The Graston Technique is a form of soft tissue mobilization that is used to treat musculoskeletal conditions and injuries. It involves the use of specially designed stainless steel instruments to detect and treat areas of scar tissue or adhesions in the muscles, tendons, and ligaments. The instruments are used to apply controlled pressure and friction to the affected area, which helps to break up scar tissue and promote healing. This technique is based on the principles of manual therapy and is often used in conjunction with other treatment modalities such as stretching and strengthening exercises.
There are several benefits of using the Graston Technique for soft tissue mobilization. Firstly, it can help to reduce pain and inflammation in the affected area. By breaking up scar tissue and adhesions, the technique can improve blood flow and promote the healing process. Secondly, it can improve range of motion and flexibility. By releasing tight muscles and restoring normal tissue mobility, the technique can help to restore normal movement patterns. Lastly, it can enhance athletic performance. By addressing soft tissue restrictions and imbalances, the technique can help athletes improve their overall performance and prevent future injuries.
In this episode, Erson is joined by Dr. Hannah Cox who recently attended one of his live TMJ Seminars. Upon leaving, she felt prepared to take on the TMJ world! Until that is two days later, she had a patient with high fear avoidance and complaints of open lock TMJ, headaches and neck issues. Luckily, Erson was able to instill her confidence over an online mentoring session and all worked out great over 3 sessions only! Untold Physio Stories is sponsored byHelix Pain Creams - I use Helix Creams in my practice and patients love them! Perfect in combination with joint mobs, IASTM and soft tissue work. Get your sample and start an additional revenue stream for your practice. Click here to get started. https://modmt.com/helixCheck out EDGE Mobility System's Best Sellers - Something for every PT, OT, DC, MT, ATC or Fitness Minded Individual https://edgemobilitysystem.comCurv Health - Start your own Virtual Clinic Side Hustle for FREE! Create your profile in 3 minutes, set your rates, and Curv will handle the rest! From scheduling to payments, messaging, charting, and a full exercise library that allow for patient/clinician tracking, it's never been easier! Click to join Dr. E's new Virtual Clinic Collective to help promote best online practices. Keeping it Eclectic... This article was originally posted on Modern Manual Therapy Blog
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Posted by on 2023-05-08
Erson follows up with the difficult lumbar lateral shift patient from this episode a few weeks back. As in the past, he's doing much better and this time Erson takes care not to flare him up! Interestingly enough using the Activforce 2 handheld dynamometer reveals some significant hip and trunk rotation strength percentage differences that could be key to better prevention. Untold Physio Stories is sponsored byHelix Pain Creams - I use Helix Creams in my practice and patients love them! Perfect in combination with joint mobs, IASTM and soft tissue work. Get your sample and start an additional revenue stream for your practice. Click here to get started.Check out EDGE Mobility System's Best Sellers - Something for every PT, OT, DC, MT, ATC or Fitness Minded IndividualCurv Health - Start your own Virtual Clinic Side Hustle for FREE! Create your profile in 3 minutes, set your rates, and Curv will handle the rest! From scheduling to payments, messaging, charting, and a full exercise library that allow for patient/clinician tracking, it's never been easier! Click to join Dr. E's new Virtual Clinic Collective to help promote best online practicesKeeping it Eclectic... This article was originally posted on Modern Manual Therapy Blog
Posted by on 2023-05-04
Introduction SummaryLow back pain (LBP) is a prevalent and costly health problem that affects a significant portion of the global population. Pain developers (PDs) are individuals who are considered a pre-clinical LBP population at risk of developing clinical LBP, which can exact great social and economic costs. Prolonged standing has been identified as a risk factor for LBP, and it is necessary to investigate the risk factors of standing-induced LBP in PDs comprehensively. By identifying these risk factors, appropriate preventive measures can be planned, which may reduce the incidence of standing-induced LBP and its associated costs.This study1 used a systematic review and meta-analysis approach to investigate the distinctive characteristics and risk factors of standing-induced LBP in PDs. The study aimed to identify statistically significant differences between PDs and non-pain developers (NPDs) in demographics, biomechanical, and psychological outcomes and to determine the pooled effect sizes of these differences. The study’s findings have important implications for preventing and managing standing-induced LBP in PDs and for future research investigating the association of these distinctive characteristics to standing-induced LBP and interventions that may modify them.Characteristics of Pain Developers and Non-Pain DevelopersThe systematic review and meta-analysis identified 52 papers and theses involving 1070 participants (528 PDs and 542 NPDs) that were eligible for inclusion. The studies used a prolonged standing duration greater than 42 minutes to classify adult PDs and NPDs without a history of LBP.Significant differences were found between PDs and NPDs in terms of movement patterns, muscular, postural, psychological, structural, and anthropometric variables. PDs exhibited altered motor control in the anterior hip abduction (AHAbd) test and displayed higher lumbar lordosis in individuals over 25 years old. These factors were found to have a statistically significant association with standing-induced LBP.Muscular differences were also identified between PDs and NPDs. PDs had a higher level of co-activation between gluteus medius and the erector spinae muscles, which can lead to increased lumbar loading and potentially contribute to the development of LBP.In terms of postural characteristics, PDs had less trunk control and increased trunk sway during standing compared to NPDs, which may suggest a lack of postural stability.Psychological characteristics were also found to differ between PDs and NPDs. PDs had higher levels of pain catastrophizing, which is the tendency to magnify the threat value of pain and to feel helpless in the face of it, and is associated with increased pain intensity and disability.Finally, anthropometric and structural differences were found between PDs and NPDs. PDs tended to have higher body mass index (BMI) and shorter stature compared to NPDs, which may result in altered spinal loading during standing.These findings suggest that PDs have distinct biomechanical and psychological characteristics that may predispose them to standing-induced LBP. Altered motor control displayed in AHAbd test and higher lumbar lordosis in individuals over 25 years seem to be probable risk factors for standing-induced LBP. The study’s findings have important implications for preventing and managing standing-induced LBP in PDs and for future research investigating the association of these distinctive characteristics to standing-induced LBP and interventions that may modify them.Risk Factors for Standing-Induced Low Back PainThe systematic review and meta-analysis identified several factors that were found to have a statistically significant association with standing-induced LBP:Lumbar fidgets – Participants with PDs displayed more lumbar fidgets, defined as small voluntary or involuntary movements of the lumbar spine, which are indicative of discomfort or pain. This factor was found to have a significant negative effect size (Hedge’s g − 0.72).Lumbar lordosis in participants over 25 years – Participants with PDs had higher lumbar lordosis, defined as the natural curvature of the lumbar spine, in individuals over 25 years old. This factor was found to have a significant positive effect size (Hedge’s g 2.75).AHAbd test – Participants with PDs displayed altered motor control in the AHAbd test, which measures the ability to control the hip and pelvis while lifting one leg. This factor was found to have a significant positive effect size (WMD 0.7).Gluteus medius co-activation – Participants with PDs had higher levels of co-activation between the gluteus medius and erector spinae muscles. This factor was found to have a significant positive effect size (Hedge’s g 4.24).Pain catastrophizing – Participants with PDs had higher levels of pain catastrophizing, which is associated with increased pain intensity and disability. This factor was found to have a significant positive effect size (WMD 2.85).These risk factors suggest that altered motor control, higher lumbar lordosis, increased gluteus medius co-activation, and pain catastrophizing may predispose individuals to standing-induced LBP. The findings may help identify individuals at risk of developing standing-induced LBP and plan appropriate preventive measures.Future research should investigate the association of the reported distinctive characteristics to standing-induced LBP and whether they are manipulable through various interventions. Such interventions may include physical therapy, posture correction, and mindfulness-based stress reduction, among others. Identifying modifiable risk factors may lead to the development of effective interventions for preventing and managing standing-induced LBP in individuals with pre-clinical LBP.Implications for Future ResearchThe systematic review and meta-analysis identified several distinct characteristics and risk factors for standing-induced LBP in PDs compared to NPDs. However, the study authors note that the identified risk factors do not necessarily prove causality or provide a complete understanding of the mechanisms underlying standing-induced LBP. As such, future research should investigate these factors in greater detail, and identify modifiable risk factors that can be targeted for preventive interventions.The study authors recommend that future research should investigate the following areas:Association with standing-induced LBP – Further research should investigate the association of the identified distinctive characteristics and risk factors to standing-induced LBP. Studies should investigate whether these factors are predictive of standing-induced LBP and whether they are specific to standing-induced LBP or generalizable to other types of LBP.Mechanisms underlying standing-induced LBP – Future research should also investigate the underlying mechanisms of standing-induced LBP, such as the interplay between motor control, muscle activation, and posture. Understanding the mechanisms underlying standing-induced LBP can help identify modifiable risk factors and develop effective interventions.Intervention strategies – Future research should investigate the efficacy of various interventions for preventing and managing standing-induced LBP in individuals with pre-clinical LBP. Such interventions may include physical therapy, posture correction, mindfulness-based stress reduction, and other strategies aimed at reducing risk factors identified in this study.Generalizability of findings – Finally, future research should investigate the generalizability of the study findings to other populations, such as individuals with clinical LBP or those with different occupational or lifestyle factors. This will help to determine the applicability of the findings to a broader population and inform the development of preventive measures for standing-induced LBP.ConclusionIn summary, this systematic review and meta-analysis found that pain developers (PDs) – individuals with a history of low back pain (LBP) – have distinct characteristics compared to non-pain developers (NPDs) when exposed to prolonged standing. These characteristics include altered movement patterns, muscular, postural, psychological, structural, and anthropometric variables. The study also identified several risk factors associated with standing-induced LBP, including lumbar fidgets, higher lumbar lordosis in participants over 25 years, AHAbd test, GMed co-activation, and higher scores on the Pain Catastrophizing Scale.These findings have important implications for preventing and managing standing-induced LBP, particularly in individuals with a history of LBP. The study suggests that altered motor control displayed in the AHAbd test and higher lumbar lordosis in individuals over 25 years old are probable risk factors for standing-induced LBP. Therefore, future interventions may focus on improving motor control and reducing excessive lumbar lordosis. Additionally, the study highlights the importance of addressing psychological factors, such as pain catastrophizing, as a potential risk factor for standing-induced LBP.Overall, the study emphasizes the need for a comprehensive approach to preventing and managing standing-induced LBP, including a focus on biomechanical, psychological, and other factors. Future research should investigate the association of these distinctive characteristics to standing-induced LBP and whether they are manipulable through various interventions. By identifying and addressing these risk factors, it may be possible to reduce the prevalence of LBP and improve the quality of life for individuals with a history of LBP.This study emphasizes the importance of developing appropriate preventive measures for standing-induced low back pain (LBP) in pain developers (PDs). PDs are individuals with a history of LBP and are considered a pre-clinical population at risk of developing clinical LBP, which can lead to significant social and economic costs. The study found that PDs have distinct characteristics compared to non-pain developers (NPDs) when exposed to prolonged standing, which suggests that targeted interventions may be necessary to prevent standing-induced LBP in this population.The development of appropriate preventive measures requires a thorough understanding of the risk factors associated with standing-induced LBP in PDs. This study identified several risk factors, including lumbar fidgets, higher lumbar lordosis in participants over 25 years, AHAbd test, GMed co-activation, and higher scores on the Pain Catastrophizing Scale. These risk factors suggest that interventions targeting motor control, lumbar lordosis, and psychological factors may be effective in preventing standing-induced LBP in PDs.In addition to identifying risk factors, the study highlights the importance of comprehensive interventions that address biomechanical, psychological, and other factors associated with standing-induced LBP. These interventions may include postural education, physical therapy, and cognitive-behavioural therapy. By addressing these factors, it may be possible to reduce the prevalence of LBP and improve the quality of life for individuals with a history of LBP.Overall, the study underscores the importance of developing appropriate preventive measures for standing-induced LBP in PDs. Identifying risk factors and developing targeted interventions may help reduce the burden of LBP in this population and improve their overall health and well-being.Dynamic Disc DesignsDynamic Disc Designs offers dynamic anatomical models that musculoskeletal healthcare workers (chiropractors, medical doctors, physiotherapists, osteopaths) can use to help explain how the spine is impacted when one stands, for example. The models are designed to simulate the spinal movement dynamically, allowing various spinal specialists to better illustrate to patients the impact that standing can have on the spine.Using the dynamic disc model, a healthcare worker can demonstrate how the intervertebral discs are compressed when standing due to the force of gravity on the spine. They can show how the discs lose water content and height throughout the day, resulting in reduced shock absorption and increased pressure on the spinal nerves. This can lead to various symptoms, including low back pain, stiffness, and numbness or tingling in the legs. In this particular research highlighted in this post, a practitioner can explain dynamically what excessive lordosis means and how the facets are approximated in this case. Explore.Want to learn in person? Attend a #manualtherapyparty! Check out our course calendar below!Learn more online - new online discussion group included!Want an approach that enhances your existing evaluation and treatment? No commercial model gives you THE answer. You need an approach that blends the modern with the old school. NEW - Online Discussion GroupLive caseswebinarslectureLive Q&Aover 600 videos - hundreds of techniques and more! Check out MMT InsidersKeeping it Eclectic... This article was originally posted on Modern Manual Therapy Blog
![[RESEARCH REVIEW] The High Cost of Standing: Uncovering Risk Factors for Low Back Pain](https://blogger.googleusercontent.com/img/b/R29vZ2xl/AVvXsEgXTsCQGpK-PEaVaLh2d-4MDJt3iZYFUMfzgmUKypDoGEjgXskP71pa-s8bMk_XOK-iWRrL8pLt-vIE6tD_i8NbsgluTbBpfCrbP80CWO3oFOoSZauwQ7U375LUV9hsBh7bwaSz6BJiYSFJfEniuRnDbSGa6swxPr0DzfpYmpWkljZ5TeS2P6031Ioh/s16000/Low%20back%20pain.png)
Posted by on 2023-04-27
While the Graston Technique is generally considered safe, there are some potential side effects and risks associated with its use. Some individuals may experience temporary bruising, soreness, or redness in the treated area. These side effects are typically mild and resolve on their own within a few days. In rare cases, more serious complications such as infection or nerve damage may occur. It is important to consult with a qualified healthcare professional who is trained in the Graston Technique to minimize the risk of complications and ensure safe and effective treatment.
The duration of a typical Graston Technique session can vary depending on the specific needs of the individual and the area being treated. However, a session typically lasts between 15 to 30 minutes. During this time, the therapist will use the instruments to assess and treat the affected area, applying controlled pressure and friction to break up scar tissue and adhesions. The therapist may also incorporate other treatment modalities such as stretching or strengthening exercises to enhance the effectiveness of the technique.
Yes, the Graston Technique can be used to treat specific conditions or injuries. It is commonly used to treat conditions such as plantar fasciitis, tennis elbow, Achilles tendonitis, and rotator cuff injuries. The technique can also be effective in treating muscle strains, ligament sprains, and post-surgical scar tissue. It is important to consult with a qualified healthcare professional who is trained in the Graston Technique to determine if it is appropriate for your specific condition or injury.
While the Graston Technique is generally safe and well-tolerated, there are some contraindications to its use. Individuals with open wounds, infections, or acute inflammation in the area being treated should not undergo the technique until the condition has resolved. Additionally, individuals with certain medical conditions such as blood clotting disorders or cancer should consult with their healthcare provider before undergoing the technique. It is important to discuss any medical conditions or concerns with a qualified healthcare professional before starting treatment.
There are several alternative treatments or therapies that are similar to the Graston Technique. One such alternative is instrument-assisted soft tissue mobilization (IASTM), which uses similar stainless steel instruments to detect and treat soft tissue restrictions. Another alternative is manual therapy, which involves hands-on techniques such as massage or joint mobilization to address soft tissue restrictions and improve mobility. Additionally, other forms of soft tissue mobilization such as myofascial release or active release technique may be used to treat similar conditions or injuries. It is important to consult with a qualified healthcare professional to determine the most appropriate treatment option for your specific needs.
Cupping therapy has been found to have a positive impact on local blood circulation and tissue oxygenation. The application of cups to the skin creates a vacuum, which helps to increase blood flow to the area. This increased blood flow brings more oxygen and nutrients to the tissues, promoting their overall health and function. Additionally, cupping therapy has been shown to stimulate the release of nitric oxide, a molecule that helps to dilate blood vessels and improve blood circulation. This enhanced circulation not only improves tissue oxygenation but also aids in the removal of waste products and toxins from the area. Overall, cupping therapy can be an effective modality for improving local blood circulation and tissue oxygenation, leading to enhanced healing and recovery.
The Alexander Technique is a method that aims to improve posture and movement patterns by addressing the underlying habits and tensions that contribute to poor alignment and inefficient movement. Through a process of self-awareness and conscious control, individuals learn to release unnecessary muscular tension and re-educate their bodies to move with greater ease and efficiency. By focusing on the relationship between the head, neck, and spine, the Alexander Technique helps individuals develop a more balanced and aligned posture, allowing for improved movement patterns and overall body coordination. This technique emphasizes the use of the body as a whole, rather than isolated parts, and encourages individuals to move with a sense of lightness and freedom. By retraining the body and mind to work together in a more integrated manner, the Alexander Technique can lead to long-term improvements in posture and movement patterns.
When implementing workplace ergonomics to prevent musculoskeletal disorders, there are several considerations that need to be taken into account. Firstly, it is important to assess the physical demands of the job and identify any potential risk factors that may contribute to the development of musculoskeletal disorders. This includes evaluating the tasks performed, the equipment used, and the work environment. Secondly, employers should provide training and education to employees on proper body mechanics and ergonomics principles. This can help employees understand how to maintain proper posture, use equipment correctly, and avoid repetitive or awkward movements that can lead to strain or injury. Additionally, employers should consider providing adjustable workstations and equipment that can be customized to fit each individual's needs. This may include adjustable chairs, desks, and computer monitors. Regular breaks and opportunities for stretching and movement should also be encouraged to prevent prolonged periods of static posture. Lastly, employers should establish a culture of safety and encourage open communication between employees and management regarding any discomfort or pain experienced. By addressing these considerations, employers can effectively implement workplace ergonomics and reduce the risk of musculoskeletal disorders among their workforce.
There is a growing body of evidence supporting the use of dry needling for myofascial pain syndrome. Numerous studies have shown that dry needling can effectively reduce pain and improve function in individuals with this condition. For example, a systematic review and meta-analysis conducted by Smith et al. (2018) found that dry needling was associated with significant improvements in pain intensity, pressure pain threshold, and range of motion in patients with myofascial pain syndrome. Another study by Dommerholt et al. (2016) demonstrated that dry needling resulted in a significant reduction in pain and disability in individuals with myofascial trigger points. Furthermore, a randomized controlled trial by Kietrys et al. (2013) showed that dry needling combined with physical therapy was more effective than physical therapy alone in reducing pain and improving function in patients with myofascial pain syndrome. Overall, these studies provide strong evidence for the efficacy of dry needling as a treatment option for myofascial pain syndrome.
Virtual reality rehabilitation has shown promising results in improving balance and gait in individuals with peripheral neuropathy. By utilizing immersive virtual environments, individuals with peripheral neuropathy can engage in various balance and gait training exercises that specifically target their condition. These exercises can include activities such as walking on uneven surfaces, navigating obstacles, and performing dynamic balance tasks. The virtual reality technology provides real-time feedback and allows for personalized adjustments to be made based on the individual's progress. Additionally, virtual reality rehabilitation can also incorporate gamification elements, which can enhance motivation and adherence to the rehabilitation program. Overall, virtual reality rehabilitation has the potential to significantly improve balance and gait in individuals with peripheral neuropathy, leading to improved functional outcomes and quality of life.
Older adults who are at risk of falls can benefit from a variety of effective balance exercises. One such exercise is the single-leg stance, where the individual stands on one leg while maintaining their balance for a certain period of time. This exercise helps improve stability and proprioception. Another effective exercise is the heel-to-toe walk, also known as the tandem walk, which involves walking in a straight line with the heel of one foot touching the toes of the other foot. This exercise challenges balance and coordination. Additionally, the sit-to-stand exercise, where the individual repeatedly stands up from a seated position, helps improve leg strength and balance. Other beneficial exercises include the standing leg lift, side leg lift, and the backward leg lift, all of which target specific muscle groups and improve overall balance. It is important for older adults to consult with a healthcare professional or a qualified exercise specialist to determine the most appropriate balance exercises for their specific needs and abilities.
Anterior cruciate ligament (ACL) injuries are often caused by a combination of biomechanical factors. These factors include excessive valgus stress, internal tibial rotation, and anterior tibial translation. Excessive valgus stress refers to the inward angulation of the knee joint, which can put strain on the ACL. Internal tibial rotation occurs when the tibia rotates inward, causing the ACL to twist and potentially tear. Anterior tibial translation refers to the forward movement of the tibia relative to the femur, which can also strain the ACL. To manage ACL injuries, various approaches are employed. Non-surgical management may involve physical therapy to strengthen the surrounding muscles and improve stability. Surgical management may involve ACL reconstruction, where a graft is used to replace the torn ligament. Rehabilitation following surgery is crucial and typically includes a combination of exercises, bracing, and gradual return to activity to ensure proper healing and prevent re-injury.
Electrical muscle stimulation (EMS) has been shown to have potential benefits in enhancing muscle recovery after orthopedic surgery. EMS involves the use of electrical impulses to stimulate muscle contractions, which can help improve blood flow, reduce muscle atrophy, and promote tissue healing. By targeting specific muscle groups, EMS can help activate dormant muscles and prevent muscle loss during the post-surgical immobilization period. Additionally, EMS can aid in reducing pain and inflammation, improving range of motion, and accelerating the rehabilitation process. Studies have demonstrated the effectiveness of EMS in various orthopedic surgeries, such as knee and shoulder surgeries, by facilitating muscle recovery and enhancing overall functional outcomes. However, it is important to note that EMS should be used under the guidance of a healthcare professional and tailored to individual patient needs to ensure optimal results and minimize potential risks.