The present invention relates, generally, to a method and apparatus for increasing muscle size and strength, as well as lung capacity, at low training intensities by utilizing eccentric ergometry and, more particularly, to a method and apparatus for providing speed controlled eccentric exercise.
It is commonly accepted that at least minimal physical activity is necessary to maintain muscle mass. If such minimal activity is lacking, the muscular system becomes atrophied and muscle mass diminishes. Muscular activity is energetically consuming, i.e. oxygen consumption by the muscular system increases heavily during physical activity. For example, oxygen consumption for a healthy person at rest may increase 10–15 times with physical activity. If an adequate amount of oxygen fails to reach the muscle, physical activity will be limited. Inadequate oxygen delivery may be due to a disorder in oxygen reception in the lungs or to insufficient transport of the oxygen to the muscles. Insufficient pumping of the heart is designated heart insufficiency. Muscle reduction begins in those with heart disease as a result of insufficient activation of the heart muscles. This in turn leads to a further reduction of the pumping performance of the heart thereby resulting in circulus vitiosus. The present invention can be used to interrupt this process or condition.
Stength gains occur when muscle produces force. If the muscle shortens while producing force, it produces concentric (Con) positive work. If it lengthens while producing force, work is done on the muscle resulting in eccentric (Ecc) negative work. A muscle action is designated “concentric” if the force of a muscle overcomes an applied resistance and a muscle action is designated “eccentric” if the muscle force is less than the applied resistance. “Acceleration work” results from concentric contractions and “deceleration work” results from eccentric contractions. For example, one may imagine that ascending a mountain requires exclusively concentric work and that descending the same mountain requires mostly only eccentric work. From a physical point of view, equal energy is converted in both cases. In ascending, potential energy is gained while in descending, the same amount of energy is lost. Although physically the same energy amounts are converted, the amount of energy to be spent by the muscular system for ascending is much higher than the amount of energy lost in descending. Five to seven times more energy is spent for concentric work as is spent for physically equal eccentric work.
The magnitude of strength gains seems to be a function of the magnitude of the force produced regardless of its Ecc or Con work. Ecc training has the capability of “overloading” the muscle to a greater extent than Con training because much greater force can be produced eccentrically than concentrically. Accordingly, Ecc training can result in greater increases in strength.
Furthermore, the Ecc mode of contraction has another unique attribute. The metabolic cost required to produce force is greatly reduced; muscles contracting eccentrically get “more for less” as they attain high muscle tensions at low metabolic costs. In other words, Ecc contractions cannot only produce the highest forces in muscle vs. Con or isometric contractions, but do so at a greatly reduced oxygen requirement (Vo2). This observation has been well-documented since the pioneering work of Bigland-Ritchie and Woods (Integrated eletromyogram and oxygen uptake during positive and negative work, Journal of Physiology (Lond) 260:267–277, 1976) who reported that the oxygen requirement of submaximal Ecc cycling is only 1/6–1/7 of that for Con cycling at the same workload Typically, single bouts of Ecc exercise at high work rates (200–250 W for 30–45 minutes) result in muscle soreness, weakness, and damage in untrained subjects. Therefore, the common perception remains that Ecc muscle contractions necessarily cause muscle pain and injury. Perhaps because of this established association between Ecc contractions and muscle injury, few studies have examined prolonged exposure to Ecc training and its effect on muscle injury and strength. Nonetheless, Ecc contractions abound in normal activities such as walking, jogging, descending/walking down any incline, or lowering oneself into a chair to name just a few. Obviously, these activities occur in the absence of any muscular damage or injury.
Accordingly, there is a need for providing chronic Ecc training techniques and/or apparatus that can improve locomotor muscle strength without causing muscle injury.
Because muscles contracting eccentrically produce higher force, and require less energy to do so, Ecc training possesses unique features for producing both beneficial functional (strength increases) and structural (muscle fiber size increases) changes in muscles, and especially in locomotor muscles. For example, because Ecc work can overload muscle at Vo2 levels that have little or no impact on muscle when the work is performed concentrically, then strength and muscle size increases might be possible in patients who heretofore have difficulty maintaining muscle mass due to severe cardiac and respiratory limitations. Ecc training may also increase the strength and size of other muscles in addition to locomotor muscles and may also be used to increase lung capacity.
The present invention is directed to an apparatus for performing speed controlled eccentric exercise which includes a frame, at least one support attached to the frame for supporting a user's body, at least one engagement member for engaging a part of the user's body where the engagement member is attached to the frame and moveable in opposite directions, means for supplying power to the engagement so the engagement member can exert a force in a first direction at a predetermined speed, means for detecting any change in the predetermined speed after the user supplies force to the engagement member in a direction opposite the first direction, and means for adjusting the output from the power supply to maintain the original predetermined speed.
In one aspect of the invention, the support may be a seat which in turn may be a seat that is recumbent and/or adjustable. The apparatus may also include a support structure for the seat which is positioned between the seat and the frame.
In another aspect of the invention, the engagement member may comprise a bar press or a turn crank, either of which may further include a pedal Or a hand grip. In addition, a drive mechanism, powered by the power supply, may be attached to the engagement member to move the engagement member. If the engagement member is a turn crank, the drive mechanism may move the turn crank in a counterclockwise direction. Alternatively, if the engagement member is a bar press, the drive mechanism may move the bar press in alternating forward and backward directions.
In yet another aspect of the invention, the apparatus may include a safety element which prevents a user's joints from fully extending and locking while operating the apparatus. The apparatus may also include a control panel for operating the apparatus and a display means for displaying pertinent data. Moreover, the apparatus of the present invention can be used to perform a variety of eccentric exercises including lower body eccentric exercise where the engagement member(s) engage a user's feet or legs and upper body eccentric exercise where the engagement member(s) engage a user's hands or arms.
The present invention is also directed to a method for providing speed controlled eccentric exercise which includes the steps of providing an exercise apparatus capable of applying a force against a user in a first direction at a predetermined speed, allowing the user to resist the force in the first direction by applying a force in an opposite direction, monitoring the user applied force, and controlling the apparatus applied force in response to the user's applied force to maintain the predetermined speed of the apparatus.
In one aspect of the inventive method, the step of controlling the apparatus applied force may include the step of adjusting the apparatus applied force to equal the user applied force.
In another aspect of the invention, the inventive method may further include the step of displaying pertinent data relating to the eccentric exercise such as, for example, deceleration power, time elapsed, a user's heart rate, and a number of revolutions or reciprocations per minute.
In still another aspect of the method of the present invention, the step of providing an apparatus may include the step of providing a recumbent exercise bicycle capable of applying a force against a user in a first direction by providing a torque in a counterclockwise direction or the step of providing an apparatus having reciprocating bar presses.
The present invention will hereinafter be described in conjunction with the appended drawing figures, wherein like numerals denote like elements, and:
The present invention is directed to a method and apparatus for increasing muscle size and strength, as well as lung capacity, at low training intensities utilizing eccentric ergometry. The apparatus of the present invention comprises means for applying a torque transfer to the human muscular system. The apparatus is directed to an eccentric ergometer device 10, shown in
In constructing the embodiment of the eccentric ergometer of the present invention which is depicted as device 10, the power train of a standard Monarch cycle ergometer may be used. The adjustable seat 18 may comprise a recumbent seat and the device 10 may be driven, for example, by a three-horsepower direct current (DC) motor with one or more idlers between the motor 12 and the flywheel 16. The gear ratio from the flywheel 16 to the turning or pedal crank 14 is preferably about 1:3.75. As previously stated, all components are mounted to a steel frame 20 for stability. A motor controller 28 controls the motor speed and preferably has a 0 to 10 Volt output for both motor speed and load. The magnetic sensor 26 monitors pedal revolutions per minute (rpm) which is preferably displayed to the rider/user during the training session The voltage and amperage outputs from the controller 28 are monitored through an analog-to-digital board and dedicated computer. The motor 12 also includes an on/off switch 30 which is accessible by a user in order to switch the device on and off from the position of use. A safety shut off may also be included which may be programmed to automatically shut off the motor once certain predetermined parameters are reached.
In using ergometer device 10, a desired speed is input by a user or computer program so that turning or pedal crank 14 rotates in a counterclockwise direction at the desired speed A user then resists the rotation of turning or pedal crank 14, or in other words attempts to accelerate the device by pedaling in a clockwise direction, and any change in the speed of rotation is sensed and then compensated for by motor controller 28 and motor 12 so that the desired speed, i.e. preset velocity, can be maintained. The ergometer device of the present invention is a speed controlled device which controls and maintains a preset speed by varying the torque of the device in response to the magnitude of torque applied by a user.
The ergometer device 10 can be calibrated by using the original standard ergometers friction band and applying known loads (via weights) as the motor 12 moves the flywheel 16 in a forward direction at a fixed rpm and reading the amperage/voltage of the motor. Therefore, for a fixed load and rpm, the calibration performed in the forward direction also serves to calibrate the reverse direction of the flywheel depending upon the wear that may have occurred in a particular direction.
For purposes of the present invention, the eccentric ergometer device is defined as a powered, recumbent device that is used in the active mode to enable a user to experience eccentric loads. The device may be used to impart an eccentric load on a muscle to increase muscle size and strength, and to increase lung capacity. The active recumbent device includes means for continuously applying a torque through three hundred sixty degrees of rotation for extended periods of time.
Turning now to
Examples of Training Regimens Used With The Embodiment Of The Eccentric Ergometer Device of the Present Invention Shown in
Six Week Training Regimen:
Subjects and training regimen: Nine healthy subjects 18–34 (mean 21.5) years old were assigned at random to one of two exercise training groups: 1) an Ecc cycle ergometer like that shown in
Measurements: To assess skeletal muscle strength changes, maximal voluntary isometric strength produced by the knee extensors was measured with a Cybex dynamometer before, after and during training. Vo2 was measured once a week while training with an open spirometric system with subjects wearing a loose fitting mask. A visual analog scale (VAS) was used to determine the perception of lower extremity muscle soreness. Subjects were asked to report a rating of perceived exertion (RPE) on a scale rating.
The results of the study demonstrated that if the Ecc work rate is ramped up during the first four weeks and then maintained for at least two weeks, strength gains can be made with minimal muscle soreness and without muscle injury as noted by the VAS and no loss in leg strength at any time during the study. In fact, leg strength increased significantly in the Ecc group. (See
With respect to
The strength enhancements using the method and apparatus of the present invention, with very minimal cardiac demand, may have profound clinical applications. Despite improvements in strength and muscle mass with high-intensity resistance training in healthy elderly, many with cardiovascular disease cannot exercise at intensities sufficient to improve skeletal muscle mass and function. Exercise intensity in this population is often severely limited by the inability of the cardiovascular system to deliver adequate oxygen to fuel muscles at levels significantly above resting. For many elderly patients, the symptom inducing metabolic limits have been estimated as low as 3 METS which is equivalent to con cycling at approximately 50 W on an ergometer. Such work rates may be insufficient to adequately stress muscle and prevent muscle atrophy and the concomitant functional decline. This group of patients with chronic heart failure and/or obstructive pulmonary disease could maintain their muscle mass and potentially even experience an increase in muscle strength during their exercise rehabilitation by using the method and apparatus of the present invention.
Eight Week Training Regimen:
Subjects and training regimen: Fourteen healthy male subjects with a mean age of 23.9 years (range, 19–38 years) were systematically grouped to create two groups of seven subjects, each with an equivalent mean peak oxygen consumption (Vo2peak) the two groups were assigned at random to one of the following two groups: 1) an Ecc cycle ergometer like that shown in
Each subject performed a Vo2peak test on a traditional Con ergometer and the subject” peak heart rate (HRpeak) was defines as the heart rate obtained at Vo2peak. Training exercise intensity was set to a fixed and identical percentage of HRpeak (% HRpeak) in both groups of subjects and heart rate was monitored over every training session for the 8 weeks of training. % HRpeak was progressively ramped for both groups in an identical fashion during the training period, from an initial 54% to a final 65% HRpeak. (See
Measurements: All measurements were the same as the six week training regimen discussed above in addition to the following: Total work (joules) on the Ecc ergometer per training session was calculated by integrating the work rate (watts), determined directly from a 0 to 10 volt output from the motor, which was calibrated to a known work rate, over the total duration of each training session. The total work per training session was calculated on the Con recumbent ergometer by multiplying the work rate displayed on the calibrated ergometer by the duration of each training session. A single needle biopsy from the vastus lateralis at the midthigh level was taken 2 days before the beginning of the study and 1–2 days after the eight week study ended to measure muscle fiber ultrastructure and fiber area. The capillary-to-fiber ratio was determined by counting the number of capillaries and fibers via capillary and fiber profiles from electron micrographs.
Ecc and Con cycle ergometry training workloads increased progressively as the training exercise intensity increased over the weeks of training. Both groups exercised at the same % HRpeak, and there was no significant difference between the groups at any point during training. But, the increase in work for the Ecc group was significantly greater than the Con group as shown in
This study demonstrates that if the training exercise intensity is ramped up and equalized for both groups over the first 5 weeks and then maintained for three additional weeks, then large differences in muscle force production, measured as total work, result comparing the significant increases in isometric strength and fiber size, neither of which occurred in the Con group.
The method and apparatus of the present invention enable an Ecc skeletal muscle paradigm that can be used in clinical settings to deliver greater stress to locomotor muscles (workloads exceeding 100 W), without severely stressing the oxygen delivery capacity of the cardiovascular system. Patients with chronic heart failure and/or obstructive pulmonary disease could at least maintain their muscle mass and perhaps even experience an increase in muscle size and strength using the method and apparatus of the present invention. The method and apparatus of the present invention may also function to increase lung capacity in patients with respiratory limitations.
Another embodiment of an eccentric ergometer in accordance with the present invention is shown in
Recumbent seat 88 is preferably an adjustable recumbent seat so that device 80 can be adjusted to accommodate the different leg length of various users. Further, recumbent seat 88 is securely positioned at an optimal angle of about 15 degrees with respect to turning crank 84 so that the user experiences an effective eccentric load on the user's muscles. However, it should be understood that the seat angle is directly related to the height of the pedals and therefore may vary somewhat depending upon the exact configuration of the device. In device 80, recumbent seat 88 is made adjustable by attaching it to a support 96 which includes a first tube member 98 connected to a second tube member 100, and a third tube member 102 connected to second tube member 100. The bottom 103 of recumbent seat 88 is connected to third tube member 102, and the back 104 of recumbent seat 88 is connected to second tube member 100. First tube member 98 is hollow and fits circumferentially around one of the tubular members 94 of frame 82 thereby enabling recumbent seat 88 to move forward and backward along the length of the tubular member 94 which it surrounds. First tube member 98 includes at least one aperture 106 which is in alignment with a plurality of apertures 108 contained in the tubular member 94 which first tube 98 surrounds so that recumbent seat 88 can be locked into position by inserting a locking piece through aperture 106 and one of the plurality of apertures 108 in tubular member 94.
Although an exemplary embodiment of an adjustable recumbent seat has been described, it will be understood by those in the art that a variety of structures and configurations may be used to make recumbent seat 88 adjustable with respect to frame 82 and that the structures and configurations used will depend upon the structures and configurations used for frame 82. Recumbent seat 88 may also include a pair of arms 110. Although arms 110 in device 80 are connected to third tube member 102, the present invention contemplates a variety of configurations and connection points for arms 110 of recumbent seat 88 depending upon the structure and configuration of support 96. In addition, arms 110 may further comprise grip covers 111 for assisting a user in securing their grip of arms 110 during operation of the device.
The speed controlled eccentric exercise apparatus of the present invention may include a safety element which prevents users from reaching full extension at the knees while operating the apparatus. Device 80 includes bar member 90 which is connected to third tube member 102 of support 96 by way of a fourth tube member (See
Visual display device 92 is connected to frame 82 and may be programmed to display a variety of data including, but not limited to, deceleration power, time elapsed, a user's heart rate, pedal revolutions per minute, intensity level, speed, and measurement of work performed.
Pedals 86 may further comprise straps 112 for securing a user's feet to pedals 86. Straps 112 prevent a user's feet from slipping off pedals 86 during operation of device 80.
An enlarged schematic layout of an exemplary embodiment of control panel 89 of device 120 is shown in
Turning now to
An enlarged perspective view of the device motor and turning crank of the device depicted in
Frame 82 is preferably comprised of a steel tubing or a similar durable material that is resistant to damage and wear. Alternating current or direct current type motors may be used for motor 170.
As described above, the embodiment shown in
Further, it will be understood by those skilled in the art that various other configurations of the apparatus may be designed in order to effectively exercise other muscles of a user's body in an eccentric manner. For example, the same elements which comprise the previously described eccentric ergometers may be repositioned and/or configured in a different way in order to effectively exercise the various muscles of the back in an eccentric manner.
The foregoing description is of exemplary embodiments of the subject invention it will be appreciated that the foregoing description is not intended to be limiting; rather, the exemplary embodiments set forth herein merely set forth some exemplary applications of the subject invention. It will be appreciated that various changes, deletions, and additions may be made to the components and steps discussed herein without departing from the scope of the invention as set forth in the appended claims.
This application is a continuation-in-part application of U.S. application Ser. No. 10/203,909 filed Oct. 29, 2002 which claims the benefit of U.S. Provisional Application No. 60/185,623, filed Feb. 29, 2000, which is incorporated herein by reference.
Financial assistance for this project was provided by the U.S. Government through the National Science Foundation under Grant Number IBN9714731; and the United States Government may own certain rights to this invention.
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Number | Date | Country | |
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20040082438 A1 | Apr 2004 | US |
Number | Date | Country | |
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Number | Date | Country | |
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Parent | 10203909 | Oct 2002 | US |
Child | 10650455 | US |