None.
The present disclosure is generally directed to systems and methods of physical rehabilitation and, more particularly, to staircase gait systems for physical rehabilitation and related methods.
People who suffer from a spinal cord injury, a stroke, or another physical condition can benefit from physical therapy. One type of task a patient may perform during physical therapy is gait training, where the patient practices walking, often with the help of a physical therapist.
The type of therapy a stroke patient receives can have a significant impact on his or her ability to recover. Recent research suggests that simply walking on a flat treadmill can limit the extent of the patient's recovery, and that training with variable challenges, such as requiring the patient to step in multiple directions, over obstacles, or up and down stairs, can help improve recovery.
However, gait training that requires a variety of challenging locomotor tasks can be discouraged in a rehabilitation setting. Post-stroke patients can have many gait impairments, and often cannot climb staircases during therapy out of safety concerns. Some physical therapists physically assist patients up and down staircases during therapy. However, successfully providing this kind of therapy for many patients in a day is strenuous for the therapist and increases the risk of fall and injury.
In an embodiment, a system for physical rehabilitation is provided. The system comprises a plurality of motors configured to be coupled to a ceiling and a plurality of cable portions, wherein each cable portion is connected at a first end to a motor, among the plurality of motors, and connected at a second end to a connector element, wherein the connector element is for attaching to a patient. The system also comprises a controller in operative communication with the plurality of motors to move the connector element in relation to a staircase, wherein the controller is configured to adjust one or both of i) position and ii) speed of the connector element based on tracked kinematics of the patient as the patient moves along the staircase.
In another embodiment, another system for physical rehabilitation is provided. The system comprises a plurality of motors configured to be coupled to a ceiling and a plurality of cable portions, wherein each cable portion is connected at a first end to a motor and connected at a second end to a connector element, the connector element comprising a ball having a plurality of holes through which the cable portions may be threaded to secure the ball thereto. The system also comprises a main controller in operative communication with the plurality of motors to move the connector element so that the connector element moves along with a patient.
Various embodiments are described herein by way of example in conjunction with the following figures.
The track system 100 may be attached to a balcony 302 or other support. A railing 304 may surround the system. A patient 10 may be placed into a harness 12 that is attachable to the track system 100 and the lift system 200. The patient 10 walks beneath track system 100. Upon reaching the end of the track system 100, the patient's harness 12 may be detached from the track system 100 and attached to the lift system 200. The lift system 200 provides support as the patient 10 ascends the stairs 306. The patient may reach the top landing of the stairs 306, turn around, and descend the stairs 306, still with the support of the lift system 200.
The connector element 206 may take many different forms. In one embodiment, shown in
In an embodiment, the lift system 200 may be configured to carry a maximum load of 400 pounds, in order to accommodate heavy patients.
A rehabilitation facility may comprise a plurality of lift systems 200, such that two or more patients may use the system at a time on the same stairs 306.
The connector element 206 may move at a variable speed up to a maximum speed, in response to commands or other signals from the user controller 270. In a preferred embodiment, the maximum speed is two feet per second. The speed of the connector element 206 may be increased or decreased without having to first stop the connector element 206.
The main controller 260 may be programmed with various algorithms to assist in the proper operation of the lift system 200. For example, a tension algorithm may be provided to indicate the load on each cable portion 204a, so that load on each motor 202 is kept within appropriate limits. A load algorithm may calculate the physical load on each motor 202 and transmit that information to the main controller 260. An angle algorithm may be further provided to calculate the three dimensional point of the connector element 206 in relation to each motor 202 and/or motor point 203.
The lift system 200 may employ various modes. For example, the main controller 260 may toggle between a horizontal mode, a vertical mode, or a path mode. In horizontal mode, the lift system 200 operates such that the connector element 206 can be moved to the left, to the right, up the stairs 306 and down the stairs 306. In vertical mode, the lift system 200 operates such that the connector element 206 can move up, away from the stairs 306 or down, towards the stairs 306. In a path mode, the lift system 200 operates such that the connector element 206 can move along a pre-determined path. One or more pre-determined paths may be programmed into the main controller 260. In a path mode, connector element 206 moves along a pre-determined path. In an embodiment, in path mode, the connector element 206 travels around a loop, such as an oval loop. Other paths, such as squares, rectangles, lines, or a combination thereof, may also be programmed into the main controller 260. Various paths may be programmed into the main controller 260, or otherwise may be pre-determined (in other words, the path of the connector element 206 may be determined prior to the patient 10 using the lift system 200). The lift system 200 may also employ a fault mode, where if the main controller 260 indicates a problem or error with the system. Examples of problems or errors include, for instance, if the tension on a cable 204 is too great. In such an instance, the lift system 200 may be configured to stop and/or return to a default position, as appropriate. For example, in fault mode the lift system 200 may lower the patient 10 to the staircase level at the point of stoppage.
The parent controller may calculate the limits of the position and speed of the connector element 206 based on known limits of its position and speed. The main controller 260 may compute control and position algorithms for each motor controller 250, which in turn will cause the motor controller 250 to appropriately control its respective motor 202. This will result in correct positioning of the connector element 206. In an embodiment, the main controller 260 converts the three-dimensional position of the connector element to linear control of length of each cable portion 204a. The main controller 260 can be configured to account for the height of a patient 10.
When used in rehabilitation, such as gait therapy, the lift system 200 can serve many different purposes. In one example, it can be used so that it provides no lift support while the patient is walking. If the patient falls, lift system 200 stops the patient from falling to the floor and suffering a fall injury. The cables 204 and the connector element 206 support the weight of the patient if the patient slips or falls. In another example, the lift system 200 can actually lift the patient off of the staircase. This can be useful, for instance, if the patient walks up a portion of the staircase but is unable to walk safely down the steps to return to the bottom of the stairs.
This application is a continuation of U.S. patent application Ser. No. 16/492,913, filed Sep. 10, 2019, which is a U.S. National Phase of International Patent Application No. PCT/US2018/021963, filed Mar. 12, 2018, which claims priority to U.S. Provisional Patent Application No. 62/470,148, filed Mar. 10, 2017, entitled “Track and Lift Rehabilitation Systems and Related Methods.” The disclosures of each of the above-listed applications are incorporated herein by reference in their entirety.
Number | Date | Country | |
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62470148 | Mar 2017 | US |
Number | Date | Country | |
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Parent | 16492913 | Sep 2019 | US |
Child | 17672213 | US |