Curious about the science behind neuromuscular electrical stimulation (NMES) in rehabilitation? In our latest article, we dive deep into how this established yet evolving technology effectively strengthens skeletal muscles.

From optimal stimulation parameters to clinical applications, discover why the "art" of electrical stimulation goes far beyond simply making muscles contract. Drawing from recent research and clinical evidence, we explore the mechanisms, effectiveness, and practical considerations for healthcare professionals working with neurological injuries and various rehabilitation scenarios.

Whether you're a clinician, researcher, or rehabilitation specialist, this comprehensive review offers valuable insights into maximizing NMES outcomes for patient care.

Recovery and progress often seem daunting, especially when facing significant physical challenges or lifestyle changes. Whether you're an injured patient working through rehabilitation or someone who has fallen out of healthy habits, the gap between where you are and where you want to be can feel overwhelming. This article explores why taking that first small step - no matter how modest it may seem - is the most crucial part of any journey toward recovery or positive change. Drawing from both clinical experience with rehabilitation patients and personal insights about motivation, we'll examine how the compound effect of small, consistent actions can lead to remarkable transformations, even when the path ahead appears insurmountable.

In this article, we step back and consider how brachial plexus injuries are treated and then look at how forms of electrical stimulation might contribute to achieving the best clinical outcome.

Brachial plexus injuries present a complex challenge in medical practice, with the potential to produce significant functional impairment and reduced quality of life. Effective treatment requires a meticulous, multifaceted approach, combining surgical and non-surgical interventions tailored to the patient's specific needs. This article explores current treatment strategies, focusing on the potential role of electrical stimulation as a complementary therapy. By examining its applications and efficacy, we aim to highlight how this innovative technique could enhance recovery and optimise clinical outcomes for individuals affected by these injuries.

The Tek RMD distinguishes itself from other mobility devices through its unique design philosophy, functionality, and target user needs. This doesn't mean that it is the perfect choice for everyone. Individuals with weak or paralysed limbs will ultimately have different physical abilities and functional goals. The Tek RMD allows individuals who are suitable to use it, to stand and move in their environment and to do this in a way that will enable them to do more than if they just were using a standing frame. They can stand for lengthy periods, interact at eye level with others and uniquely engage in their environment. We know that standing is good for health but most candidates for the Tek RMD or standing wheelchair want to do more.

Choosing the right product requires thoughtful consideration. It’s important to assess each option’s physical suitability while carefully evaluating its strengths and weaknesses in relation to the user’s functional goals.

All medical devices have indications and contraindications, and the manufacturer always states these clearly. However, not all electrical stimulation devices on the market are classified as medical devices, so the manufacturer may not clearly describe when they might be unsafe to use.

A very common situation we face when dealing with clients is the presence of metal implants such as joint replacements, fracture fixation plates and spinal instrumentation near where we wish to apply electrodes. The concern has been that the energy generated by electrical stimulation over metal implants would cause local, damaging heating within the tissues. We consider this below.

We must follow the manufacturer's recommendations. However, you might wonder about the real risks. Do the benefits of using electrical stimulation outweigh the risks? This article explores this topic.

Spinal cord injuries have profound and lasting effects, disrupting both physical and neurological functions. Understanding these consequences is vital for patients, healthcare professionals, and researchers working towards improving outcomes for those affected. This brief guide will explore the physical challenges caused by spinal cord injuries, supported by insights from medical experts and research while highlighting potential treatments and solutions.

When the spinal cord is damaged, communication between the brain and body is disrupted. Depending on the severity and location of the injury, this disruption can result in paralysis, loss of sensation, or other debilitating symptoms. By comprehending these impacts, we can better develop treatments, therapies, and assistive technologies that improve quality of life.