Gait analysis is a method used in sports medicine to assess and analyze an individual's walking or running pattern. It involves the measurement and evaluation of various parameters such as stride length, step width, foot placement, and joint angles during the gait cycle. By analyzing these parameters, sports medicine professionals can identify any abnormalities or imbalances in the way a person moves, which can help in diagnosing and treating injuries or improving athletic performance. Gait analysis is typically performed using specialized equipment such as motion capture systems, force plates, and pressure sensors.
Gait analysis can identify various types of gait abnormalities that may be present in individuals. These abnormalities include but are not limited to: limping, toe walking, foot drop, excessive pronation or supination, asymmetrical gait, and abnormal joint movements. By identifying these abnormalities, sports medicine professionals can gain insights into the underlying causes of musculoskeletal issues or performance limitations. This information is crucial for developing targeted treatment plans or interventions to address the specific gait abnormality and improve overall function.
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
Gait analysis plays a significant role in diagnosing and treating musculoskeletal disorders by providing valuable information about an individual's movement patterns. By analyzing the gait cycle, sports medicine professionals can identify any deviations from the normal movement pattern, which can help in diagnosing the root cause of the musculoskeletal disorder. Additionally, gait analysis can assist in monitoring the progress of treatment interventions and rehabilitation programs by objectively measuring changes in gait parameters over time. This allows for the adjustment of treatment plans and the evaluation of their effectiveness in improving the individual's condition.
During gait analysis, several key parameters are measured to understand an individual's walking pattern. These parameters include stride length, step width, cadence, stance time, swing time, and joint angles at various phases of the gait cycle. Stride length provides information about the distance covered with each step, while step width indicates the lateral distance between the feet. Cadence refers to the number of steps taken per minute, and stance time and swing time represent the duration of the foot on the ground and in the air, respectively. Joint angles, such as hip, knee, and ankle angles, are measured to assess the range of motion and any abnormalities in joint movement. By analyzing these parameters, sports medicine professionals can gain a comprehensive understanding of an individual's walking pattern and identify any deviations or abnormalities that may require intervention.
Yes, gait analysis can be used to assess the effectiveness of rehabilitation programs for patients with mobility impairments. By comparing pre- and post-rehabilitation gait analysis results, sports medicine professionals can objectively measure changes in gait parameters and determine the impact of the rehabilitation program on the individual's walking pattern. This information is crucial for evaluating the effectiveness of the program and making any necessary adjustments to optimize the patient's recovery. Gait analysis provides quantitative data that can be used to track progress, set goals, and tailor rehabilitation interventions to address specific gait abnormalities or limitations.
Gait analysis contributes significantly to the design and development of prosthetics and orthotics. By analyzing the gait patterns of individuals with limb loss or musculoskeletal impairments, sports medicine professionals can identify the specific needs and requirements for prosthetic limbs or orthotic devices. Gait analysis helps in determining the optimal alignment, fit, and function of these devices to ensure proper biomechanics and improve overall mobility. By considering the individual's gait parameters, such as stride length, joint angles, and foot placement, prosthetists and orthotists can customize the design and alignment of the devices to enhance the individual's walking pattern and maximize their functional outcomes.
There are certain limitations and challenges associated with gait analysis techniques that researchers are working to overcome. One limitation is the reliance on specialized equipment and facilities, which may not be easily accessible or affordable for all healthcare settings. Additionally, the interpretation of gait analysis data requires expertise and experience, as there can be variations in normal gait patterns among individuals. Furthermore, gait analysis is typically performed in a controlled laboratory environment, which may not fully capture the individual's natural walking pattern in real-world conditions. Researchers are working on developing portable and affordable gait analysis systems that can be used in various settings. They are also exploring the use of artificial intelligence and machine learning algorithms to automate the analysis process and improve the accuracy and reliability of gait analysis results.
Individuals with osteoporosis can benefit from specific exercise guidelines to improve bone health. Weight-bearing exercises, such as walking, jogging, and dancing, are recommended as they help stimulate bone formation and increase bone density. Resistance exercises, such as lifting weights or using resistance bands, can also be beneficial as they help strengthen muscles and bones. It is important to engage in exercises that target different muscle groups and incorporate a variety of movements to promote overall bone health. Additionally, balance and posture exercises, such as yoga or tai chi, can help improve stability and reduce the risk of falls, which is particularly important for individuals with osteoporosis who are at a higher risk of fractures. It is crucial for individuals with osteoporosis to consult with a healthcare professional or a qualified exercise specialist to develop a personalized exercise program that takes into account their specific needs and limitations.
Craniosacral therapy, a gentle hands-on technique that focuses on the craniosacral system, has been suggested as a potential method to alleviate symptoms of migraines. This alternative therapy involves the manipulation of the bones and tissues in the head, neck, and spine to improve the flow of cerebrospinal fluid and release any restrictions or tensions in the craniosacral system. While there is limited scientific evidence to support its effectiveness, some individuals have reported positive outcomes in terms of reducing the frequency and intensity of migraines. It is important to note that craniosacral therapy should not be used as a substitute for medical treatment, but rather as a complementary approach to managing migraines.
Therapists utilize gait analysis as a valuable tool to detect and assess abnormalities in a person's walking pattern and subsequently develop appropriate interventions. By carefully observing and analyzing the individual's gait, therapists can identify deviations from the normal biomechanical patterns, such as asymmetry, limited range of motion, or irregular foot placement. They may also employ various measurement techniques, including video recording, force plates, and motion sensors, to gather quantitative data on the person's gait parameters, such as step length, cadence, and ground reaction forces. This comprehensive analysis allows therapists to pinpoint specific areas of dysfunction and design targeted interventions, such as corrective exercises, gait training, or orthotic prescriptions, to address the identified abnormalities and improve the individual's overall walking ability and functional mobility.
Swimmers can greatly benefit from incorporating exercises that focus on improving shoulder stability. One highly effective exercise is the prone Y-T-W exercise, which targets the muscles in the upper back and shoulders. This exercise involves lying face down on a mat or bench and lifting the arms up in a Y shape, then a T shape, and finally a W shape, while engaging the shoulder blades and keeping the core stable. Another beneficial exercise is the external rotation exercise, which specifically targets the rotator cuff muscles. This exercise can be performed using resistance bands or dumbbells, with the swimmer holding the weight in one hand and rotating the arm outward against the resistance. Additionally, exercises such as the plank and side plank can help improve overall shoulder stability by engaging the core and promoting proper alignment. By incorporating these exercises into their training routine, swimmers can enhance their shoulder stability and reduce the risk of injury.
Mindfulness-based stress reduction (MBSR) has shown promising results in improving the quality of life in cancer survivors. Numerous studies have demonstrated the positive impact of MBSR on various aspects of well-being, including physical, psychological, and social domains. By incorporating mindfulness practices such as meditation, body awareness, and gentle movement, MBSR helps cancer survivors develop a greater sense of self-awareness, acceptance, and resilience. This holistic approach addresses the unique challenges faced by cancer survivors, such as anxiety, depression, pain, and fatigue. Moreover, MBSR fosters a sense of community and support among participants, which can further enhance their overall quality of life. The integration of MBSR into the standard care for cancer survivors has the potential to significantly improve their well-being and promote long-term recovery.