Prosthetics Lower Limb
GeniumGenium/Genium X3 gait training MyModes: Switching
With a Genium or Genium X3 knee joint, you can benefit from the unique option of using five additional settings called MyModes, which supplement the tailored basic settings. MyModes can be used to make the joint’s functions even more individual and adapt them to the very own daily routine.
With a Genium or Genium X3 knee joint, you can benefit from the unique option of using five additional settings called MyModes, which supplement the tailored basic settings. MyModes can be used to make the joint’s functions even more individual and adapt them to the very own daily routine.
Prosthetics Lower Limb
Genium
Genium/Genium X3 gait training MyModes: Switching
With a Genium or Genium X3 knee joint, you can benefit from the unique option of using five additional settings called MyModes, which supplement the tailored basic settings. MyModes can be used to make the joint’s functions even more individual and adapt them to the very own daily routine.
Prosthetics Lower Limb
Prosthetic gait training Walking on level ground (1)
The exercises are suitable for C-Leg 4, Genium, Genium X3 and Kenevo (Mode C). The knee joint bends slightly during initial contact and loading response when observing physiological gait. This movement serves as a shock absorber, relieves the musculoskeletal system and provides safety through a faster foot flat position.
The exercises are suitable for C-Leg 4, Genium, Genium X3 and Kenevo (Mode C). The knee joint bends slightly during initial contact and loading response when observing physiological gait. This movement serves as a shock absorber, relieves the musculoskeletal system and provides safety through a faster foot flat position.
Prosthetics Lower Limb
Prosthetic gait training Walking on level ground (1)
The exercises are suitable for C-Leg 4, Genium, Genium X3 and Kenevo (Mode C). The knee joint bends slightly during initial contact and loading response when observing physiological gait. This movement serves as a shock absorber, relieves the musculoskeletal system and provides safety through a faster foot flat position.
Prosthetics Upper Limb
Myo PlusMyo Plus Pattern Recognition
Myo Plus pattern recognition controls myoelectric hand prostheses with artificial intelligence. The animation explains how the prosthetic control learns from the user due to artificial intelligence. Myo Plus is compatible with the bebionic hand as well as all MyoBock terminal devices including the Greifer. Myo Plus pattern recognition controls terminal devices with artificial intelligence.
The Myo Plus prosthesis control uses up to eight electrodes to measure incoming signals of the forearm. And derive patterns that are characteristic for individual movements. Complex mathematical algorithms transform and amplify these signals and patterns so that a prosthetic hand can translate them into the corresponding movement. The Myo Plus app is the central interface between the user and the control unit.
The spiderplot visualizes the movement patterns in the residual limb and helps users and clinicians to identify movement patterns. Myo Plus supports especially a smooth and intuitive prosthesis control: direct transitions, precise control and more grip options. Myo Plus offers an extended use of the hand prosthesis and gives users the opportunity to unlock their individual potential. Myo Plus prosthetic control is compatible with all MyoBock terminal devices and the Greifer. Myo Plus – The new standard of care by artifical intelligence.
Myo Plus pattern recognition controls myoelectric hand prostheses with artificial intelligence. The animation explains how the prosthetic control learns from the user due to artificial intelligence. Myo Plus is compatible with the bebionic hand as well as all MyoBock terminal devices including the Greifer. Myo Plus pattern recognition controls terminal devices with artificial intelligence.
The Myo Plus prosthesis control uses up to eight electrodes to measure incoming signals of the forearm. And derive patterns that are characteristic for individual movements. Complex mathematical algorithms transform and amplify these signals and patterns so that a prosthetic hand can translate them into the corresponding movement. The Myo Plus app is the central interface between the user and the control unit.
The spiderplot visualizes the movement patterns in the residual limb and helps users and clinicians to identify movement patterns. Myo Plus supports especially a smooth and intuitive prosthesis control: direct transitions, precise control and more grip options. Myo Plus offers an extended use of the hand prosthesis and gives users the opportunity to unlock their individual potential. Myo Plus prosthetic control is compatible with all MyoBock terminal devices and the Greifer. Myo Plus – The new standard of care by artifical intelligence.
Prosthetics Upper Limb
Myo Plus
Myo Plus Pattern Recognition
Myo Plus pattern recognition controls myoelectric hand prostheses with artificial intelligence. The animation explains how the prosthetic control learns from the user due to artificial intelligence. Myo Plus is compatible with the bebionic hand as well as all MyoBock terminal devices including the Greifer. Myo Plus pattern recognition controls terminal devices with artificial intelligence.
The Myo Plus prosthesis control uses up to eight electrodes to measure incoming signals of the forearm. And derive patterns that are characteristic for individual movements. Complex mathematical algorithms transform and amplify these signals and patterns so that a prosthetic hand can translate them into the corresponding movement. The Myo Plus app is the central interface between the user and the control unit.
The spiderplot visualizes the movement patterns in the residual limb and helps users and clinicians to identify movement patterns. Myo Plus supports especially a smooth and intuitive prosthesis control: direct transitions, precise control and more grip options. Myo Plus offers an extended use of the hand prosthesis and gives users the opportunity to unlock their individual potential. Myo Plus prosthetic control is compatible with all MyoBock terminal devices and the Greifer. Myo Plus – The new standard of care by artifical intelligence.
Prosthetics Lower Limb
Prosthetic gait training Intuitive stance function
See how to activate and deactivate the intuitive stance function. There are different possibilities to start walking out of the stance function. The exercises are suitable for C-Leg 4, Genium, Genium X3 and Kenevo (Mode C).
See how to activate and deactivate the intuitive stance function. There are different possibilities to start walking out of the stance function. The exercises are suitable for C-Leg 4, Genium, Genium X3 and Kenevo (Mode C).
Prosthetics Lower Limb
Prosthetic gait training Intuitive stance function
See how to activate and deactivate the intuitive stance function. There are different possibilities to start walking out of the stance function. The exercises are suitable for C-Leg 4, Genium, Genium X3 and Kenevo (Mode C).
Prosthetics Upper Limb
MyoBockMyoBock - Evaluation of the myosignals tutorial
As part of a myoelectric, prosthetic fitting of the hand or arm the evaluation of the myosignals must be completed prior to definitive prosthesis manufacture and fitting. Preliminary evaluation will help determine the ideal electrode position and gain, as well as the most appropriate switching mode. A careful, accurate evaluation of the myo-signal and the corresponding adjustment is essential. This will affect the definitive fitting and final result. Once both myosignals have been evaluated, and the switching method is defined, check and train the settings with the myosimulation in PAULA software. This ensures that the user can control the prosthesis independently and reliably in everyday life with the selected adjustments.
By completing the evaluation you have laid the foundations for successful prosthesis fitting and use.
Myoelectric is the technical term for the electrical voltage generated in muscle cells in the microvolt range, which can be measured on the skin surface and used via electrodes to control prostheses. Myoelectric prostheses are powered by a battery and set in motion by the contraction of a muscle.
As part of a myoelectric, prosthetic fitting of the hand or arm the evaluation of the myosignals must be completed prior to definitive prosthesis manufacture and fitting. Preliminary evaluation will help determine the ideal electrode position and gain, as well as the most appropriate switching mode. A careful, accurate evaluation of the myo-signal and the corresponding adjustment is essential. This will affect the definitive fitting and final result. Once both myosignals have been evaluated, and the switching method is defined, check and train the settings with the myosimulation in PAULA software. This ensures that the user can control the prosthesis independently and reliably in everyday life with the selected adjustments.
By completing the evaluation you have laid the foundations for successful prosthesis fitting and use.
Myoelectric is the technical term for the electrical voltage generated in muscle cells in the microvolt range, which can be measured on the skin surface and used via electrodes to control prostheses. Myoelectric prostheses are powered by a battery and set in motion by the contraction of a muscle.
Prosthetics Upper Limb
MyoBock
MyoBock - Evaluation of the myosignals tutorial
As part of a myoelectric, prosthetic fitting of the hand or arm the evaluation of the myosignals must be completed prior to definitive prosthesis manufacture and fitting. Preliminary evaluation will help determine the ideal electrode position and gain, as well as the most appropriate switching mode. A careful, accurate evaluation of the myo-signal and the corresponding adjustment is essential. This will affect the definitive fitting and final result. Once both myosignals have been evaluated, and the switching method is defined, check and train the settings with the myosimulation in PAULA software. This ensures that the user can control the prosthesis independently and reliably in everyday life with the selected adjustments.
By completing the evaluation you have laid the foundations for successful prosthesis fitting and use.
Myoelectric is the technical term for the electrical voltage generated in muscle cells in the microvolt range, which can be measured on the skin surface and used via electrodes to control prostheses. Myoelectric prostheses are powered by a battery and set in motion by the contraction of a muscle.
Prosthetics Lower Limb
GeniumGenium/Genium X3 gait training Stairs & obstacle function: Basic exercises
The stairs and obstacle function of Genium and Genium X3 allows users to step over small obstacles and to climb stairs step over step. A certain movement pattern is necessary to trigger the function, which can be trained with fundamental and trust building exercises.
The stairs and obstacle function of Genium and Genium X3 allows users to step over small obstacles and to climb stairs step over step. A certain movement pattern is necessary to trigger the function, which can be trained with fundamental and trust building exercises.
Prosthetics Lower Limb
Genium
Genium/Genium X3 gait training Stairs & obstacle function: Basic exercises
The stairs and obstacle function of Genium and Genium X3 allows users to step over small obstacles and to climb stairs step over step. A certain movement pattern is necessary to trigger the function, which can be trained with fundamental and trust building exercises.
Prosthetics Lower Limb
Prosthetic gait training Walking downstairs (1)
Gerhard learns the basics for walking downstairs. The exercises are suitable for C-Leg 4, Genium, Genium X3 and Kenevo (Mode C).
Gerhard learns the basics for walking downstairs. The exercises are suitable for C-Leg 4, Genium, Genium X3 and Kenevo (Mode C).
Prosthetics Lower Limb
Prosthetic gait training Walking downstairs (1)
Gerhard learns the basics for walking downstairs. The exercises are suitable for C-Leg 4, Genium, Genium X3 and Kenevo (Mode C).
Prosthetics Lower Limb
Prosthetic gait training Stability before mobility
Franziska and Gerhard show simple exercises for weight transfer and for improving stability. The exercises are suitable for C-Leg 4, Genium, Genium X3 and Kenevo (Mode C).
Franziska and Gerhard show simple exercises for weight transfer and for improving stability. The exercises are suitable for C-Leg 4, Genium, Genium X3 and Kenevo (Mode C).
Prosthetics Lower Limb
Prosthetic gait training Stability before mobility
Franziska and Gerhard show simple exercises for weight transfer and for improving stability. The exercises are suitable for C-Leg 4, Genium, Genium X3 and Kenevo (Mode C).
Prosthetics Lower Limb
Prosthetic gait training Sitting down & standing up
During activities of daily living like sitting down, the hydraulic resistance against knee flexion of C-Leg 4, Genium, Genium X3 and Kenevo (Mode C) makes consistent loading of both legs possible.
During activities of daily living like sitting down, the hydraulic resistance against knee flexion of C-Leg 4, Genium, Genium X3 and Kenevo (Mode C) makes consistent loading of both legs possible.
Prosthetics Lower Limb
Prosthetic gait training Sitting down & standing up
During activities of daily living like sitting down, the hydraulic resistance against knee flexion of C-Leg 4, Genium, Genium X3 and Kenevo (Mode C) makes consistent loading of both legs possible.
Prosthetics Lower Limb
Prosthetic gait training Walking downstairs (2)
Gerhard learns the step over step pattern for walking downstairs. To see how the setting of the stance flexion resistance influences walking downstairs it will be changed in small intervals by the OT. The exercises are suitable for C-Leg 4, Genium, Genium X3 and Kenevo (Mode C).
Gerhard learns the step over step pattern for walking downstairs. To see how the setting of the stance flexion resistance influences walking downstairs it will be changed in small intervals by the OT. The exercises are suitable for C-Leg 4, Genium, Genium X3 and Kenevo (Mode C).
Prosthetics Lower Limb
Prosthetic gait training Walking downstairs (2)
Gerhard learns the step over step pattern for walking downstairs. To see how the setting of the stance flexion resistance influences walking downstairs it will be changed in small intervals by the OT. The exercises are suitable for C-Leg 4, Genium, Genium X3 and Kenevo (Mode C).
Prosthetics Lower Limb
Prosthetic gait training Walking on level ground (2)
The following exercises as walking with small steps and changing the walking speed are intended to refine the walking technique with C-Leg 4, Genium, Genium X3 and Kenevo (Mode C). Spontaneous adjustment of cadence and walking speed is essential for day to day security.
The following exercises as walking with small steps and changing the walking speed are intended to refine the walking technique with C-Leg 4, Genium, Genium X3 and Kenevo (Mode C). Spontaneous adjustment of cadence and walking speed is essential for day to day security.
Prosthetics Lower Limb
Prosthetic gait training Walking on level ground (2)
The following exercises as walking with small steps and changing the walking speed are intended to refine the walking technique with C-Leg 4, Genium, Genium X3 and Kenevo (Mode C). Spontaneous adjustment of cadence and walking speed is essential for day to day security.
Prosthetics Upper Limb
Myo PlusMyo Plus - Die neue Generation der Prothesensteuerung
Die Animation zeigt die Funktionsweise der Myo Plus Mustererkennung, der lernenden Handprothesensteuerung von Ottobock. Die völlig neu entwickelte Steuerungseinheit erkennt die gedanklichen Befehle des Anwenders und übersetzt sie in Prothesenbewegungen.
Die Muskeln im Unterarm werden aktiviert sobald ein Mensch eine bestimmte Handbewegung ausüben möchte. Das Gehirn sendet entsprechende Signale an die Unterarmmuskulatur und aktiviert die vorhandenen Muskeln im Stumpf. Auch bei einer angeborenen Fehlbildung des Arms oder nach einer Amputation sind diese Muskeln meist noch vorhanden. Ebenso bleibt die gedankliche Vorstellung der Hand im Gehirn meist angelegt. Betroffene können sich weiterhin gedanklich vorstellen, ihre Hand zu schließen oder nach außen zu drehen. Dabei wird die verbliebene Muskulatur im Stumpf aktiviert. Es fehlt jedoch das entsprechende Organ um die Handbewegung auszuführen.
Bestimmte Muskelaktivitäten, die zu eindeutigen Handbewegungen führen, nennt man Bewegungsmuster. Diese sind bei jedem Menschen individuell. Mit Hilfe von Elektroden misst die Myo Plus Prothesensteuerung die eingehenden Signale an der Oberfläche des Unterarms und leitet daraus Muster ab, die charakteristisch für einzelne Bewegungen sind. Dabei lernt die Steuerung vom Anwender. Mit Hilfe der eigens entwickelten Myo Plus App kann jedem gelernten Muster ein bestimmter Prothesenhandgriff zugeordnet werden.
Die Animation zeigt die Funktionsweise der Myo Plus Mustererkennung, der lernenden Handprothesensteuerung von Ottobock. Die völlig neu entwickelte Steuerungseinheit erkennt die gedanklichen Befehle des Anwenders und übersetzt sie in Prothesenbewegungen.
Die Muskeln im Unterarm werden aktiviert sobald ein Mensch eine bestimmte Handbewegung ausüben möchte. Das Gehirn sendet entsprechende Signale an die Unterarmmuskulatur und aktiviert die vorhandenen Muskeln im Stumpf. Auch bei einer angeborenen Fehlbildung des Arms oder nach einer Amputation sind diese Muskeln meist noch vorhanden. Ebenso bleibt die gedankliche Vorstellung der Hand im Gehirn meist angelegt. Betroffene können sich weiterhin gedanklich vorstellen, ihre Hand zu schließen oder nach außen zu drehen. Dabei wird die verbliebene Muskulatur im Stumpf aktiviert. Es fehlt jedoch das entsprechende Organ um die Handbewegung auszuführen.
Bestimmte Muskelaktivitäten, die zu eindeutigen Handbewegungen führen, nennt man Bewegungsmuster. Diese sind bei jedem Menschen individuell. Mit Hilfe von Elektroden misst die Myo Plus Prothesensteuerung die eingehenden Signale an der Oberfläche des Unterarms und leitet daraus Muster ab, die charakteristisch für einzelne Bewegungen sind. Dabei lernt die Steuerung vom Anwender. Mit Hilfe der eigens entwickelten Myo Plus App kann jedem gelernten Muster ein bestimmter Prothesenhandgriff zugeordnet werden.
Prosthetics Upper Limb
Myo Plus
Myo Plus - Die neue Generation der Prothesensteuerung
Die Animation zeigt die Funktionsweise der Myo Plus Mustererkennung, der lernenden Handprothesensteuerung von Ottobock. Die völlig neu entwickelte Steuerungseinheit erkennt die gedanklichen Befehle des Anwenders und übersetzt sie in Prothesenbewegungen.
Die Muskeln im Unterarm werden aktiviert sobald ein Mensch eine bestimmte Handbewegung ausüben möchte. Das Gehirn sendet entsprechende Signale an die Unterarmmuskulatur und aktiviert die vorhandenen Muskeln im Stumpf. Auch bei einer angeborenen Fehlbildung des Arms oder nach einer Amputation sind diese Muskeln meist noch vorhanden. Ebenso bleibt die gedankliche Vorstellung der Hand im Gehirn meist angelegt. Betroffene können sich weiterhin gedanklich vorstellen, ihre Hand zu schließen oder nach außen zu drehen. Dabei wird die verbliebene Muskulatur im Stumpf aktiviert. Es fehlt jedoch das entsprechende Organ um die Handbewegung auszuführen.
Bestimmte Muskelaktivitäten, die zu eindeutigen Handbewegungen führen, nennt man Bewegungsmuster. Diese sind bei jedem Menschen individuell. Mit Hilfe von Elektroden misst die Myo Plus Prothesensteuerung die eingehenden Signale an der Oberfläche des Unterarms und leitet daraus Muster ab, die charakteristisch für einzelne Bewegungen sind. Dabei lernt die Steuerung vom Anwender. Mit Hilfe der eigens entwickelten Myo Plus App kann jedem gelernten Muster ein bestimmter Prothesenhandgriff zugeordnet werden.
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