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Weightbelt Science

tim290280

tim290280

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This is a repost, but it is easier on the eye and to access.

On The Use Weight Belts

A review invited by the National Strength and Conditioning Association

Scientific studies regarding the use of belts for athletic endeavours is scarce.
Much more evidence and insight exists for the use of belts in occupational settings. The relevant information from occupational usage is discussed in this article and is blended with the limited work on athletic/performance use to form a position statement. Given the assets and liabilities of belt wearing, they are not recommended for healthy individuals either in routine work or exercise participation. However, the temporary prescription of belts may help some individual workers return to work. The exception is for extreme athletic lifting where belts appear to increase torso stability to reduce the risk of buckling and provide some elastic extensor recoil to assist with the lift. But the possible liabilities underscore the counterpoint to this proposition. The individual must make their own informed decisions on whether or not to wear a belt although guidance is provided here for their prescription and use. The average person must be confused when they observe both Olympic lifters
and back-injured people wearing back belts. A review of the documented effects of belt wearing in occupational settings (McGill, 1993) would support that:

  • Those who have never had a previous back injury appear to have no additional protective benefit from wearing a belt.
  • Those who are injured while wearing a belt seem to risk a more severe injury.
  • Belts appear to give people the perception they can lift more and may in fact enable them to lift more.
  • Belts appear to increase intra-abdominal pressure and blood pressure.
  • Belts appear to change the lifting styles of some people to either decrease the loads on the spine or increase the loads on the spine. Other opinions have been expressed regarding the mechanisms of belts, although few hold up to scrutiny. For example, some have suggested that belts perform the following functions:
  • Remind people to lift properly
  • Support shear loading on the spine that results from the effect of gravity acting on the handheld load and mass of the upper body when the trunk is flexed
  • Reduce compressive loading of the lumbar spine through the hydraulic action of increased intra-abdominal pressure associated with belt wearing
  • Act as a splint on the torso, reducing the range of motion and thereby decreasing the risk of injury
  • Provide warmth to the lumbar region
  • Enhance proprioception via pressure to increase the perception of stability
  • Reduce muscular fatigue
  • Provide stiffening to the torso to enhance performance
Many of these remain contentious.

The Recreational/Occupational Use of Belts
While there are guidelines for belt wearing for occupational use, sporting use
requires a different approach. Occupational use is based on the premise of injury risk reduction while sporting use includes performance enhancement ? to lift more for example. Previous recommendations for occupational use (see McGill, 1993, 1999, 2004) presented data and evidence that neither completely supported, nor condemned, the wearing of abdominal/back belts. Given the available literature, it would appear that the universal prescription of belts (i.e., providing belts to all workers in an industrial operation) is not in the best interest of globally reducing the risk of injury. Uninjured workers do not appear to enjoy any additional benefit from belt wearing, and in fact may be exposing themselves to the risk of a more severe injury if they were to become injured. Moreover, they may have to confront the problem of weaning themselves from the belt. However, if some individual workers perceive a benefit from belt wearing, they may be allowed to wear a belt conditionally, but only on trial. Having considered the scientific evidence for belt wearing for occupational and athletic use that the mandatory conditions for occupational/recreational prescription (for which there should be no exception) are as follows:

1. Given the concerns regarding increased blood pressure and heart rate and issues of liability, all candidates for belt wearing should be screened for cardiovascular risk by medical personnel.

2. Given the concern that belt wearing may provide a false sense of security, belt wearers must receive education on lifting mechanics. All too often, belts are being promoted as a quick fix to the injury problem. Promotion of belts, conducted in this way, is detrimental to the goal of reducing injury as it redirects the focus from the cause of the injury. Education programs should include information on how tissues become injured, techniques to spare the back, and what to do about feelings of discomfort to avoid disabling injury.

3. Consultants should not prescribe belts until they have conducted a full ergonomic assessment of the individual?s job, or a very thorough analysis of their training/lifting technique. Belts are no substitute for poor lifting technique. The ergonomic approach should examine, and attempt to correct, the cause of the musculoskeletal overload and provide solutions to reduce the excessive loads.

4. Belts should not be considered for long-term use. The objective of any small-scale belt program should be to wean workers from the belts by insisting on mandatory participation in comprehensive fitness programs and education on lifting mechanics, combined with ergonomic assessment. Furthermore, consultants would be wise to continue vigilance in monitoring former belt wearers for a period of time following belt wearing, given that this period appears to be characterized by an elevated risk of injury.

5. An analysis of the anatomy and biomechanics of the torso shows that there is a natural belt formed by the abdominal wall and the lumbodorsal fascia. Training the core musculature enhances the stabilizing effect of the natural belt by both strengthening the core and improving the motor control of these muscles so that they work as a team to enhance back stability.

Belt use for Serious Lifting Athletes
Much of the occupational evidence has relevance for athletic use of belts. There is no question that belts assist in generating a few more Newton-meters (or foot-pounds) of torque in the torso through elastic recoil of a bent torso that is stiffened with a belt. However, if a neutral spine is preserved throughout the lift this effect is diminished. In other words, to obtain the maximal effect from a belt, the lifter must lift poorly and in a way that exposed the back to a much higher risk of injury! There is no question that belts assist in generating torso stiffness to reduce the risk of spine buckling in extreme heavy lifts. Many athletes working at this edge of the envelope will receive this assist. However, other techniques are employed to maximize the torso stiffness ? the lungs are filled to almost the top of tidal volume and the breath is then held. In some tasks, an athlete will only sip the air never allowing much air to leave the lungs that would reduce torso
stiffness. Belts also increase intra-abdominal pressure which in turn increases the CNS fluid pressure in the spine and, in turn, the brain. This decreases the transmural gradient (the pressure difference between the arterial blood pressure in the brain vessels and the brain itself) which in turn may reduce the risk of aneurysm, or stroke. Others have argued that this effect has detrimental implications for venous return to the heart. There appears to be no evidence to suggest where the balance lies on this issue. There are other
counter considerations. Evidence suggests that people change their motor patterns, together with their motion patterns when using a belt. The evidence suggests that these motor control changes can elevate the risk of injury should a belt not be worn in a belt-training athlete. The severity of a back injury may be greater if a belt is worn.

Many people adopt belts in training for one of three reasons:
  • They have observed others wearing them and have assumed that it will be a good idea for them to do so.
  • Their backs are becoming sore and they believe that a back belt will help.
  • They want to lift a few more pounds.
None of these reasons are consistent with the objective of good health. It would appear that if one must lift a few more pounds, wear a belt. If one wants to groove motor patterns to train for other athletic tasks that demand a stable torso, it is probably better not to wear one. Instead individuals are encouraged to train the core musculature and to perfect lifting technique.

Natures Belt - A brief review of the anatomy
The abdominal wall formed by the lateral obliques (external and internal) and transverse abdominis creates hoop forces around the abdomen (see figure 1). These hoop forces are the reason why the rectus abdominis has a beaded appearance the lateral tendons transmit the lateral forces from the oblique muscles forming a continuous hoop around the abdomen. Further the intermuscular tendons and rectus fascia prevent the fibers of rectus from being ripped apart laterally from these hoop stresses. Posteriorly, the obliques connect with the lumbodorsal fascia (LDF) completing the hoop, or belt. The resulting hoop stresses and stiffness assist with spine stability.

Training of this mechanism has been extensively discussed in McGill (2004).
Figure 1. The abdominal fascia anteriorly,
and the LDF posteriorly, are passive parts of
the abdominal hoop. The lateral active
musculature (transverse abdominis, external
and internal oblique) serves to tension the
hoop-forming natures back belt.
 
tim290280

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Scientific Studies
The scientific studies can be divided into clinical trials and those that examined biomechanical, psychophysical, and physiological changes from belt wearing.

Clinical Trials: Clinical trials have been conducted to examine the effectiveness of belts to reduce injury in workers who perform lifting tasks. These types of studies are difficult to conduct. For example, the Hawthorne effect is a concern, as it is difficult to present a true double-blind paradigm to participants since those who receive belts certainly know so. In addition, logistical constraints on duration, diversity in occupations, and sample size are problematic. However, the data reported in the better-executed clinical trials cannot support the practice of universal prescription of belts to all workers involved in industrial lifting to reduce the risk of low-back injury (for example, Reddell and colleagues, 1992, Mitchell and colleagues, 1994, Wassell and colleagues, 2000). Weak evidence suggests that those people already injured might benefit from belts with a reduced risk of injury recurrence. However, evidence does not appear to support uninjured workers wearing belts to reduce the risk of injury; in fact, the risk of injury seems to increase during the period following a trial of belt wearing. Finally, some evidence suggests that the cost of a back injury may be higher in workers who wear belts than in workers who do not.

Biomechanical Studies: Researchers who have studied the biomechanical issues of belt wearing have focused on spinal forces, intra-abdominal pressure (IAP), load, and range of motion. The most informative studies are reviewed in this section. Two studies in particular (Harman et al.,1989, and Lander et al., 1992) suggested that wearing a back belt can increase the margin of safety during repetitive lifting. Both of these papers reported ground reaction force and increased intra-abdominal pressure while subjects repeatedly lifted barbells. It was only assumed that intra-abdominal pressure is a good indicator of spinal forces. However, several studies have questioned the hypothesized link between elevated intra-abdominal pressure and reduction in low back load. For example, using an analytical model and data collected from three subjects lifting various magnitudes of loads, McGill and Norman (1987) noted that a buildup of intra-abdominal pressure required additional activation of the musculature in the abdominal wall. This activity resulted in a net increase in low back compressive load and not a net reduction of load, as researchers had previously thought. In addition, Nachemson and colleagues (1986) published some experimental results that directly measured intradiscal pressure during the performance of Valsalva maneuvers, documenting that an increase in intra-abdominal pressure increased, not decreased, the low back compressive load. Therefore, the conclusion that an increase in intra-abdominal pressure due to belt wearing reduces compressive load on the spine seems erroneous. In fact, such an increase may have no effect or may even increase the load on the spine.

Several studies have put to rest the belief that IAP affects low back extensor activity. Our own study (McGill and colleagues, 1990) suggested that there was no change in activation levels of the low back extensors nor in any of the abdominal muscles (rectus abdominis or obliques). Both Reyna and colleagues (1995) and Ciriello and Snook (1995) found belts provided no enhancement of function in terms of alleviating the loading of back extensor muscles or fatigue, but these trials were not conducted over a very long period of time.

Both Lantz and Schultz (1986) and McGill and colleagues (1994) observed the range of lumbar motions in subjects wearing low back orthoses and belts, respectively. Generally, the stiffness of the torso was significantly increased about the lateral bend and axial twist axes when belt wearing but not when subjects were rotated into full flexion. A data set presented by Granata and colleagues (1997) supports the notion that some belt styles are better in stiffening the torso in the manner described previously—namely, the taller elastic belts that span the pelvis to the rib cage. Furthermore, these authors also documented that a rigid orthopedic belt generally increased the lifting moment, while the elastic belt generally reduced spinal load. Even in well controlled studies, belts appear to modulate lifting mechanics in some positive ways in some people and in negative ways in others.

Studies of Belts, Heart Rate, and Blood Pressure: Hunter and colleagues (1989) monitored the blood pressure and heart rate of five males and one female performing dead lifts and one-arm bench presses and riding bicycles while wearing and not wearing a 10-cm (4-in.) weight belt. During the lifting exercise, blood pressure (up to 15 mmHg) and heart rate were both significantly higher in subjects wearing belts. Given the relationship between elevated systolic blood pressure and an increased risk of stroke, Hunter and colleagues (1989) concluded that individuals who may have cardiovascular system compromise are probably at greater risk when undertaking exercise while wearing back belts than when not wearing them. Our own work (Rafacz and McGill, 1996) supports these conclusions. Anecdotally, belts and associated pressures may possibly be linked with higher incidents of varicose veins in the testicles, hemorrhoids, and hernias. As of this writing, there has been no scientific and systematic investigation of the validity of these suggestions. It may be prudent to simply state concern and test these ideas in the future.

Psychophysical Studies: Some scientists and coaches have expressed concern that wearing belts fosters an increased sense of security that may, or may, not be warranted. Studies based on the psychophysical paradigm allow subjects to select weights that they can lift repeatedly using their own subjective perceptions of physical exertion. For example McCoy and colleagues (1988) found that subjects were willing to lift by approximately 19% when wearing a belt. This evidence may lend some support to the theory that belts give people a false sense of security.

A Look to the future
Training for high performance usually requires high speed movement. Also critical for ultimate performance is timed and coordinated stiffness and joint stability. Consider the golf swing that epitomizes the contrast between controlled relaxed motion through the backswing and violent whole body stiffening at the instant of ball contact only to be followed by more relaxed follow through motion. The same contrast can be generalized for generating punching power and for the impressive “hit” in football, for example. The best athletes are able to generate motion but know when to stiffen with extremely rapid muscle activation together with rapid muscle relaxation. Techniques for training this skill involve selective plyometric exercise which is generally encumbered by wearing a belt. Thus, different considerations apply for speed training and belt usage is considered inappropriate.

Note: Adapted from the chapter on back belts by Stuart McGill in:
“Ultimate Back Fitness and Performance”, Wabuno publishers, 2004,
Canada. Available from www.backfitpro.com

References
Ciriello, V.M., and Snook, S.H. (1995) The effect of back belts on lumbar muscle
fatigue. Spine, 20 (11):1271-1278.
Granata, K.P., Marras, W.S., and Davis, K.G. (1997) Biomechanical assessment of
lifting dynamics, muscle activity and spinal loads while using three different style
lifting belts. Clin. Biomech, 12 (2): 107-115.
Harman, E.A., Rosenstein, R.M., Frykman, P.N., and Nigro, G.A. (1989) Effects of a
belt on intra-abdominal pressure during weight lifting. Med. Sci. Sports Exercise, 2
(12): 186-190.
Hunter, G.R., McGuirk, J., Mitrano, N., Pearman, P., Thomas, B., and Arrington, R.
(1989) The effects of a weight training belt on blood pressure during exercise. J.
Appl. Sport Sci. Res., 3 (1):13-18.
Lander, J.E., Hundley, J.R., and Simonton, R.L. (1992) The effectiveness of weight belts
during multiple repetitions of the squat exercise. Med. Sci. Sports Exercise, 24 (5):
603-609.
Lantz, S.A., and Schultz, A.B. (1986) Lumbar spine orthosis wearing. I. Restriction of
gross body motion. Spine, 11 (8): 834-837.
McCoy, M.A., Congleton, J.J., Johnston, W.L., and Jiang, B.C. (1988) The role of
lifting belts in manual lifting. Int. J. Ind. Ergonomics, 2: 259-266.
McGill, S.M. (1993) Abdominal belts in industry: A position paper on their assets,
liabilities and use. Am.Ind.Hyg.Assoc.J., 54 (12): 752-754.
McGill, S.M., and Norman, R.W. (1987) Reassessment of the role of intra-abdominal
pressure in spinal compression. Ergonomics, 30 (11): 1565-1588.
McGill, S., Norman, R.W., and Sharratt, M.T. (1990) The effect of an abdominal belt
on trunk muscle activity and intra-abdominal pressure during squat lifts.
Ergonomics, 33 (2): 147-160.
McGill, S.M., Seguin, J.P., and Bennett, G. (1994) Passive stiffness of the lumbar torso
in flexion, extension, lateral bend and axial twist: The effect of belt wearing and
breath holding. Spine, 19 (6): 696-704.
McGill, S.M. Invited Paper. (1999) Should industrial workers wear abdominal belts:
guidelines based on the recent literature. Int. J. Industrial Ergonomics 23(5-6):
633-636.
McGill, S.M. Medical Management: Back Belts. In: Occupational Ergonomics
Handbook (second edition), CRC Press, 2004.
McGill, S.M., Ultimate back fitness and performance, Wabuno Publishers, Waterloo,
2004 (available from www.backfitpro.com).
Mitchell, L.V., Lawler, F.H., Bowen, D., Mote, W., Asundi, P., and Purswell, J. (1994)
Effectiveness and cost-effectiveness of employer-issued back belts in areas of high
risk for back injury. J. Occup. Med., 36 (1): 90-94.
Nachemson, A.L., Andersson, G.B.J., and Schultz, A.B. (1986) Valsalva maneuver
biomechanics. Effects on lumbar trunk loads of elevated intra-abdominal
pressures. Spine, 11 (5): 476-479.
National Institute for Occupational Safety and Health (NIOSH) (1994, July) Workplace
use of back belts. U.S. Department of Health and Human Services, Centers for
Disease Control and Prevention.
Rafacz, W., and McGill, S.M. (1996) Abdominal belts increase diastolic blood pressure.
J. Occup. Environ. Med., 38 (9): 925-927.
Reddell, C.R., Congleton, J.J., Huchinson R.D., and Montgomery J.F. (1992) An
evaluation of a weightlifting belt and back injury prevention training class for
airline baggage handlers. Appl. Ergonomics, 23 (5): 319-329.
Reyna, J.R., Leggett, S.H., Kenney, K., Holmes, B., and Mooney, V. (1995) The effect
of lumbar belts on isolated lumbar muscle. Spine, 20 (1): 68-73.
Wassell, J.T., Gardner, L.I., Landsittel, D.P., Johnston, J.J., and Johnston, J.M. (2000)
A prospective study of back belts for prevention of back pain and injury. J. Am.
Med. Assn., 284 (21): 2727-2734.
 
smcfay

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so....i didnt read all of it but are belts good or bad?
 
tim290280

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^^ So I should bother answering that question :dunnodude:

Read the article. I didn't post it for my health I posted it for yours.


Long story short: belts are only for 1-2rep max attempts.
 
Natzo

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Thanks for the info there Tim.

Having you on this forum really makes the difference.

Before I read this post I had started to leave my belt at home most of the times.

I only use it now for deads last set wich is like 4-5 reps. It makes me more comfortable. I think the belt in the other exercises made my mechanics, my form a little "stiff" somehow "rusty" it didn't felt right (Am I making sense?). Now I noticed my mechanic flow and exercise form is much improved and I'm able to lift more, plus my core is much stronger!

With this piece of information I see my assumptions comfirmed!

thanks.


(repped)
 
tim290280

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^^ Yeh I had a similar awakening.

I used to squat at a gym that had belts available for use. Then I got some weights and started lifting at home on the holidays. Didn't buy a belt and noticed a big change. Suddenly I couldn't have the forward lean, suddenly I had to get myself better braced and positioned.

From then on I have barely touched a belt. Still took me a long time to get decent squat form. But it wasn't until much later that I found out that there was a fair bit of research suggesting that belts were really only for competitive strength athletes.

Of course I also have objections to lifting aids in general. Growing up on a farm you don't get given a belt or wraps or straps or anything else to lift strainer posts, hay bales and other heavy stuff. So I've always thought "what is so special" about the gym. These things have their place, but most are using them under false assumptions or as a crutch.
 
tim290280

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Some other research that has been done on spines and belts. Belts aren't bad, but as you see the bracing and breathing are just as important.
J. Cholewicki, Krishna Juluru, Andrea Radebold, Manohar M. Panjabi and Stuart M. McGill

Abstract The increased intra-abdominal pressure (IAP) commonly observed when the spine is loaded during physical activities is hypothsized to increase lumbar spine stability.The mechanical stability of the lumbar spine is an important consideration in low back injury prevention and rehabilitation strategies. This study examined the effects of raised IAP and an abdominal belt on lumbar spine stability. Two hypotheses were tested: (1) An increase in IAP leads to increased lumbar spine stability, (2) Wearing an abdominal belt increases spine stability. Ten volunteers were placed in a semi-seated position in a jig that restricted hip motion leaving the upper torso free to move in any direction. The determination of lumbar spine stability was accomplished by measuring the instantaneous trunk stiffness in response to a sudden load release. The quick release method was applied in isometric trunk flexion, extension, and lateral bending. Activity of 12 major trunk muscles was monitored with electromyography and the IAP was measured with an intra-gastric pressure transducer. A two-factor repeated measures design was used (P < 0.05), in which the spine stability was evaluated under combinations of the following two factors: belt or no belt and three levels of IAP (0, 40, and 80% of maximum). The belt and raised IAP increased trunk stiffness in all directions, but the results in extension lacked statistical significance. In flexion, trunk stiffness increased by 21% and 42% due to 40% and 80% IAP levels respectively; in lateral bending, trunk stiffness increased by 16% and 30%. The belt added between 9% and 57% to the trunk stiffness depending on the IAP level and the direction of exertion. In all three directions, the EMG activity of all 12 trunk muscles increased significantly due to the elevated IAP. The belt had no effect on the activity of any of the muscles with the exception of the thoracic erector spinae in extension and the lumbar erector spinae in flexion, whose activities decreased. The results indicate that both wearing an abdominal belt and raised IAP can each independently, or in combination, increase lumbar spine stability. However, the benefits of the belt must be interpreted with caution in the context of the decreased activation of a few trunk extensor muscles.
The Journal of Strength and Conditioning Research
Volume 13, Issue 4 (November 1999)

The Use of Lumbar-Supporting Weight Belts While Performing Squats: Erector Spinae Electromyographic Activity
JEFFREY A. BAUER, ANDREW FRY, and CORY CARTER

This study sought to analyze the effects of subjects' wearing weightlifting lumbar support belts on surface electromyographic recordings of the erector spinae muscle group while the subject executed parallel squats. Ten healthy college-age men with weightlifting experience participated in this study. Participants completed a total of 6 repetitions of high-bar parallel back-squats at loads equaling 60% of their 1 repetition maximum. Experimental conditions required subjects to perform 6 squats, 3 while wearing a belt and 3 without. Electromyographic electrodes recorded muscle activity at 800 Hz on both the right and left erector spinae at the lumbar (L3-L5) and thoracic (T5-T7) regions during all lifts. The results indicate that subjects' mean erector spinae activity was greater (p < 0.0125) in the lumbar region of the spine when wearing weight belts (258 SD; 69.0 analog-to-digital units) during squatting exercises than the mean activity in subjects who were not wearing weight belts (235 SD; 71.3 analog-to-digital units).
Spine:
Volume 31 - Issue 22
Biomechanics
Effect of a Stiff Lifting Belt on Spine Compression During Lifting
Kingma, Idsart; Faber, Gert S.; Suwarganda, Edin K.; Bruijnen, Tom B. M.; Peters, Rob J. A.; van Dien, Jaap H.

Abstract
Study Design. An in vivo study on weightlifters.

Objectives. To determine if and how a stiff back belt affects spinal compression forces in weightlifting.

Summary of Background Data. In weightlifting, a back belt has been reported to enhance intraabdominal pressure (IAP) and to reduce back muscle EMG and spinal compression forces.

Methods. Nine experienced weightlifters lifted barbells up to 75% body weight while inhaling and wearing a belt, inhaling and not wearing a belt, and exhaling and wearing a belt. IAP, trunk muscle EMG, ground reaction forces, and kinematics were measured. An EMG-assisted trunk model, including IAP effects, was used to calculate spinal compression and shear forces and to reveal the contribution of back muscles, abdominal muscles, and IAP to moment generation.

Results. The belt reduced compression forces by about 10%, but only when inhaling before lifting. The moment generated by IAP increased when wearing a belt and inhaling, but this moment was small and the increase was largely negated by the flexing moment generated by abdominal muscles.

Conclusions. Wearing a tight and stiff back belt while inhaling before lifting reduces spine loading. This is caused by a moment generated by the belt rather than by the IAP.
Three-dimensional Motion Analysis of the Lumbar Spine During Free Squat Weight Lift Training
James C. Walsh, MB, MRCSI, John F. Quinlan, MCh, AFRCSI, Robert Stapleton, PhD, David P. FitzPatrick, BAI, DPhil(Oxon), and Damian McCormack, MCh, FRCS (Orth)

Abstract
Background: Heavy weight lifting using a squat bar is a commonly used athletic training exercise. Previous in vivo motion studies have concentrated on lifting of everyday objects and not on the vastly increased loads that athletes subject themselves to when performing this exercise.

Hypothesis: Athletes significantly alter their lumbar spinal motion when performing squat lifting at heavy weights.

Study Design:
Controlled laboratory study.

Methods: Forty-eight athletes (28 men, 20 women) performed 6 lifts at 40% maximum, 4 lifts at 60% maximum, and 2 lifts at 80% maximum. The Zebris 3D motion analysis system was used to measure lumbar spine motion. Exercise was performed as a ?free? squat and repeated with a weight lifting support belt. Data obtained were analyzed using SAS.

Results: A significant decrease (P < .05) was seen in flexion in all groups studied when lifting at 40% maximum compared with lifting at 60% and 80% of maximum lift. Flexion from calibrated 0 point ranged from 24.7 ? (40% group) to 6.8 ? (80% group). A significant increase (P < .05) was seen in extension when lifting at 40% maximum was compared with lifting at 60% and 80% maximum lift. Extension from calibrated 0 point ranged from −1.5 ? (40% group) to −20.3 ? (80% group). No statistically significant difference was found between motion seen when exercise was performed as a free squat or when lifting using a support belt in any of the groups studied.

Conclusion:
Weight lifting using a squat bar causes athletes to significantly hyperextend their lumbar spines at heavier weights. The use of a weight lifting support belt does not significantly alter spinal motion during lifting.
 
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^^ So I should bother answering that question :dunnodude:

Read the article. I didn't post it for my health I posted it for yours.


Long story short: belts are only for 1-2rep max attempts.

That is what I like. Short and sweet! Thanx.
 
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I am almost certain a belt helped contribute to my hernia. I got the hernia exactly where my belts puts all the additional pressure, but that is j speculation.
 
tim290280

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^^ Speculation is what most sites thrive on Ben :xyxthumbs:

I was chatting with a powerlifter yesterday and his back is done. He'll never lift again, has a degerated spine in his early 30's, and he blamed the belt and squats.
 

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Good postings dude. Reppage coming your way.

My 2c: I generally only use belts for my maximum ME work but will occasionally add it when I am doing high volume work (eg. 10 sets) for relief or as extra support when I am already experiencing back pain or discomfort either from injury or high volume work.

As a rule I generally only use my belt to brace against providing me with increased intra-abdominal pressure. I use a competition grade powerlifting belt like this which is the same width all the way around.
ABTL01-1.jpg

Normal weight belts which are less wide in the front are less efficient for this purpose unless worn backwards.
 
El Freako

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Apparently I rep you too much...

You must spread some Reputation around before giving it to tim290280 again.
 
tim290280

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^^ Stop reminding me how much better your squat is :no:


Lulz
 
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I dropped belt couple of months ago.I havent use it even once.Had to drop little weights on certain exercises naturally ,but im very close now what i use to lift with belt.My core is much stronger now and all the back pain and discomfort is gone.
Thanks to Tim:thumbsup2:
 
Natzo

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I dropped belt couple of months ago.I havent use it even once.Had to drop little weights on certain exercises naturally ,but im very close now what i use to lift with belt.My core is much stronger now and all the back pain and discomfort is gone.
Thanks to Tim:thumbsup2:

I know what you're saying. when I used a belt I had some discomfort in the lombar area. that seems to be going away now that I'm not using it.
 
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I'm going to go out on a limb here and suggest that a lot of people use belts wrong. They buy the generic weightlifting belt (wide at the back, thin at the front) and then they do it up so tight that they can barely breath. This provides increased intra-muscular pressure through compression of your torso but inevitably breeds weakness through neglect of the stabilising muscles. In powerlifting however, the belt is not done up so tight and is used to brace your abs against creating torso stability through intra-muscular pressure once again but requiring the athlete to use his own strength to do so. Herein greater pressure can be produced than can through compression and the stabilising muscles are being used, trained and strengthened in the process.

People need to learn to use their belts rather than rely on them. And I would also like to clarify that as a rule belts should only be used in maximal lifts.
 
tim290280

tim290280

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^^ Yes that is another point. The science that shows their usefulness has been conducted on guys that are experienced lifters and understand how to use a belt. The paper that quoted the benefit of the belt to strength was conducted on elite level powerlifters.

I think the average gym warrior both overuses, and creates a crutch with a belt (and just about every other training aid). And I'll go out on a flaming limb here and say that most people here probably don't need to use training aids in the manner they use them.
 
El Freako

El Freako

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And I'll go out on a flaming limb here and say that most people here probably don't need to use training aids in the manner they use them.

But I can't lift anything without my gloves/belt/straps/wraps/headband/compression top/cockring/portable HGH IV drip.:bitenails:
 
Natzo

Natzo

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But I can't lift anything without my gloves/belt/straps/wraps/headband/compression top/cockring/portable HGH IV drip.:bitenails:

:rofl3::rofl3:

no kidding.. I know a guy just like that..and he's afraid to squat!
 
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