SciELO - Scientific Electronic Library Online

 
vol.22 issue3Motherhood and intrafamilial child sexual abuse: to guarantee a protective embraceGroup process and psychologist work in primary health care author indexsubject indexarticles search
Home Pagealphabetic serial listing  

Journal of Human Growth and Development

Print version ISSN 0104-1282

Rev. bras. crescimento desenvolv. hum. vol.22 no.3 São Paulo  2012

 

ORIGINAL RESEARCH

 

Aquatic gait modulation by resistance and its effects on motor behavior

 

 

Vanessa Z. RebutiniI; Elisângela V. RodriguesII; Leonardo MaiolaIII; Vera L. IsraelIV

IMestre pelo Programa de Pós-Graduação em Educação Física, Universidade Federal do Paraná (UFPR), Curitiba, PR - Brasil
IIMestre pelo Programa de Pós-Graduação em Educação Física, Universidade Federal do Paraná (UFPR); Docente no Instituto Federal do Paraná, Curitiba, PR
IIIAluno do Programa de Pós-Graduação em Educação Física, Universidade Federal do Paraná (UFPR), Curitiba, PR - Brasil
IVDoutora, Centro de Estudos do Movimento e Postura Humana (CEMPH), Universidade Federal do Paraná - Litoral (UFPR-Litoral), Matinhos, PR - Brasil

Corresponding author

 

 


ABSTRACT

The aquatic environment causes many modifications in motor gestures, changes directly linked to the characteristics and physical principles that govern this medium. Gait is a functional motor act acquired in childhood, repeated and automated. The objective of this study was to identify how the resistance of the water interferes with the motor behavior in aquatic gait.
METHODS: a review was carried out using the Bireme database (LILACS, IBECS, MEDLINE, Cochrane Library, SciELO). The articles studied showed that gait could be defined and influenced by its historical evolution, the variables of the water environment (depth, density, flow) and the characteristics of the body being displaced (shape, composition, weight, etc). The findings point to a somatosensory response that is enabled by the action as a function of the composition, shape, weight, etc.

Key words: water; gait; kinematics; motor activity.


 

 

INTRODUCTION

Studies involving human movement in an aquatic medium have great relevance on research concerning training and rehabilitation, due to the different physical and mechanical properties that this medium imposes1. Of these properties, the resistance of the water stands out, a determinant characteristic when one considers the diverse displacements possible in this medium.

The displacement performance in an aquatic medium can be described by the interaction the body has with the water, aimed at overcoming the resistance offered by the water. One of the most influential negative resistive effects is the hydrodynamic drag, defined by the action of the water in opposing displacement of the immersed body2. This drag is enabled by the relationship between the shape or area of frontal contact of the immersed body and by the speed with which the body displaces itself3,4, a relationship which occurs in quadratic proportions, that is, the resistance increases exponentially with increment in velocity5.

Another effect to be considered is that of viscosity, which results from the interaction and grouping of the molecules according to their thermal agitation2, which depends on the temperature of the water, turning into a factor that makes displacement in the medium easier or more difficult6. In addition to the factors cited above, turbulent flow, characterized by the disorganized movement of the water, also acts as an element resistive to displacement in this environment, although its action will favor displacement when the direction of flow is equal to that of the movement, and make it more difficult when contrary to the movement7.

The resistive action of an aquatic medium also provides what is known as active drag - a propulsive movement created by the body itself during displacement due to movement of the limbs. Such a propulsive movement can be explained by the following theories: the first is based on Newton's third law (action and reaction) and establishes propulsion of the bodies due to the reaction of the water to the movement (on pushing the water backwards, this exerts a force of equal magnitude to push the bodies forward; the second theory is based on Bernoulli's principle which defines the existence of a sustaining force created by the difference in pressure between the opposite sides of the hands when moved "sweeping" the water: a greater pressure on the palm and lower pressure on the back of the hand (the pressure difference produces a sustaining force perpendicular to the direction of the flow of water over the hands, pushing the body forward), subject to the influence of the angle of action of the hands in movement, this being principal or auxiliary3.

One of the possible forms of displacement in an aquatic environment, which comes under the action of the properties described above, is gait: a fundamental motor ability and the habitual motor gesture automated, composed of integrated movements of the body and defined by successive disequilibria of the body which determine the movement forward8. In normal human beings, the gait pattern is acquired and developed in infancy, such that the sensory motor system becomes highly adapted and automatically generates a repetitive group of motor control commands for the segments, allowing the person to walk without conscious effort1.

Although this is a complex, automated act of daily life, gait can suffer interference and modification of the patterns of movement according to the type of surface and environment where it is carried out9. For the study of gait, the parameters are used from the biomechanical (linear and angular/ articular kinematic variables: speed, displacement, acceleration, etc.), motor behavioral (orientation or postural control, manipulation and locomotion - movement patterns, ability level) viewpoints and by the interaction between them.

Angular displacement, for example, describes the amplitudes of the articular movements during gait. The kinetic variables include the ground reaction force and the moments of force, power and work of the articulations during movement10. The kinematic, dynamic or neuromuscular modifications are what determine the interference in the medium in which the movement takes place10, allowing for conclusions and proposals for the mechanism of this influence.

In the aquatic environment, as on land, gait is carried out with the individual in the vertical position, with variations in direction and sense2. Due to the physical properties of the water described above, the behavior of the gait variables in the water are differentiated from those on land and also between different depths of water11, determining adjustments that vary according to the characteristics of the individual and his age12. Gait can be facilitated if the water temperature is higher, hence decreasing the viscosity; for its part, active drag can determine greater gait efficiency according to the application of the propulsive limb - in this case, with the help of the arms. Thus, be it facilitating or offering resistance to the execution of the movements, the aqueous medium demands that adjustments be made in relation to the terrestrial motor behavior of the individual, such as greater activation of the spinal and femoral rectus erectors13.

The observable adjustments defined by the aquatic and terrestrial media can be evaluated from the biomechanical and motor behavior viewpoints. To date there has been greater emphasis on studies from the biomechanical perspective, with few studies that argue from the motor behavior viewpoint specifically in the aquatic medium.

Thus the objective of the present study was to verify how aquatic resistance promoted adequacies of motor behavior in aquatic gait.

 

METHODS

This was a survey of the databases carried out in the period from September 2010 to November 2011 using the Bireme databases (covering the following databases LILACS, IBECS, MEDLINE, Cochrane Library, SciELO), with the objective of finding studies related to gait in aquatic and terrestrial environments. Initially the following keywords, found in the DeCS system, were chosen: flow mechanics, gait, biomechanics, motor behavior and physical aquatic, combined in groups of three words for the survey. This choice of keywords resulted in 68 articles, of which 35 were excluded and the remaining 33 did not cover studies on gait in an aquatic environment, this being the reason for abandoning this survey.

New searches were carried out with the keywords water, walking and kinematics, used in a single search. Initially 36 publications were identified, potentially eligible for the present review. The inclusion criteria were: availability of free access online or via the Capes gateway, research carried out with human beings, papers published in the last 10 years, studies published in Portuguese or English and studies carried out in both aquatic and terrestrial media.

Articles that, from the reading of the titles and summaries, conformed with the exclusion criteria, were then excluded, as follows: studies carried out more than ten years ago (8 articles), those carried out with animals (9 articles), and studies with populations with co-morbidities of the central nervous system and/or musculoskeletal system (3 articles).

The remaining 16 articles were divided at random, in equal numbers between the authors, grouped according to research objective and described in chronological order.

 

RESULTS

The studies found were grouped according to their research objectives in addition to their chronological sequence: AG - aquatic gait, muscular and kinematic activities (5 articles); VG - gait on variable terrains with biomechanical differences (3 articles); CAT - comparison of aquatic and terrestrial gait (4 articles); AAG - anthropological analysis of human gait (2 articles); OT - others (2 articles).

 

 

The articles in group AG showed there was an increase in muscular activation in the aquatic environment due to: movement load and speed5; water flow speed and stability14; displacement and posture13; positioning of the upper limbs, influence of weight, immersion level, body area and speed11.

With respect to variations in terrain and mechanical differences (VG), the articles showed that the interferences that altered the movement parameters could be: the slope and modification in composition of the surface moved on15; the addition of a double task, cognitive and/or concomitantly motor, with or without adjustment by feedback16. However, results were also found that showed similarity in behavior for the kinematic factors between irregular and flat surfaces.

When the two types of media in which gait can be carried out, aquatic and terrestrial, were compared (CAT), the articles presented a variation in articular moments according to the difference in body load, influenced by the media6; the reduction in the vertical force values6 and impact of the water18; the increase in articular moments and muscle activations as a function of the increase in displacement velocity in the water19; the reduction in articular amplitude of the movement in the aquatic environment19,18 or its maintenance20; the difference in articular action of the ankle in aquatic gait - flat support18 and the increase in plantar flexion in the rest of the phases19; the variation between the media of the characteristic of execution speed18; the increase in muscle activation to move the body forward in water, against the resistance6.

Finally, the articles that established an anthropological analysis of human gait (AAG) defended that bipedalism originated in order to improve locomotion: reducing the costs of walking on four supports, such that great distances were covered quickly with less wastage21; in the exchange of bipedal locomotion, but with knees and ankles flexed (wasteful in terrestrial gait but facilitating in the aquatic environment), for erect locomotion22.

 

 

DISCUSSION

For enchainment, the articles were discussed according to the groups based on their research objectives and also the organization of the results.

The first studies described considered the characteristics and behaviors of aquatic gait (AG). Miyoshi et al.5 pointed out there were variations in muscle activation that could be influenced by the weight of the body immersed and by the speed with which it displaced itself. The first influence is described as a reduction in somatosensory input related to the action of pushing, whereas the second is described as an increase in the commands coming from higher centers, making it possible to transport the body forward against the resistance of the water.

 

Figure 3

 

 

Figure 4

 

 

Figure 5

 

 

Figure 6

 

The author also explored another question, stating that the commands coming from the higher centers, related to a greater propulsive force, appear to selectively activate the motor neuron of the muscle responsible for the action; that is, the request was direct and selective, it being conceivable to relate it directly to the effort or role of this motoneuron in overcoming the resistance to movement in the water. According to Kotani et al.14 this activation depended on the association between the type of muscle requested (monoarticular/ biarticular) and its function. The authors also established that the variation in time of this activation was related to the existence of a flow of water encountering the body being displaced, and would increase according to the increase in this flow.

With respect to the influence of the weight of the immersed body, which is determined from its characteristics and from the pushing action, Roesler et al.11 confirmed that the immersion level and position of the upper limbs (variation in weight) determined greater responses for the ground reaction force (GRF) during gait. This idea was corroborated by Masumoto & Mercer2, who stated that muscle activation occurred due to the somatosensory input of the weight - a relation characteristic of the body and its consequent pushing action. The authors explained that pushing modified the gravitational action in the aquatic medium, decreasing the ground reactions, and for its part the related somatosensory input. This reduction determines less muscle activation, as well as modifying the influence of the hydrostatic pressure, altering the muscular action mediated by body pressure receptors.

The displacement speed of a body in the water behaves according to the interaction of some factors: the influence of the area of the submersed body and the imposed aquatic resistance, since the relationship of this resistance with the speed is in a quadratic proportion5; and the viscosity of the medium2. This interaction is enabled by the vertical position of the body during gait, since with the increase in frontal area, in resistance and with the interaction between the body and the medium (viscosity), there is a reduction in speed in relation to that in the terrestrial medium2. If the speed is the result of motoneuron activation for a movement23, be it angular or linear, there will be great activation in order to overcome the resistance of the water, which is greater than that of the air2. Some motor and functional adjustments are carried out to increase the speed such as: alteration in posture maintenance by the erector muscles, which stabilize in the frontal plane for low speeds and alternate in the sagittal plane for higher speeds; and a reduction in pace frequency in relation to movement on land, as a consequence of the pushing action and the hydrodynamic drag13.

With respect to variations in the surface (VG), the studies found reported that when a body finds an environment that is different from that in which it developed its gait routine, it needs to carry out potential adaptations, resulting in significant differences in the gait biomechanics15,16. Cham & Redfern15 commented that adaptations carried out to walk on a slippery floor altered the angular moment of the joints, which is associated with the concept of equilibrium in biomechanics. This equilibrium is where the joints assume a stable posture, which, according to Caromano24, is where various forces act on a body in opposite directions and hence annul themselves. This equilibrium is also observed in studies where the people have to carry out two tasks simultaneously16: in the tests applied, the participants had to carry out a task involving reasoning together with a motor action, making adaptations to their posture in the search for equilibrium in order to attain the determined objective.

The comparison of gait in different media and people is a focus of research in human beings, considering the diverse phases of evolution: Preuschoft21 showed an interest in studying the differences in gait in the australopitecos and how this form influenced locomotion in modern times. He showed that in deep waters the energy expenditure in locomotion with the knees flexed, the form of locomotion of the australopitecos, is less than that seen in locomotion in the terrestrial environment. The author attributed this difference to less activity of the gastocnemius and soleus muscles in the aquatic exercise, justified by the absence of contact and consequent vertical forces with the bottom of the swimming pool, during walking in this medium25.

The studies related to the comparison of aquatic and terrestrial gait (CAT) justified the results by relating them to the properties of pushing and hydrodynamic dragging and the viscosity of the water.

Miyoshi et al.19 and Barela et al.20 reported that a decrease in the vertical component of GRF was related to the pushing action, which influences the reduction in the force of impact in the initial support phase in the water. This supports the study of Masumoto & Mercer2 which reported a 71% reduction in body weight when the water was level with the xyphoid process, which could be related to the decrease in the vertical component of GRF. Barela et al. 20 added that the decrease in the vertical component of GRF was related to a decrease in gait speed in water as compared to on land. Considering that the characteristics of area and viscosity contribute to such alterations2, this corroborates the idea that aquatic gait speed is half of that on land26.

However, Barela et al.18 and Barela et al. 20 explained that the difference found between aquatic and terrestrial gaits was not only due to the influence of the medium, but also due to the different speeds used during displacement, the decrease in body weight in water on account of the act of pushing and the changes required to overcome the hydrodynamic drag. According to the principles of hydrodynamics, the movements of segments in water are influenced by the dragging force and by the act of pushing28, differentiating them from movement in the terrestrial environment.

Electromyographic findings define the low speed developed during aquatic gait as a fundamental element to overcome the hydrodynamic drag, and in addition consider that the decrease in weight generates a smaller propulsive impulse for displacement in the water18,20.

According to this reasoning, the decrease in muscular activity during aquatic gait as compared to terrestrial gait is related to changes in the gait: in their study Masumoto et al.27 showed a decrease in pace frequency (approximately 57% in relation to on land) and a decrease in pace length in water in relation to on land. The decrease in muscular activity in water could be related to the act of pushing and to decreases in the force of gravity and hydrostatic pressure which act on the neuromuscular system2.

Barela et al. 18 and Barela et al. 20 found no differences in the amplitude of movement (ADM) of the joints during gait on land and in water, but when considering the segments (feet, legs and trunk) separately, there was a difference, due to maintenance of the limb in a neutral position during displacement in the water in order to overcome the force of drag, corroborating with the study of Ribas et al.1.

Miyoshi et al.19 suggested that the decreases in ankle plantar flexion and knee extension were due to the act of pushing, and that in their study, the knee joint did not show the role of absorbing the impact of the water. In their study Ribas et al. 1 stated that in the initial support phase and final oscillation, knee joint extension was greater on land than in the aquatic environment, and that in the balance phase, knee flexion was greater in the aquatic environment due to the attempt to decrease the frontal resistance of the water.

Miyoshi et al. 19 and Miyoshi et al.6 justified the reduction in body weight of the individual on walking in water, and the increase in force required to move the body in this environment, as being due to, respectively, the act of pushing and the aquatic resistance, specifically the viscosity. They also argued that the increase in angular moment of the hip in the extension during the support phase was due to the impulsive force required to displace the body in the water. Similar responses for the activation of propulsive muscles for walking were found in investigations with fixed speeds (same physiological intensity for the exercise)23,26 in the muscles responsible for the propulsive movement.

When carried out at the same intensity of physiological effort in the two media, the terrestrial gait speed has to be twice the aquatic gait speed23. In the same way, the increase in activity of muscles such as the gastrocnemius, anterior tibial, vastus medius, rectus femoris and biceps femoris in an aquatic medium is due to the increase in resistance imposed to the movement on account of the need to overcome the greater density of the liquid, as compared to that of the air at the same exercise speed on land23,28.

Miyoshi et al.6 focused on the fact that ankle plantar flexion increased when body instability, body weight and speed increased, indicating that greater changes in articular moment are required to maintain the stability against gravity. Miyoshi et al.19 reported increases in articular moments and muscular activations as a function of an increase in displacement speed in the water. These observations suggest that muscular activities can be activated by small changes in the displacement speed in water in relation to that on land, since this could be due to the exponential increase in hydrodynamic drag, which influences the speed of movement during locomotion in water, since the relationship between the force of dragging and the speed of movement is not linear, such that drag increases as a function of the square of the speed28.

The alterations suffered by the body start on its first contact with the medium, but the effects of resistance are only experimented by way of displacement. The articles described in this study established that alterations in motor behavior were based on synesthetic reflexes (vision, touch etc. receptors), movement and load reflexes in the corresponding sensory-motor activations, in the consequent muscle actions and, finally, in changes that could be observed: kinematic (linear, angular), etc. Some limitations were identified in this study: the keywords chosen and used were far from being able to cover the studies corresponding to the areas responsible for producing this knowledge; and only one database was used to survey the articles, thus reducing the number of studies passive to analysis under the conditions specified here. The authors suggest a widening of this research with a greater number of keywords and databases, such that the subject can be discussed at greater depth.

 

REFERENCES

1. Ribas DIR, Israel VL, Manfra EF, Araújo CC. Estudo comparativo dos parâmetros angulares da marcha humana em ambiente aquático e terrestre em indivíduos hígidos adultos jovens. Rev Bras Med Esporte. 2007; 13(6). DOI 10.1590/S1517-86922007000600003.         [ Links ]

2. Masumoto K; Mercer JA. Biomechanics of human locomotion in water: an electomyographic analysis. Exerc Sport Sci Rev. 2008; 36(3): 160-9.         [ Links ]

3. Maglischo E. Swimming Fastest. Human Kinetics. 2003. USA.         [ Links ]

4. Tucher G, Gomes ALM, Dantas EHM. Relação entre a potência mecânica de nado e o rendimento na natação. Rev. Bras. Cienc. Esporte. 2009; 30 (2): 169-180.         [ Links ]

5. Miyoshi T, Nakazawa K, Tanizaki M, Sato T, Akai, M. Altered activation pattern in synergistic ankle plantarflex or muscles in a reduced-gravity environment. Gait Posture. 2006; 24(1): 94-9.         [ Links ]

6. Miyoshi T, Shirota T, Yamamoto SI., Nakazawa K, Akai M. Functional roles of lower-limb joint moments while walking in water. Clinical Biomechanics. 2005; 20: 194 - 201.         [ Links ]

7. Canderolo JM, Caromano FA. Revisão e atualização sobre a graduação da resistência ao movimento durante a imersão na água. Revista Fisioterapia Brasil. 2004; 5(1).         [ Links ]

8. Alonso VK, Okaji SS, Pinheiro MT, Ribeiro CM, Souza HP, Santos SS. Análise cinemática da marcha em pacientes hemiparéticos. Revista Fisio Brasil. 2002;         [ Links ]

9. Mann L, Teixeira CS, Mota CB. A marcha humana: interferências de cargas e de diferentes situações. Arq. Ciênc. Saúde Unipar. 2008; 12 (3): 257-264.         [ Links ]

10. Kirkwood RN, Gomes HA, Sampaio RF, Culham E, Costigan P. Análise Biomecânica das Articulações do Quadril e Joelho Durante a Marcha em Participantes Idosos. Acta Ortop Bras. 2007; 15(5): 267-271.         [ Links ]

11. Roesler H, Brito RN, Haupenthal A, Souza PV. Análise comparativa da marcha humana em solo à subaquática em dois níveis de imersão: joelho e quadril. Revista Brasileira de Fisioterapia. 2004; 8:1-6.         [ Links ]

12. McGibbon CA, Krebs DE. Age-Related Changes in Lower Trunk Coordination and Energy Transfer During Gait. J Neurophysiol. 2001; 85: 1923 - 1931.         [ Links ]

13. Chevutschi A, Lensel G, Vaast D, Thevenon A. An electromyographic study of human gait both in water and on dry ground. J Physiol Anthropol. 2007; 26(4): 467-7. DOI 10.2114/jpa2.26.467        [ Links ]

14. Kotani K, Hirato Y, Ishigaki T, Shimada H, Toda K, Horii K. Biomechanical analysis of walking through a hallway under flooded conditions. J Physiol Anthropol. 2009; 28(1): 23-28.         [ Links ]

15. Cham R, Redfern MS. Changes in gait when anticipating slippery floors. Gait Posture. 2002; 15(2): 159-71.         [ Links ]

16. Verhoeff LL, Horlings CG, Janssen LJ, Bridenbaugh SA, Allum JH. Effects of biofeedback on trunk sway during dual tasking in the healthy young and elderly. Gait Posture. 2009; 30(1): 76-81.         [ Links ]

17. Wade C, Redfern MS. Ground reaction forces during human locomotion on railroad ballast. J Appl Biomech. 2007; 23(4): 322-9.         [ Links ]

18. Barela AM, Stolf SF, Duarte M. Biomechanical characteristics of adults walking in shallow water and on land. Journal of Electromyography and Kinesiology. 2006; 16: 250-256. DOI 10.1016/j.jelekin.2005.06.013        [ Links ]

19. Miyoshi T, Shirota T, Yamamoto S, Nakazawa K, Akai M. Effect of the walking speed to the lower limb joint angular displacements, joint moments and ground reaction forces during walking in water. Disabil Rehabil. 2004; 26(12): 724-32.         [ Links ]

20. Barela AMF, Duarte M. Biomechanical characteristics of elderly individuals walking on land and in water. Journal of Electromyography and Kinesiology. 2008; 18: 446 - 454. DOI 10.1016/j.jelekin.2006.10.008        [ Links ]

21. Preuschoft H. Mechanisms for the acquisition of habitual bipedality: are there biomechanical reasons for the acquisition of upright bipedal posture? J Anat. 2004; 204(5): 363-84.         [ Links ]

22. Kuliukas AV, Milne N, Fournier P. The relative cost of bent-hip bent-knee walking is reduced in water. Homo. 2009; 60(6): 479-88.         [ Links ]

23. Masumoto K, Shono T, Hotta N, Fujishima K. Muscle activation, cardiorespiratory response, and rating of perceived exertion in older subjects while walking in water and on dry land. J. Electromyogr. Kinesiol. 2008;18(4):581-90.         [ Links ]

24. Caromano, FA. Movimentos na água. Revista Fisioterapia Brasil. 2003; 4(2).         [ Links ]

25. Silva, EM; Kruel, LFM. Caminhada em Ambiente Aquático e Terrestre: Revisão de Literatura Sobre a Comparação das Respostas Neuromusculares e Cardiorrespiratórias. Rev Bras Med Esporte. 2008; 14(6). DOI 10.1590/S1517-86922008000600016        [ Links ]

26. Masumoto KS, Takasugi N, Hotta K, Fujishima, Iwamoto Y. Electromyographic analysis of walking in water in healthy humans. J. Physiol. Anthropol. Appl. Human Sci. 2004; 23: 119-127.         [ Links ]

27. Masumoto K, Shono T, Takasugi S, Hotta N, Fujishima K, Iwamoto, Y Age-related differences in muscle activity, stride frequency and heart rate response during walking in water. Journal of Electromyography and Kinesiology. 2007; 17: 596 - 604.         [ Links ]

28. Pöyhönen T, Kyröläinen H, Keskinen KL, Hautala A, Savolainen J, Mälkiä E. Electromyographic and kinematic analysis of therapeutic knee exercises under water. Clin.Biomech. 2001; 16: 496-504. DOI: 10.         [ Links ]

 

 

Corresponding author:
vanerebutini@hotmail.com

Manuscript submitted Nov 05 2011
Accepted for publication Aug 02 2012