What is robotic neurorehabilitation?
Neurorobotics is a multidisciplinary field of the last decade that connects knowledge from the fields of neuroscience, engineering and computer science.
Neurorehabilitation process:
1. Team examination by neurologist and physiatrist
Before receiving the therapy, a history is taken by the neurologist, the medical documentation about the previous treatment is reviewed, and then a neurological examination and an examination by a physiatrist.
2. Neurorehabilitation plan
After determining the degree of motor impairment using a neurological examination and application of neurological scales, an expert team composed of neurologists and physiatrists determines a personal neurorehabilitation plan for each patient.


3. Implementation of neurorehabilitation
Neurorehabilitation is carried out using specialized robotic devices under the supervision of neurologists, physiatrists and professional physiotherapists. In addition to neurorehabilitation, conventional physical therapy is used in combination with individual patients. The therapy is carried out continuously every day, which depends on the degree of damage and neurological deficit. Therapy should be daily with frequent repetitions with regular breaks between exercise and rest. The therapy is very challenging and motivating for the patient, especially the information about the progress that is monitored using the scales on the device. Then a comparison is made of the findings that the patient had before the start of the therapy and two weeks after the therapy, which shows the patient, the doctor and the therapist the progress and effectiveness of the therapy in terms of better movement and better coordination.
4. Results of neurorehabilitation
The achieved results are analyzed using scales, the results of the work and the progress of the rehabilitation process are continuously measured.
What is neuroplasticity?
Neuroplasticity means the ability of the brain to constantly change at the request of the environment and for the rest of life.
The cerebral cortex consists of nerve cells that are very well connected. Movement begins in the brain. Motor neurons in the brain that are responsible for movement and motility send impulses to alpha-moto neurons and the spinal cord which further sends impulses to the muscles. Movement is not just the movement of certain parts of the body from one position to another, but complex motor skills directed towards a specific goal. With the advancement of technology in the field of neurophysiology, it has been concluded that the brain has the property of plasticity. After brain damage, information from the periphery is needed, which will enable normal functional movement through the plasticity of the brain. The basic property of nervous tissue is the ability to adapt to new conditions, which is the basis for learning. Structurally, neuroplasticity consists of numerous axons and dendrites of synapses and neurons. Together, they form a neural network that can be reorganized depending on the stimulus. In other words, neuroplasticity means THERE IS NO IMPOSSIBLE.
The concept of neuroplasticity is relatively new. The thesis that a damaged brain cell cannot recover has been overcome today. Neurons can be regenerated, and the destroyed function of a part of the brain can be taken over by another group of neurons by creating new synapses between them.

Neuroanatomical plasticity represents the creation of new neural pathways and connections in damaged parts of the brain, which is achieved in neurorehabilitation by repeating the movements of damaged limbs using robotics. For example, during a stroke, the motor cortex is damaged, but by repeating the movement, other parts of the cortex are activated that before the stroke had no part in the patient’s movement. During neurorehabilitation using a robot, patients receive a certain task in the form of repeating movements and thus activate other parts of the motor cortex, as well as the creation of new synapses between neurons. The best recovery of function is in the first three months after a stroke.
When is robotic neurorehabilitation applied?
Neurological patients in whom robotic neurorehabilitation is applied:
- stroke
- multiple sclerosis,
- Parkinson’s disease,
- muscular dystrophy,
- amyotrophic lateral sclerosis,
- spinal muscular atrophy,
- primary lateral sclerosis,
- different forms of motor neuron disease,
- different forms of myopathies
- acquired and hereditary neuropathies,
- condition after AIDP (Guillain-Barre syndrome),
- cerebral palsy,
- dementia,
- brachialis plexus lumbosacral plexus injuries,
- spinal cord injuries (paraplegia and paraparesis),
- tumors of the brain and spinal cord in which there is a neurological deficit,
- conditions after meningitis or encephalitis in which there is a neurological deficit.


Robotic neurorehabilitation and Neuromedic
We believe in medical innovation, we work with the most modern technology of the last generation such as “movement sensors, virtual reality games and robotics” and we constantly implement new therapeutic possibilities.
We only use treatments that are based on neuroscientific evidence, clinical research and expert experience.
We measure the progress and success of the treatment, we take care of the patient’s environment, a pleasant environment, a friendly and highly educated team.
Our goal is to provide the full potential of neurorehabilitation and apply therapy to patients with neurological deficits as soon as possible!
New therapeutic procedures with robotic devices, persistent and long-term rehabilitation enable quick recovery after brain damage.
Neurorehabilitation results depend on motivation!
We are very supportive of patients and provide feedback on their progress and create a very fun and enjoyable atmosphere.
Every rehabilitation program is a long journey, but patients must be persistent and use their maximum potential and achieve their goals, much faster if they are motivated.
However, we always put patients’ progress first, even when it is difficult for them and when they lose hope and motivation, we devote ourselves to the utmost to get their focus back on their long-term goal, which is progress!
Individual neurorehabilitation concept for you!
The best results were achieved thanks to a highly educated team, that’s why we exchange experiences every day, hold meetings and follow the latest medical achievements in the field of neurology and neurorehabilitation.
The best team for the best results.