least fifteen repetitions after the respective warm-up exercises), as follows: (i) stretching to work on their joint mobility and flexibility; (ii) eccentric joint movements with bipedal standing to improve strength and proprioception; (iii) seated marching workout and stairs with unipedal standing to work on balance and proprioception; and (iv) exercises to identify the joint position (eyes open/closed) with unipedal and bipedal standing for coordination, speed, and functionality.

Signal acquisition

Surface electromyography was used to capture muscle coactivation signals, and a baropodometric platform recorded their plantar pressures. The signals were obtained while the participants were standing on both feet on the platform for 6 seconds before and after the water exercise protocol to calculate all the measurements and obtain 24 signals per subject.

Stability measured by muscle coactivation

The muscle coactivation percentage of the subjects’ self-reported dominant leg was calculated by means of surface electromyography (EMG) of the six muscle groups that are directly involved in the stability of lower limbs: tibialis anterior (TA), soleus (S), gastrocnemius medialis (GM), gastrocnemius lateralis (GL), vastus medialis (VM), and biceps femoris (FB) ¹⁵ (Figure 1A ).

Figure 1 (A) Placement of the electrodes: front (TA, S, and FB muscles) and back (GM, GL, and VM muscles). (B) Area of the muscle coactivation percentage. (C) Baropodometric variables (weight distribution, area of the stabilometric ellipse, and mean plantar pressure).

The protocol of the SENIAM (Surface Electromyography for the Non-Invasive Assessment of Muscles) project was applied to place the electrodes ¹⁶. The signals were acquired with an ML138 differential amplifier connected to a PowerLab 16/35 polygraph manufactured by AD Instruments Inc. A 2-kHz sampling frequency was used, and the signal was preprocessed with LabChart Pro software implementing a 60-Hz notch filter and another passband with a cutoff frequency between 10 and 500 Hz.

Matlab was employed to calculate the coactivation percentage. The signals obtained from the muscles were filtered once again using a fifth-order digital Butterworth bandpass filter with cutoff frequencies between 10 and 300 Hz. The root mean square (RMS) of each resulting signal was calculated with a window of 250 samples and an overlapping of 50 samples. Finally, four muscle groups (VM/BF, T/S, T/GM, and T/GL) were created to be normalized using the following equation:

Xn=X-XminXmax-Xmin (Equation 1)

Where 𝑋_𝑛 denotes the normalized signal; 𝑋, the original signal; and 𝑋_𝑚𝑖𝑛 and 𝑋_𝑚𝑎𝑥, the minimum and maximum values of the original signal, respectively. Afterward, the coactivation percentage between muscles was calculated using Equation 2 ¹⁷.

%COACT=2 × A & B common area B area + A area ×100 (Equation 2)

where % COACT is the coactivation percentage between the agonist and antagonist muscles; A area, the area under the curve of the processed EMG signal of the A muscle; 𝐵 𝑎𝑟𝑒𝑎, the area under the curve of the processed EMG signal of the B muscle; and A & B common area, the region of activity shared by the A and B muscles (Figure 1B) ¹⁷. Note that, when this percentage approaches 100%, stability is low; and, when it tends to 0%, stability is high ¹⁸^,¹⁹.

Stability measured by baropodometry

The pressure platform Ecowalk and its software EcoFoot 4.0 calculated the baropodometric variables in this study. Such measurement system comprises a 67-cm-long, 54-cm-wide portable platform equipped with 2,300 capacitive sensors. After the participants stood on the platform and maintained their standard anatomical position for 6 seconds, the following data were collected: area of stabilometric ellipse, mean plantar pressure, and weight distribution percentage (Figure 1C). Said distribution was calculated as the difference between the anterior and posterior distribution of weight; likewise, the lateral distribution resulted from subtracting 50% from the lateral distribution of the dominant foot because only one foot was measured. The variables mentioned above describe the stability of each participant ¹¹^,²⁰.

Characterization of the captured data

The immediate and long-term effects of this exercise protocol were analyzed. The former were studied by comparing each variable before and after the exercise sessions; and the latter were established by comparing the measurements before the first routine and after the twelfth session. Additionally, the sessions that had a significant influence on the measured variables were examined in detail.

The data were statistically analyzed using SPSS software (version 24). The Kolmogorov- Smirnov test for normality was employed with a significance level of 0.05. Some of the data presented normality, however, a non-parametric test, Wilcoxon signed rank test were applied to all the variables to determine significant differences between the groups of variables mentioned above for each exercise protocol effect.

Results

Snowball sampling, a non-probability technique, was implemented to select, among 42 adults, only 20 participants. As a result, the sample was composed of 17 women and 3 men aged 62.5 ± 9.2. Their data were collected between August and December 2018 to measure the effectiveness of the aquatic exercise protocol in improving postural stability. Six participants abandoned the study after the ninth session for personal reasons or due to incompatibilities in their schedules. No accidents were reported during the implementation of the protocol. The immediate effects of the exercise protocol were analyzed by comparing each one of the measurements before and after every exercise session. In the final effect, the first session before performing the protocol was compared with the twelfth session after performing the exercises.

Immediate effect

Regarding stability by coactivation, only the values of T/GM exhibited a significant difference. The coactivation of the tibialis anterior decreased compared to that of the gastrocnemii (T/GM and T/GL), while the coactivation of VM/BF and T/S increased slightly; hence, only two of the four muscle pairs presented reduced coactivation (Table 1).

Table 1 Immediate effect of the exercise protocol.

Variables		Measurement	Mean ± SD	Median	Kolmogorov-Smirnov Test	Wilcoxon signed rank test
Variables		Measurement	Mean ± SD	Median	P-value	Significance Level	Significant difference
Muscle Coactivation	Vastus Medialis vs Biceps Femoris (%)	Before	42.28 ± 23.12	42.95	0.004	614.0	No
	Vastus Medialis vs Biceps Femoris (%)	After	42.68 ± 21.43	43.57	0.200	614.0	No
	Tibialis anterior vs Soleus (%)	Before	43.25 ± 22.78	42.28	0.005	510.0	No
	Tibialis anterior vs Soleus (%)	After	41.29 ± 24.46	42.95	0.002	510.0	No
	Tibialis anterior vs Gastrocnemius Medialis (%)	Before	44.07 ± 22.62	43.65	0.002	33.0	Yes
	Tibialis anterior vs Gastrocnemius Medialis (%)	After	39.29 ± 22.13	40.64	0.007	33.0	Yes
	Tibialis anterior vs Gastrocnemius Lateralis (%)	Before	44.19 ± 24.45	47.35	0.000	224.0	No
	Tibialis anterior vs Gastrocnemius Lateralis (%)	After	41.39 ± 24.89	41.30	0.003	224.0	No
Stabilometry	Anteroposterior weight distribution (%)	Before	27.15 ± 17.18	24.20	0.007	128.0	No
	Anteroposterior weight distribution (%)	After	29.16 ± 17.31	27.60	0.044	128.0	No
	Lateral weight distribution (%)	Before	20.37 ± 13.83	18.10	0.001	218.0	No
	Lateral weight distribution (%)	After	22.06 ± 15.23	19.90	0.000	218.0	No
	Area of ellipse (cm²)	Before	14.16 ± 27.40	3.99	0.000	21.0	Yes
	Area of ellipse (cm²)	After	16.52 ± 22.79	8.40	0.000	21.0	Yes
	Mean pressure (kPa)	Before	22.71±12,07	19.25	0.000	12.0	Yes
	Mean pressure (kPa)	After	21.26±11.74	19.00	0.000	12.0	Yes

When postural stability was determined by means of baropodometry, only the ellipse area and mean pressure exhibited significant differences, the latter being the only one that did not show an increase after the protocol was applied (Table 1). Additionally, more body weight was distributed on the right foot in 54% of the population, and on the hindfoot in 86% of them.

Final effect

The stability by coactivation of the VM/BF muscle pair was the only variable that decreased in the long term, although it showed no significant difference after the entire exercise protocol (Table 2).

Table 2 Final effect of the exercise protocol.

Variables		Measurement	Mean ± SD	Median	Kolmogorov-Smirnov Test	Wilcoxon signed rank test
Variables		Measurement	Mean ± SD	Median	P-value	Significance Level	Significant difference
Muscle Coactivation	Vastus Medialis vs Biceps Femoris (%)	Before	43.84 ± 22.99	42.96	0.200	925.0	No
	Vastus Medialis vs Biceps Femoris (%)	After	40.89 ± 20.05	34.13	0.123	925.0	No
	Tibialis anterior vs Soleus (%)	Before	44.89 ± 21.12	37.13	0.042	221.0	No
	Tibialis anterior vs Soleus (%)	After	35.14 ± 24.44	40.40	0.200	221.0	No
	Tibialis anterior vs Gastrocnemius Medialis (%)	Before	33.55 ± 19.34	30.71	0.156	433.0	No
	Tibialis anterior vs Gastrocnemius Medialis (%)	After	42.28 ± 22.39	36.11	0.052	433.0	No
	Tibialis anterior vs Gastrocnemius Lateralis (%)	Before	41.79 ± 29.03	41.71	0.015	975.0	No
	Tibialis anterior vs Gastrocnemius Lateralis (%)	After	39.92 ± 25.36	41.10	0.200	975.0	No
Stabilometry	Anteroposterior weight distribution (%)	Before	33.13 ± 20.24	24.3	0.030	221.0	No
	Anteroposterior weight distribution (%)	After	25.94 ± 15.28	23.9	0.200	221.0	No
	Lateral weight distribution [%]	Before	27.53 ± 17.31	19.7	0.034	158.0	No
	Lateral weight distribution [%]	After	19.60 ± 16.07	14.40	0.145	158.0	No
	Area of ellipse (cm²⁾	Before	3.60 ± 6.70	1.02	0.001	8.0	Yes
	Area of ellipse (cm²⁾	After	19.18 ± 22.68	8.93	0.054	8.0	Yes
	Mean pressure (kPa)	Before	28.64 ± 7.37	19.85	0.200	221.0	No
	Mean pressure (kPa)	After	16.34 ± 9.47	12.90	0.138	221.0	No

As in the case of the immediate effect measured by baropodometry, the area of the ellipse presented a significant difference. Nevertheless, the mean pressure did not, which was reflected in a decrease in all the variables, except for the area of the stabilometric ellipse (Table 2). Additionally, more body weight was distributed on the right foot in 57% of the population, and on the hindfoot in 79% of them.

Discussion

The slightly lower coactivation of most of the calf muscles that was found in this study may indicate an immediate improvement of the postural stability of the elderly after the water exercise protocol was applied. Such muscles are directly involved in the stability of lower limbs because they are located close to the ankle joint ²¹, closer than the VM/BF muscle pair in the thigh, which has no direct influence on the postural stability of lower limbs. Additionally, studies suggest that the coactivation of the T/S muscles decreases mainly after an exercise routine on the floor ²²; therefore, water may produce changes in the activation of said group.

Nevertheless, there is no consensus in the field to compare the results of aquatic exercises with those of traditional balance therapy. Some evidence in related works shows there is no statistically significant difference between conventional therapy and hydrotherapy; therefore, regardless of the environment where therapy is performed, an improvement in postural stability can be achieved ²³. Even using other measuring instruments (e.g., Berg Balance scale and the Timed Up and Go test), perceived stability has been reported to be lower when the task is performed in the water compared to on the ground ²⁴^,²⁵.

The results of this study show an immediate increase in lateral and anteroposterior weight distribution, but a slight decrease in mean plantar pressure. This outcome may have expanded the area of the stabilometric ellipse, which is the variable most closely related to postural stability ²⁶.

The final coactivation of the VM/BF muscle pair was reduced, which suggests a general improvement in postural stability. This decrease in coactivation only in the thigh muscles and not the calf could indicate that the final proprioception exercises in the protocol focus more on that area.

It has been shown that stabilometric parameters measured using pressure platforms provide valid information about postural stability ²⁷. All the baropodometric variables in this study exhibited lower values in the long term, except for the stabilometric ellipse area, which is possibly due to the fact that a standard position was not established for participants to place their feet on the pressure platform and their base of support could affect said variable ²⁸.

This study has two limitations: (a) the pool water temperature and the feet posture on the pressure platform were not standardized and (b) there was no control group. As a result, future work should consider factors such as water temperature (typical hydrotherapy pools are between 33.5° and 35.5° C) because this aspect determines the behavior of seniors’ bodies, as the heat transfer starts immediately after the initial immersion, affecting muscular behavior ²⁹. Furthermore, the support base should be measured or normalized as an additional variable related to stability ³⁰.

Conclusion

After the 12-session protocol was completed, the baropodometry and muscle coactivation showed improvements, which indicates that the water exercises considered in this work may have positive effects on postural stability. This protocol can be part of an optimal intervention strategy to prevent falls because it involves training to improve the strength and balance of patients with osteoarthritis, as claimed by Martínez-Amat et al. ³¹.

Acknowledgments:

The authors would like to thank the Laboratorio de Biomecánica e Ingeniería de Rehabilitación at the Instituto Tecnológico Metropolitano for providing the infrastructure and the assistant staff necessary to conduct this study.

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Received: September 07, 2020; Revised: January 30, 2021; Accepted: April 24, 2021

^{Corresponding author:} Natali Olaya Mira. Facultad de Ciencias Exactas y Aplicadas Instituto Tecnológico Metropolitano. Telephone: +574 440 5100 ext. 5266. Email: nataliolaya@itm.edu.co

^{conflicts of interest:}

None declared.

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