BR202015010505U2 - vibrating platform for osteoporosis treatment and prevention - Google Patents

Abstract

Abstract Vibratory Platform for Treatment and Prevention of Osteoporosis Refer to the present utility model patent application to a low amplitude and low amplitude vibratory platform for the treatment and prevention of osteoporosis working with low intensity 0.6 g, 4-stroke displacement. mm and frequency 60 hz, having application in hospital equipment industries as well as in industries producing equipment related to human health, consisting basically of a calibrated motor vibrator (1), affixed by screws or by welding on an upper platform (2) to provide your vibration; a core transformer (3) affixed to the bottom base (4) by screws; an elastic suspension system provided with rubber and / or springs (5); a tubular metal frame (6) for the user's hand rest, which can be attached by welding or bolting to the bottom base (4); structure (6) has an interface (7) with the user (display); and a microcontroller.

Description

VIBRATORY PLATFORM FOR TREATMENT AND PREVENTION OF OSTEOPOROSIS Field of Application [001] This utility patent application refers to a vibrating platform for the treatment and prevention of osteoporosis, provided with a vibrating base, support and support for the patient and a user interface, having application in hospital equipment industries as well as in industries producing equipment related to human health. It is intended to provide a non-drug option for the prevention and adjuvant treatment of osteoporosis and bone fragility. Grounds for patent application Osteoporosis is a disease in which bones become weakened and can break easily, even in minor trauma and daily living activities. The most common forms of osteoporosis are associated with aging, and show a geometric growth in relation to age from 50 years of age. The disease is commonly diagnosed in female patients, however men also suffer from osteoporosis, especially at older ages (after 70 years of age). Its pathophysiology includes, besides genetic inheritance, the fall of estrogens that occur in climacteric women, sedentary lifestyle, reduced dietary calcium intake, the use of harmful medications such as corticosteroids, among others.

[003] The main consequences are fractures, which severely impair the quality of life of patients, and induce high morbidity and mortality, generating high costs for society. Epidemiological studies show that about half of women and 15% of men over 50 will experience at least one osteoporotic fracture during their lifetime. These fractures occur after mild or even spontaneous trauma, and the most commonly affected sites are wrist, vertebrae, hip, humerus and ribs. Both vertebral and hip (proximal femur) fractures are associated with a 6 to 7-fold increase in mortality. While vertebral fractures generate great suffering and produce severe pain that persists for months, hip fractures, because they require surgical correction, greatly increase the risks of the elderly and generate permanent functional disability in most cases.

[004] It is estimated that there are more than 10 million people with osteoporosis in the United States, responsible for about 1.5 million fractures / year, resulting in an expenditure of approximately $ 14 billion / year (1). Brazil has one of the fastest growing elderly populations in the world. There are currently more than 32 million Brazilians, representing 15% of the total population, and our life expectancy is progressively increasing.

Although very consistent data on the epidemiology of osteoporosis in Brazil are not yet available, preliminary data show that our incidence is also high. In the Escola Paulista community in the Vila Clementino neighborhood of São Paulo, there was a high prevalence of lumbar spine osteoporosis in men and women over 70 years old (6). The data were surprising on the femur neck, where 54.6% of women and 43.6% of men had osteoporosis proven by bone densitometry (examination performed to verify bone loss).

In view of the picture presented it is very important to prevent and if not treat osteoporotic disease in order to prevent future fractures.

[007] In addition to nutritional and physical activity guidance, medication use is indicated for bone mass improvement and fracture prevention. Drug treatment should be prolonged (over the years), has undesirable side effects that may limit its use, and represents a high cost for both the patient and public institutions that bear part of this treatment for populations served by the Unified Health System. Health (SUS). Proven, cost-effective alternative treatments are most welcome, especially in our country, with scarce health resources. To this end, the development of methods for mechanical bone stimulation has been studied, among them the effects of "vibration".

Fukada, in 1957, demonstrated the phenomenon of piezoelectricity, advocating that a material exposed to mechanical loads transforms mechanical energy into electrical energy (7). Fukada and his followers understand that bone enjoys these properties, since bone is a perfect energy transducer, the deformation of a bone causes negative stress and positive stress loads, and remodeling would be controlled by this polarity.

Based on these principles, many researchers have studied how low magnitude and low frequency vibration can interfere with bone metabolism, since bone is a piezoelectric material.

[010] Studies measuring the strength in bone of different animal species, which naturally performed their daily activities, demonstrated that small forces were quantified when animals were standing still or sitting and large forces of great magnitude were employed in small animals. activities like jumping, walking, flying. Observing the animals it was found that small magnitude events occur many times a day, and large magnitude and force peaks occur relatively few times a day, suggesting that the history of strength and the stimulus for bone maintenance do not occur. necessarily comes from vigorous movement activities, but of small magnitude of force, for example, the maintenance of posture (8). The activity that the animals performed during the day was measured and translated into measures of strength.

[011] Rubin et al (9) studied the application of mechanical stimulation with low magnitude and low frequency pulses in the lower limbs of adult female sheep in two groups: experimental and control. The sheep from the experimental group were placed on a vibrating platform that vibrated at a frequency of 30 Hz with a vertical oscillation of 0.3 g (where g is the earth's gravitational field). The animals were stimulated for twenty minutes daily, five times a week. After one year of stimulation, there was a 34.2% increase in bone mass in femur bone. Since then, many animal researches have been conducted experimentally to verify the effectiveness of mechanical vibration in bone mass (10, 11,12).

[012] Currently, in the state of the art, there are some recent technologies that work with the idea of a vibrating platform for the treatment of osteoporosis and other diseases related to human bone structure.

Patent Application W02009073898 describes a vibrating platform with dimensions so that a person can stand, sit or lie on it; a first movement inductor positioned under the platform and a joint that transfers the force from the inductor to the platform; oscillating force amplitude and frequency controlling software; and a weight compensating device placed on the platform.

Patent application CN101224159 describes a device for prevention and treatment of osteoporosis by mechanical vibration.

[015] Both patent applications provide a solution for mechanical vibration-based osteoporosis. The present utility model patent application differs substantially from the state of the art mainly in that the vibratory structure of the device is much simpler and low frequency based.

Brief Description of Patent Application [016] This utility patent application refers to a low amplitude and low amplitude vibrating platform for the treatment and prevention of osteoporosis consisting basically of a calibrated motovibrator (1) affixed to it. by bolting or welding on an upper platform (2) to provide its vibration; a core transformer (3) affixed to the bottom base (4) by screws; an elastic suspension system provided with rubber and / or springs (5); a tubular metal frame (6) for the user's hand rest, which can be attached by welding or bolting to the bottom base (4); structure (6) has an interface (7) with the user (display); and a microcontroller.

[017] The motovibrator (1) used on the platform object of the patent application aims to enable the vibration of the upper platform (2) efficiently and at low cost.

[018] The acceleration intensity is adjusted by varying the supply current of the transformer primary (2) by potentiometric means. By means of the motor vibrator (1), the frequency is determined by the number of motor poles and the impact intensity is mechanically determined by adjusting the eccentric masses affixed to the motor vibrator axis (1).

[019] The upper vibratory platform (2) is interconnected to the lower base (4) by rubberized suspension system and / or springs (5).

[020] The present device also comprises a user interface, more specifically a display (7) aiming to enable adjustments of intensity, time, among others.

BRIEF DESCRIPTION OF THE FIGURES Figure 1 illustrates the platform in front view without the side covers.

[2] Figure 2 illustrates the platform in right side view without the side covers.

Figure 3 illustrates the platform in rear view without the side covers.

Figure 4 illustrates the platform in left side view without the side covers.

Figure 5 illustrates the platform in top view without the side covers.

[626] Figure 6 illustrates the platform in bottom view without the side covers.

Figure 7 illustrates the platform in perspective view highlighting the left and bottom side thereof without the side covers.

Figure 8 illustrates the platform in perspective view highlighting the left and bottom side thereof without the side covers. DETAILED DESCRIPTION OF PATENT APPLICATION This utility patent application refers to a low amplitude, low amplitude vibrating platform for the treatment and prevention of osteoporosis, working at a low intensity in the range of 0.6 g. , 4 mm displacement and 60 Hz frequency, consisting of a calibrated vibrator platform vibrator (1), intended for the application of low amplitude mechanical stimulation, mounted on an upper metal platform (2) coupled to the vibratory system by elastic suspension shock absorber, consisting of rubber springs and shock absorbers (5).

[030] The patent-pending platform utilizes motor vibrator (1) for the purpose of enabling platform vibration efficiently and at low cost.

[031] During the Research and Development project, the use of a motor vibrator was chosen, due to the affordable cost and good availability of equipment with an impact force of up to 5,000 N. The motor vibrator (1) offers the possibility to obtain impact strength in the range of interest at reduced costs, allowing you to tailor the end product at a good market price. In comparative terms, a 50W electrovibrator has the same large cost as a 7 times higher power vibrator.

[032] The next step was to adjust the damping system based on springs, dampers and transformers, in which the acceleration intensity is adjusted by varying the transformer primary supply current (2) by potentiometric means. Using motors, the frequency of vibration is now determined by the number of motor poles and the intensity of the impact produced is mechanically determined by adjusting the eccentric masses attached to the motovibrator shaft (1).

[033] Once the question of the platform's mechanism of action is addressed, the need for platform automation arises. Because the vibration system is driven by vibration, the platform adjustments must be mechanically performed.

[034] Vibration level intensity adjustment should be "in sudden", measured in accelerations of gravity. However, micro-accelerometers (micro machined ceramic type) may be used, especially for the monitoring of electronic systems subject to mechanical vibration. These are low cost devices with good mechanical resistance. Thus, a stage for acquisition and display (7) of the signals of an accelerometer positioned on the upper vibratory platform (2) was incorporated into the microcontroller. This solution allows the evaluation of the platform operation at intervals as short as desired, including the daily monitoring of intensities.

The constituent parts of the platform can be seen by means of the attached figures, where through figures 1 to 4 and 7, which are without the side covers (10) it is possible to verify the structural form of the device being made of a tubular frame (6) to support the user's hands, the damping system with rubber gloves and / or springs (5), which connects a lower sheet steel base (4) to an upper vibrating platform (2) also in sheet steel; the vibrator (1) properly coupled to the upper platform (2), the positioning of the display (7) on the tubular metal frame (6), the rubber feet (9) located at the corners of the lower base (4).

By figures 5, 6 and 7 it is possible to verify the tubular metal structure (6) properly fixed by the outside of the lower base (4).

[037] In Figure 8 it is possible to verify the patent platform properly closed by the side covers (10) and mounted with a handle (11) to support the user's hands and a rubber mat (12) located on the upper platform surface. (2).

Bibliography 1 -www.asbmr.org 2- Melton LJ. How many women have osteoporosis now? J. Bone Miner Res; 1995 10: 175-77 3- Florindo AA. Habitual physical activity and bone mineral density in elderly men. University of São Paulo. Faculty of Public Health. Department of Epidemiology / Master 2000, pages 96. 4. Ray NF, Chan Jk, Thamer M, Melton LJ. Medical expenditures for the treatment of osteoporotic fractures in the United States in 1995: report from The National Osteoporosis Foundation. J Bone Miner Res 1997; 12 (1): 24-35 5- Komatsu RS, Simões MFJ, Ramos LR, Szejnfeld VL. Incidence of proximal femur fractures in Marilia, Brazil.J.Nutr Health Aging 2004: 8 (5): 362-367. 6- Camargo MBR, Cendoroglo MS, Ramos LR, Latorre MRDO, Saraiva GP, Lage A, Oaks-Neto Araujo LMQ, Vieira JGH, Lazaretti-Castro M. Bone mineral density and osteoporosis among a predominantly Caucasian elderly population of Sao Paulo, Brazil. Osteoporosis Int - accepted for publication (forthcoming). 7- Fukada E, Yasuda I. On the piezoelectric effect of bone. J Physical Society Japan 1957.12: 1158-1162. 8- Rubin C, Turner AS, Muller R, Mittra E, Mcleod K, Lin W, QinYX. Quantity and quality of trabecular bone in the femur are enhanced by a strongly anabolic, noninvasive mechanical intervention. Bone and Miner Res; 2002.17 (2): 349-57. 9- Rubin C, Turner A, Mcleod K, Bain SD et al. Mechanical strain, non-invasively induced in the high-frequency domain, is anabolic to cancellous bone, but not cortical bone. Bone 2002 Mar; 30 (3): 445-52. 10- Flieger, TH, Karachalios L, Khaldi P, Lyritis RG. Mechanical Stimulation in the form of postmenopausal vibration prevents bone loss in ovariectomized rats. Calcif Tissue Int 1998; 63: 510-14. 11- Oxlund BS, Ortoft G, Andreassen TT, Oxlund H. Low-intensity, high-frequency vibration appears to prevent the decrease in strength of the femur and tibia associated with ovariectomy of adult rats. Bone 2003 Jan; 32 (1): 69-77. 12- Rubin C, Xu G, Judex S. The anabolic activity of bone tissue, suppressed by disuse, is normalized by brief exposure to extremely low-magnitude mechanical stimuli. The Faseb Journal 2001; 15: 2225-229. 13- Ward K, Alsop C, Caulton J, Rubin C, Adams J, Mughal Z. Low magnitude mechanical loading is osteogenic in children with disabling conditions. .J Bone Miner Res. 2004 Mar; 19 (3): 360-9. Rubin C.Recker R, Cullen D, Ryaby J, Mccabe J, Mcleodk. Prevention of postmenopausal bone loss by low-magnitude, high-frequency mechanical stimuli: a clinical trial assessing compliance, efficacy, and safety. J Cap Miner Res. 2004 Mar; 19 (3): 343-51. 15- Verschueren SM, Roelants M, Delecluse C, Swinnen S et al. Effect of 6-month whole body vibration training on hip density, muscle strength, and postural control in postmenopausal women: a randomized controlled pilot study. J Cap Miner Res. 2004 Mar; 19 (3): 352-9. 16- Vieira LR, de Souza JL, Zaro MA, Moura AMM et al. Use of thermography as an auxiliary method in the diagnosis of tibial stress syndrome. Rev. Brasil Med Esporte 2003 9: 6.

Claim

Claims (1)

1 - VIBRATORY PLATFORM FOR TREATMENT AND PREVENTION OF OSTEOPOROSIS, characterized by presenting low frequency and low amplitude for the treatment and prevention of osteoporosis working with low intensity (0.6 g), 4 mm displacement and frequency of 60 Hz, comprising a calibrated motor vibrator (1) providing an impact force of up to 5,000 N, which is coupled to a platform (2), which in turn has a suspension system consisting of rubber springs and shock absorbers (5) interconnecting the base ( 4); a structure (6) interconnected on the outside of the base (4), whose structure (6) has a display (7) for user interaction with the equipment.