For individuals working at a desk or work station where the majority of the work is done in a sitting position and increases the risk for a variety of health problems, can using a standing desk help prevent musculoskeletal problems and improve short and long-term wellness?
Stand Desks
More than 80% of jobs are done in a seated position. Stand desks have proven to help. (Allene L. Gremaud et al., 2018) An adjustable stand desk is intended to be the standing height of an individual. Some desks can be lowered to use while sitting. These desks can improve:
Blood circulation
Back pain
Energy
Focus
Individuals who are less sedentary may experience decreased depression, anxiety, and risk of chronic disease.
Improve Posture and Decrease Back Pain
Sitting for prolonged periods can cause fatigue and physical discomfort. Back pain symptoms and sensations are common, especially when practicing unhealthy postures, already dealing with existing back problems, or using a non-ergonomic desk set-up. Instead of only sitting or standing for the whole workday, alternating between sitting and standing is far healthier. Practicing sitting and standing regularly reduces body fatigue and lower back discomfort. (Alicia A. Thorp et al., 2014) (Grant T. Ognibene et al., 2016)
Increases Energy Levels
Prolonged sitting correlates with fatigue, reduced energy, and productivity. A sit-stand desk can provide benefits like increased productivity levels. Researchers discovered that sit-stand desks could improve the general health and productivity of office workers. Individuals in the study reported:
According to the CDC, six in 10 individuals in the U.S. have at least one chronic disease, like diabetes, heart disease, stroke, or cancer. Chronic disease is the leading cause of death and disability, as well as a leading force of healthcare costs. (Centers for Disease Control and Prevention. 2023) While further research is needed to see if standing desks can reduce the risk of chronic disease, one study looked to quantify the association between sedentary time and the risk of chronic disease or death. Researchers reported that sedentariness for prolonged periods was independently associated with negative health outcomes regardless of physical activity. (Aviroop Biswas et al., 2015)
Improved Mental Focus
Sitting for extended periods slows down blood circulation. This decreased blood flow to the brain lowers cognitive function and increases the risk of neurodegenerative conditions. One study confirmed that healthy individuals who worked in a prolonged sitting position had reduced brain blood flow. The study found that frequent, short walks could help prevent this. (Sophie E. Carter et al., 2018) Standing increases blood and oxygen circulation. This improves cognitive function, which also helps improve focus and concentration.
Depression and Anxiety Reduction
Modern lifestyles typically contain large amounts of sedentary behavior.
However, there is a small amount about the mental health risks of prolonged sedentary behavior. There have been a few studies aimed at improving public understanding. One study focused on a group of older adults, having them self-report sedentary habits that included television, internet, and reading time. This information was compared to their individual scoring on the Centre of Epidemiological Studies Depression scale. (Mark Hamer, Emmanuel Stamatakis. 2014)
The researchers found that certain sedentary behaviors are more harmful to mental health than others.
Television watching, for example, resulted in increased depressive symptoms and decreased cognitive function. (Mark Hamer, Emmanuel Stamatakis. 2014)
Internet use had the opposite effect, decreasing depressive symptoms and increasing cognitive function.
Researchers theorize that the results come from the contrasting environmental and social contexts in which they are happening. (Mark Hamer, Emmanuel Stamatakis. 2014)
Another study looked at the possible correlation between sedentary behavior and anxiety.
Incorporating a standing desk into the workspace can help to reduce the negative effects of sedentary behaviors, leading to improved productivity, improved mental and physical health, and a healthy work environment for individuals who work long hours at a desk or workstation.
Understanding Academic Low Back Pain: Impact and Chiropractic Solutions
References
Gremaud, A. L., Carr, L. J., Simmering, J. E., Evans, N. J., Cremer, J. F., Segre, A. M., Polgreen, L. A., & Polgreen, P. M. (2018). Gamifying Accelerometer Use Increases Physical Activity Levels of Sedentary Office Workers. Journal of the American Heart Association, 7(13), e007735. doi.org/10.1161/JAHA.117.007735
Thorp, A. A., Kingwell, B. A., Owen, N., & Dunstan, D. W. (2014). Breaking up workplace sitting time with intermittent standing bouts improves fatigue and musculoskeletal discomfort in overweight/obese office workers. Occupational and environmental medicine, 71(11), 765–771. doi.org/10.1136/oemed-2014-102348
Ognibene, G. T., Torres, W., von Eyben, R., & Horst, K. C. (2016). Impact of a Sit-Stand Workstation on Chronic Low Back Pain: Results of a Randomized Trial. Journal of occupational and environmental medicine, 58(3), 287–293. doi.org/10.1097/JOM.0000000000000615
Ma, J., Ma, D., Li, Z., & Kim, H. (2021). Effects of a Workplace Sit-Stand Desk Intervention on Health and Productivity. International journal of environmental research and public health, 18(21), 11604. doi.org/10.3390/ijerph182111604
Centers for Disease Control and Prevention. Chronic disease.
Biswas, A., Oh, P. I., Faulkner, G. E., Bajaj, R. R., Silver, M. A., Mitchell, M. S., & Alter, D. A. (2015). Sedentary time and its association with risk for disease incidence, mortality, and hospitalization in adults: a systematic review and meta-analysis. Annals of internal medicine, 162(2), 123–132. doi.org/10.7326/M14-1651
Carter, S. E., Draijer, R., Holder, S. M., Brown, L., Thijssen, D. H. J., & Hopkins, N. D. (2018). Regular walking breaks prevent the decline in cerebral blood flow associated with prolonged sitting. Journal of applied physiology (Bethesda, Md. : 1985), 125(3), 790–798. doi.org/10.1152/japplphysiol.00310.2018
Hamer, M., & Stamatakis, E. (2014). Prospective study of sedentary behavior, risk of depression, and cognitive impairment. Medicine and science in sports and exercise, 46(4), 718–723. doi.org/10.1249/MSS.0000000000000156
Teychenne, M., Costigan, S. A., & Parker, K. (2015). The association between sedentary behaviour and risk of anxiety: a systematic review. BMC public health, 15, 513. doi.org/10.1186/s12889-015-1843-x
Individuals with neck and shoulder pain may experience what feels like tightened lumps or knots in and around the muscles where the neck and shoulder meet. Can using kinesiology tape for neck and shoulder trigger points help to loosen and release them, restore function, and bring pain relief?
Kinesiology Tape For Neck and Shoulder Trigger Points
The upper trapezius and levator scapula muscles are where the shoulder and neck come together and are often the location of trigger point formations. These trigger points can cause tension, pain, and muscular spasms in the neck and shoulders. Various treatments for releasing trigger points and alleviating the pain symptoms include therapeutic massage, trigger point release, and chiropractic adjustments in a multidisciplinary treatment approach.
Electrical stimulation and ultrasound have often been used to break up the knots, but scientific evidence has shown that these treatments alone are not the most effective. (David O. Draper et al., 2010)
Stretching the neck muscles can bring tension relief and help release the knots.
Kinesiology tape can decrease the pain and spasms and help to release the trigger points.
Therapy
Using kinesiology tape is a form of physical therapy that can be used in various ways.
The tape helps lift the upper tissues from underlying tissues to increase circulation and release muscular spasms.
It can help improve muscular contractions, decrease swelling, and inhibit pain in injured tissues.
Helps stop the trigger points and knots from worsening.
The tape can also be used for managing lymphedema.
Usage
To decrease trigger points, individuals can use a specific kinesiology tape strip called a lift strip. Individuals can consult their healthcare provider or physical therapist to show them the various types of strips to learn how to cut them properly.
Before using kinesiology tape, consult a healthcare provider or physical therapist to assess the injury and situation.
Kinesiology tape is not for everyone, and some people have conditions where the use of kinesiology tape should be avoided altogether.
A therapist can evaluate the neck pain and trigger points to determine if the individual should use kinesiology tape.
To use kinesiology tape for neck and shoulder trigger points:
Get comfortable with the neck and shoulders exposed.
Cut one lift strip for each side of the neck, if necessary.
The lift strip should be around 3 to 4 inches long.
Remove the paper backing in the center with the exposed tape in the center, which should look like a band-aid.
Both ends of the lift strip should still have the paper backing on.
Stretch out the kinesiology tape.
Place the stretched tape directly over the trigger points in the upper shoulder area.
Remove the backing on either side of the lift strip and place the ends on without stretching.
Gently rub the tape to help the adhesive adhere.
Once the tape has been applied, it can be left there for 2 to 5 days.
It’s ok if it gets wet with a bath or shower.
Monitor the skin around the tape to watch for redness or other signs of a negative reaction to the tape.
Kinesiology taping can be a useful tool to decrease pain and spasms but does not replace professional treatment, prescribed exercises and stretches, and posture retraining.
The physical therapy team will teach proper self-care strategies for the individual’s condition.
For individuals with neck and shoulder pain and muscle spasms, a trial of kinesiology taping may help alleviate symptoms and improve the overall injury.
The Non-Surgical Approach to Wellness with Chiropractic Care
References
Draper, D. O., Mahaffey, C., Kaiser, D., Eggett, D., & Jarmin, J. (2010). Thermal ultrasound decreases tissue stiffness of trigger points in upper trapezius muscles. Physiotherapy theory and practice, 26(3), 167–172. doi.org/10.3109/09593980903423079
For individuals experiencing gluteus minimus pain and are unsure where to start to deal with it, can a physical therapist, chiropractor, or general practitioner help diagnose lower extremity pain and develop an appropriate treatment plan?
Gluteus Minimus Muscles
The gluteus minimus is the smallest muscle of the gluteal muscles. Combined with the gluteus maximus and gluteus medius, these muscles make up the glutes. The glutes help form the buttocks shape, stabilize the hips, rotate the legs, and raise the thighs. The gluteus minimus and medius specifically support the gluteus maximus’s ability to raise the leg to the side and rotate the thigh inwards. (ScienceDirect. 2011)
Anatomy
The gluteus minimus muscles are triangular and lie underneath the gluteus medius near the rotators of the hip joints. The muscles start in the lower ilium region, the upper and largest area of the hip bone that makes up the pelvis and attaches to the femur/thigh bone.
The fibers on the top part of the muscle are thick and compact, while the lower fibers are flat and spread out.
The superior gluteal nerves and blood vessels separate the gluteus minimus and the medius.
The gluteus medius muscles start on the upper ilium region, which covers the gluteus minimus muscle entirely. The location of the gluteus minimus muscles envelopes the sciatic notch or the area in the pelvis that houses the piriformis muscle, superior gluteal vein, and superior gluteal artery, which provide a certain amount of protection.
Function
Movement depends on the location of the femur. The gluteus minimus muscle’s function is to:
Flex
Rotate
Stabilize
When the thigh is extended, it helps abduct or swing the leg out away from the body.
When the hip bones are flexed, the gluteus minimus rotates the thigh inward with the help of the gluteus medius.
The movements are done with the support of the muscle fibers, which contract to move the thigh in both directions. (ScienceDirect. 2011)
The gluteus minimus and the medius also stabilize the hips and pelvis during movement and when resting.
Associated Conditions
One of the most common injuries is muscle wearing and tearing, which can cause pain over and around the greater trochanter. This is known as greater trochanteric pain syndrome or GTPS, a condition usually caused by a gluteus medius or minimus tendinopathy, which can include inflammation of the surrounding bursae. (Diane Reid. 2016) For a gluteus minimus tear, the pain/sensations will be felt outside the hip, especially when rolling or applying weight on the affected side. A tear can happen suddenly with no particular activity causing the tear to occur aside from normal use and stress on the muscle. Physical activities like walking may be painful.
Rehabilitation
Treatment depends on the severity of the condition. Usually, rest, ice, and over-the-counter medication can help reduce swelling and pain symptoms. For pain symptoms that are not subsiding, it’s recommended to see a healthcare provider who can run an MRI or X-ray to see the condition of the muscle and rule out other causes of pain. The healthcare provider will refer the patient to a physical therapy team that can evaluate the strength of the gluteus minimus and provide a list of exercises and stretches to help repair the muscle while conditioning the surrounding muscles. (SportsRec. 2017) Depending on the level of pain, sometimes the healthcare provider will prescribe a cortisone injection to the gluteus minimus muscle in conjunction with physical therapy. This will help alleviate the pain so that the physical therapy exercises can be done comfortably, allowing the gluteus maximus muscle to heal properly and strengthen. (Julie M. Labrosse et al., 2010)
Reid D. (2016). The management of greater trochanteric pain syndrome: A systematic literature review. Journal of orthopaedics, 13(1), 15–28. doi.org/10.1016/j.jor.2015.12.006
Labrosse, J. M., Cardinal, E., Leduc, B. E., Duranceau, J., Rémillard, J., Bureau, N. J., Belblidia, A., & Brassard, P. (2010). Effectiveness of ultrasound-guided corticosteroid injection for the treatment of gluteus medius tendinopathy. AJR. American journal of roentgenology, 194(1), 202–206. doi.org/10.2214/AJR.08.1215
For individuals experiencing a turf toe injury, can knowing the symptoms help athletes and non-athletes with treatment, recovery time, and returning to activities?
Turf Toe Injury
A turf toe injury affects the soft tissue ligaments and tendons at the base of the big toe under the foot. This condition usually occurs when the toe is hyperextended/forced upward, such as when the ball of the foot is on the ground and the heel is lifted. (American Academy of Orthopaedic Surgeons. 2021) The injury is common among athletes who play sports on artificial turf, which is how the injury got its name. However, it can also affect non-athletes, like individuals working on their feet all day.
Recovery time after turf toe injury depends on the severity and the type of activities the individual plans to return to.
Returning to high-level sports activities after a severe injury can take six months.
These injuries vary in severity but usually improve with conservative treatment. In severe cases, surgery could be required.
Pain is the primary issue that stops physical activities after a grade 1 injury, while grades 2 and 3 can take weeks to months to heal completely.
Meaning
A turf toe injury refers to a metatarsophalangeal joint strain. This joint comprises ligaments that connect the bone on the sole of the foot, below the big toe/proximal phalanx, to the bones that connect the toes to the larger bones in the feet/metatarsals. The injury is usually caused by hyperextension that often results from a pushing-off motion, like running or jumping.
If experiencing turf toe symptoms, see a healthcare provider for a proper diagnosis so they can develop a personalized treatment plan. They will perform a physical exam to assess pain, swelling, and range of motion. (American Academy of Orthopaedic Surgeons. 2021) If the healthcare provider suspects tissue damage, they may recommend imaging with X-rays and (MRI) to grade the injury and determine the proper course of action.
Grades 2 and 3 come with partial or complete tissue tearing, severe pain, and swelling. Treatments for more severe turf toe can include: (Ali-Asgar Najefi et al., 2018)
Limited weight bearing
Using assistive devices like crutches, a walking boot, or a cast.
Physical therapy also includes proprioception and agility training exercises, orthotics, and wearing recommended shoes for specific physical activities. (Lisa Chinn, Jay Hertel. 2010)
A physical therapist can also help ensure that the individual does not return to physical activities before the injury is fully healed and prevent the risk of re-injury.
Grade 1 – Subjective as it varies depending on the individual’s pain tolerance.
Grade 2 – Four to six weeks of immobilization.
Grade 3 – Eight weeks minimum of immobilization.
It can take up to six months to return to normal function.
Returning To Normal Activities
After a grade 1 turf toe injury, individuals can return to normal activities once the pain is under control. Grades 2 and 3 take longer to heal. Returning to sports activities after a grade 2 injury can take around two or three months, while grade 3 injuries and cases that require surgery can take up to six months. (Ali-Asgar Najefi et al., 2018)
Sports Chiropractic Treatment
References
American Academy of Orthopaedic Surgeons. (2021). Turf toe.
American College of Foot and Ankle Surgeons. Foot Health Facts. (2023). RICE protocol.
Najefi, A. A., Jeyaseelan, L., & Welck, M. (2018). Turf toe: A clinical update. EFORT open reviews, 3(9), 501–506. doi.org/10.1302/2058-5241.3.180012
Pinter, Z. W., Farnell, C. G., Huntley, S., Patel, H. A., Peng, J., McMurtrie, J., Ray, J. L., Naranje, S., & Shah, A. B. (2020). Outcomes of Chronic Turf Toe Repair in Non-athlete Population: A Retrospective Study. Indian journal of orthopaedics, 54(1), 43–48. doi.org/10.1007/s43465-019-00010-8
Chinn, L., & Hertel, J. (2010). Rehabilitation of ankle and foot injuries in athletes. Clinics in sports medicine, 29(1), 157–167. doi.org/10.1016/j.csm.2009.09.006
For individuals trying to optimize muscle growth, protein intake is essential. However, the body is limited by how much protein can synthesize to repair and grow muscles. Can knowing protein intake timing, amount, and how to best stimulate muscle growth help achieve better results?
Muscle Protein Synthesis
Muscle protein synthesis is a physiological process of producing new muscle protein and is an important component of how the body maintains and builds muscle. Muscle growth is achieved with resistance training and protein intake. (Tanner Stokes, et al., 2018)
How Protein Synthesis Works
Protein is the building block of muscles, while protein synthesis is a natural metabolic process in which protein is produced to repair muscle damage caused by exercise. This happens from amino acids binding to skeletal muscle proteins, increasing muscle size. It counteracts muscle protein breakdown (MPB) due to protein loss during exercise. The breakdown of muscles is a necessary part of building muscle. When damaged, muscles will build back larger, so long as enough calories and protein are consumed to repair and grow the muscles. Muscle protein synthesis can be enhanced by increasing protein intake immediately following exercise. Learning to stimulate muscle protein synthesis through exercise and diet can help accelerate muscle growth, expedite recovery, improve physical performance, and increase overall endurance. (Cameron J. Mitchell et al., 2014)
Effects of Exercise
Protein balance describes the relationship between muscle protein breakdown and muscle protein synthesis. When the body is in protein balance, no muscle growth or wasting occurs, and the individual is considered in a healthy state of biological equilibrium/homeostasis, also known as maintenance. To stimulate muscle growth, individuals need to shake up the protein balance. Although it may seem counter-intuitive, exercise can break down muscle protein, but not more than the amount of protein the body can synthesize. (Felipe Damas, et al., 2015) The more intense the workout, the greater the muscle protein synthesis, as the muscle breakdown stimulates the repair and growth of tissues. Scientists measure intensity by the one-repetition maximum – 1-RM – meaning the maximum weight an individual can lift for one repetition. According to a research study, workout intensities of under 40% of the 1-RM will not affect muscle protein synthesis. And intensities greater than 60% will double or triple muscle protein synthesis. (P. J. Atherton, K Smith. 2012)
Food Impact
The relationship between diet and protein balance is not so straightforward. Even with increased protein intake, muscle protein synthesis occurs for a specific period. This is because the body can only utilize a certain amount of the essential amino acids it receives, with anything more being broken down and excreted by the liver. Nutritionists recommend about 1.4 to 2.0 grams of protein per kilogram of body weight per day for building muscle and strength. (Ralf Jäger, et al., 2017) Enough protein can be obtained by focusing on dairy, eggs, lean meats, nuts, and legumes. It is also recommended to consume enough whole grains, healthy fats, fruits, and vegetables to help the body perform and repair properly. For example, carbohydrates are necessary for muscle building as they stimulate insulin release that supports muscle cell protein absorption. (Vandré Casagrande Figueiredo, David Cameron-Smith. 2013) A study looked into response rates in men prescribed 10, 20, or 40 grams of whey protein immediately following resistance training. Researchers noted the following results: (Oliver C. Witard et al., 2014)
10 grams of whey protein – No effect on muscle protein synthesis.
20 grams – Increased muscle protein synthesis by 49%.
40 grams – Increased the muscle protein synthesis by 56% but also caused the excessive accumulation of urea.
Consuming 20 grams to 40 grams of whey protein after resistance training also increased other essential amino acids associated with lean muscle growth. (Lindsay S. Macnaughton et al., 2016)
Whey protein is a fast-digesting protein.
Increased results can be obtained by consuming slower-digesting protein throughout the day.
Muscle gains vary from person to person as everyone’s body is different. Individuals considering consuming protein beyond the recommended dietary intake should consult their doctor or a registered nutritionist to understand the potential benefits and risks.
Building A Stronger Body
References
Stokes, T., Hector, A. J., Morton, R. W., McGlory, C., & Phillips, S. M. (2018). Recent Perspectives Regarding the Role of Dietary Protein for the Promotion of Muscle Hypertrophy with Resistance Exercise Training. Nutrients, 10(2), 180. doi.org/10.3390/nu10020180
Mitchell, C. J., Churchward-Venne, T. A., Parise, G., Bellamy, L., Baker, S. K., Smith, K., Atherton, P. J., & Phillips, S. M. (2014). Acute post-exercise myofibrillar protein synthesis is not correlated with resistance training-induced muscle hypertrophy in young men. PloS one, 9(2), e89431. doi.org/10.1371/journal.pone.0089431
Damas, F., Phillips, S., Vechin, F. C., & Ugrinowitsch, C. (2015). A review of resistance training-induced changes in skeletal muscle protein synthesis and their contribution to hypertrophy. Sports medicine (Auckland, N.Z.), 45(6), 801–807. doi.org/10.1007/s40279-015-0320-0
Atherton, P. J., & Smith, K. (2012). Muscle protein synthesis in response to nutrition and exercise. The Journal of physiology, 590(5), 1049–1057. doi.org/10.1113/jphysiol.2011.225003
Jäger, R., Kerksick, C. M., Campbell, B. I., Cribb, P. J., Wells, S. D., Skwiat, T. M., Purpura, M., Ziegenfuss, T. N., Ferrando, A. A., Arent, S. M., Smith-Ryan, A. E., Stout, J. R., Arciero, P. J., Ormsbee, M. J., Taylor, L. W., Wilborn, C. D., Kalman, D. S., Kreider, R. B., Willoughby, D. S., Hoffman, J. R., … Antonio, J. (2017). International Society of Sports Nutrition Position Stand: protein and exercise. Journal of the International Society of Sports Nutrition, 14, 20. doi.org/10.1186/s12970-017-0177-8
Figueiredo, V. C., & Cameron-Smith, D. (2013). Is carbohydrate needed to further stimulate muscle protein synthesis/hypertrophy following resistance exercise?. Journal of the International Society of Sports Nutrition, 10(1), 42. doi.org/10.1186/1550-2783-10-42
Witard, O. C., Jackman, S. R., Breen, L., Smith, K., Selby, A., & Tipton, K. D. (2014). Myofibrillar muscle protein synthesis rates subsequent to a meal in response to increasing doses of whey protein at rest and after resistance exercise. The American journal of clinical nutrition, 99(1), 86–95. doi.org/10.3945/ajcn.112.055517
Macnaughton, L. S., Wardle, S. L., Witard, O. C., McGlory, C., Hamilton, D. L., Jeromson, S., Lawrence, C. E., Wallis, G. A., & Tipton, K. D. (2016). The response of muscle protein synthesis following whole-body resistance exercise is greater following 40 g than 20 g of ingested whey protein. Physiological reports, 4(15), e12893. doi.org/10.14814/phy2.12893
For individuals wanting to eat pancakes regularly, are there ways to increase pancake nutrition and lower the calorie and carb counts so they can be included in a balanced diet?
Pancake Nutrition
This high-carbohydrate meal can provide enough energy to fuel a day’s physical activity.
Nutrition
The following nutrition information is provided for:
Pancakes made with whole-wheat flour offer more fiber and protein. The following is nutrition info for two or three whole-wheat pancakes (150g) made from a mix. (Child Nutrition Recipe Box. 2023)
Calories – 348
Fat – 15g
Sodium – 594mg
Carbohydrates – 45g
Fiber – 6g
Sugars – 6g
Protein – 12g
Carbohydrates
Pancakes will increase carbohydrate intake. The body uses carbohydrates as a primary fuel source, making them an important nutrient. However, most nutritionists suggest that individuals get their daily carbohydrates from nutrient-dense sources. Pancakes typically don’t fall into this category. White flour pancakes do not provide much fiber, and around 60 grams of carbohydrates are consumed in this meal. Substituting whole-wheat flour changes the amount to around 6g of fiber or 20% of the daily recommended value.
Fat
Pancakes can include dairy and eggs and are topped with butter that contributes a significant amount of fat. Pancake mix may contain trans fat. Some brands include partially hydrogenated oils. Health experts recommend that individuals limit or completely avoid foods containing trans fat. If the label ingredient list contains partially hydrogenated ingredients, it is recommended to avoid it. (MedlinePlus. 2022)
Protein
Pancakes may provide some protein, which varies based on the type of flour used. Some brands add protein powder to increase intake.
Vitamins and Minerals
Pancakes and ready mixes are generally made from enriched flour. Enriched foods are those that have had nutrients added during the manufacturing process. In most cases, the nutrients, vitamins, and minerals are stripped away, and then some are added back in during processing. Constantly eating enriched bread products limits diet-friendly fiber and nutrients. The enriched flour in pancakes and added sugar and syrup raise blood sugar levels rapidly and then generate hunger shortly afterward.
Calories
Total nutrition numbers also depend on serving size. The numbers on the label only apply to a single serving which is just two medium pancakes. Many individuals consume 3-4 medium pancakes and double the amount of butter and syrup as well. This can add up to more than 1,000 calories.
Benefits
Whole-wheat pancakes made with whole-grain flour are more nutritious than pancakes made with white flour and can be a delicious way to eat more whole grains. They can be topped with berries or other fruits for added fiber and nutrients.
Digestion
Whole-wheat pancakes made with whole-grain flour provide significant fiber for healthy digestion. Fiber helps with waste evacuation and has prebiotic compounds that fuel beneficial gut bacteria. (Joanne Slavin. 2013)
Improves Hunger Satisfaction
Whole-grain pancakes taste heartier and include fiber that keeps the body fuller longer than pancakes made with faster-digesting refined flour.
Decreases Risk of Heart Disease
A review of studies examining whole grain consumption and heart disease found that eating whole grains was associated with a reduced risk of heart disease. (Dagfinn Aune, et al., 2016)
Reduces Risk of Obesity
Research suggests that whole grain intake reduces the risk of obesity and could help individuals maintain a stable weight. (Katrina R. Kissock et al., 2021) The fiber will also help keep the fuller longer after the meal.
Slavin J. (2013). Fiber and prebiotics: mechanisms and health benefits. Nutrients, 5(4), 1417–1435. doi.org/10.3390/nu5041417
Aune, D., Keum, N., Giovannucci, E., Fadnes, L. T., Boffetta, P., Greenwood, D. C., Tonstad, S., Vatten, L. J., Riboli, E., & Norat, T. (2016). Whole grain consumption and risk of cardiovascular disease, cancer, and all cause and cause specific mortality: systematic review and dose-response meta-analysis of prospective studies. BMJ (Clinical research ed.), 353, i2716. doi.org/10.1136/bmj.i2716
Kissock, K. R., Neale, E. P., & Beck, E. J. (2021). Whole Grain Food Definition Effects on Determining Associations of Whole Grain Intake and Body Weight Changes: A Systematic Review. Advances in nutrition (Bethesda, Md.), 12(3), 693–707. doi.org/10.1093/advances/nmaa122
Centers for Disease Control and Prevention. (2022). Folic acid.
Can individuals with sensory nerve dysfunction incorporate nonsurgical decompression to restore sensory-mobility function to their bodies?
Introduction
The spinal column in the musculoskeletal system comprises bones, joints, and nerves that work together with various muscles and tissues to ensure that the spinal cord is protected. The spinal cord is part of the central nervous system where the nerve roots are spread out to the upper and lower body parts that supply sensory-motor functions. This allows the body to move and function without pain or discomfort. However, when the body and spine ages or when a person is dealing with injuries, the nerve roots can become irritated and cause weird sensations like numbness or tingling, often correlating with body pain. This can cause a socio-economic burden on many individuals and, if not treated right away, can lead to chronic pain. To that point, it can lead to many individuals dealing with body extremity pain associated with sensory nerve dysfunction. This causes many individuals dealing with musculoskeletal disorders to start looking for treatment. Today’s article examines how nerve dysfunction affects the extremities and how nonsurgical decompression can help reduce nerve dysfunction to allow mobility back to the upper and lower limbs. We speak with certified medical providers who incorporate our patients’ information to provide nonsurgical solutions like decompression to help individuals with nerve dysfunction. We also inform patients how nonsurgical decompression can restore mobility-sensory to the upper and lower extremities. We encourage our patients to ask intricated and educational questions to our associated medical providers about the pain-like symptoms they are experiencing correlating with the sensory nerve dysfunction. Dr. Alex Jimenez, D.C., utilizes this information as an academic service. Disclaimer.
How Nerve Dysfunction Affects The Extremities
Do you experience tingling or numb sensations in your hands or feet that don’t want to go away? Do you feel pain in different back portions that can only be relieved through stretching or resting? Or does it hurt to walk for long distances that you feel like you need to rest constantly? Many pain-like scenarios are associated with sensory nerve dysfunction that can affect the upper and lower extremities. When many individuals experience sensory nerve dysfunction and deal with weird sensations in their extremities, many think it is due to musculoskeletal pain in their neck, shoulders, or back. This is only part of the issue, as many environmental factors can be associated with sensory nerve pain, as the nerve roots are being compressed and agitated, causing sensory nerve dysfunction in the extremities. Since the nerve roots are spread out from the spinal cord, the brain sends the neuron information to the nerve roots to allow sensory-mobility function in the upper and lower extremities. This allows the body to be mobile without discomfort or pain and functional through daily activities. However, when many individuals start to do repetitive motions that cause the spinal disc to be compressed constantly, it can lead to potential disc herniation and musculoskeletal disorders. Since numerous nerve roots are spread to the different extremities, when the main nerve roots are aggravated, it can send pain signals to each extremity. Hence, many people are dealing with nerve entrapment that leads to lower back, buttock, and leg pain that can affect their daily routine. (Karl et al., 2022) At the same time, many people with sciatica are dealing with sensory nerve dysfunction that affects their walking ability. With sciatica, it can be associated with spinal disc pathology and causes many individuals to seek treatment. (Bush et al., 1992)
Sciatica Secrets Revealed-Video
When it comes to looking for treatment to reduce sensory nerve dysfunction, many individuals will opt for nonsurgical solutions to minimize the pain-like symptoms and reduce the pain signals that are causing the upper and lower extremities to suffer. Nonsurgical treatment solutions like decompression can help restore sensory nerve function through gentle traction by causing the spinal disc to lay off the aggravated nerve root and start the body’s natural healing process. At the same time, it helps reduce musculoskeletal disorders from returning. The video above shows how sciatica associated with sensory nerve dysfunction can be decreased through nonsurgical treatments to allow the body’s extremities to feel better.
Nonsurgical treatments can help reduce low back pain associated with sensory nerve dysfunction to restore sensory-motor function to the upper and lower extremities. Many individuals who incorporate nonsurgical treatments like decompression as part of their health and wellness routine can see improvement after consecutive treatment. (Chou et al., 2007) Since many healthcare practitioners incorporate nonsurgical treatments like decompression into their practices, there has been quite an improvement in pain management. (Bronfort et al., 2008)
When many individuals start to use nonsurgical decompression for sensory nerve dysfunction, many will see improvement in their pain, mobility, and activities of their daily living. (Gose et al., 1998). What spinal decompression does for the nerve roots is that it helps the affected disc that is aggravating the nerve root, pulls the disc back to its original position, and rehydrates it. (Ramos & Martin, 1994) When many individuals start thinking about their health and wellness, nonsurgical treatments can be effective for them due to their affordable cost and how they can be combined with other therapies to manage better the pain associated with nerve dysfunction affecting their body extremities.
References
Bronfort, G., Haas, M., Evans, R., Kawchuk, G., & Dagenais, S. (2008). Evidence-informed management of chronic low back pain with spinal manipulation and mobilization. Spine J, 8(1), 213-225. doi.org/10.1016/j.spinee.2007.10.023
Bush, K., Cowan, N., Katz, D. E., & Gishen, P. (1992). The natural history of sciatica associated with disc pathology. A prospective study with clinical and independent radiologic follow-up. Spine (Phila Pa 1976), 17(10), 1205-1212. doi.org/10.1097/00007632-199210000-00013
Chou, R., Huffman, L. H., American Pain, S., & American College of, P. (2007). Nonpharmacologic therapies for acute and chronic low back pain: a review of the evidence for an American Pain Society/American College of Physicians clinical practice guideline. Ann Intern Med, 147(7), 492-504. doi.org/10.7326/0003-4819-147-7-200710020-00007
Gose, E. E., Naguszewski, W. K., & Naguszewski, R. K. (1998). Vertebral axial decompression therapy for pain associated with herniated or degenerated discs or facet syndrome: an outcome study. Neurol Res, 20(3), 186-190. doi.org/10.1080/01616412.1998.11740504
Karl, H. W., Helm, S., & Trescot, A. M. (2022). Superior and Middle Cluneal Nerve Entrapment: A Cause of Low Back and Radicular Pain. Pain Physician, 25(4), E503-E521. www.ncbi.nlm.nih.gov/pubmed/35793175
Ramos, G., & Martin, W. (1994). Effects of vertebral axial decompression on intradiscal pressure. J Neurosurg, 81(3), 350-353. doi.org/10.3171/jns.1994.81.3.0350
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