Jump to content

Strength training

From Wikipedia, the free encyclopedia
(Redirected from Resistance training)

A gym environment where various forms of strength training are being practiced. Identified from left to right, the exercises are: overhead presses, battle ropes, planking, and kettlebell raises.

Strength training, also known as weight training or resistance training, involves the performance of physical exercises that are designed to improve physical strength. It is often associated with the lifting of weights. It can also incorporate a variety of training techniques such as bodyweight exercises, isometrics, and plyometrics.[1]

Training works by progressively increasing the force output of the muscles and uses a variety of exercises and types of equipment. Strength training is primarily an anaerobic activity, although circuit training also is a form of aerobic exercise.

Strength training can increase muscle, tendon, and ligament strength as well as bone density, metabolism, and the lactate threshold; improve joint and cardiac function; and reduce the risk of injury in athletes and the elderly. For many sports and physical activities, strength training is central or is used as part of their training regimen.

Principles and training methods

[edit]

Strength training follows the fundamental principle that involves repeatedly overloading a muscle group. This is typically done by contracting the muscles against heavy resistance and then returning to the starting position. This process is repeated for several repetitions until the muscles reach the point of failure.[2] The basic method of resistance training uses the principle of progressive overload, in which the muscles are overloaded by working against as high resistance as they are capable of. They respond by growing larger and stronger.[3] Beginning strength-trainers are in the process of training the neurological aspects of strength, the ability of the brain to generate a rate of neuronal action potentials that will produce a muscular contraction that is close to the maximum of the muscle's potential.[4][better source needed]</ref>[better source needed]

Proper form

[edit]
A dumbbell half-squat.[5]

Strength training also requires the use of proper or 'good form', performing the movements with the appropriate muscle group, and not transferring the weight to different body parts in order to move greater weight (called 'cheating'). An injury or an inability to reach training objectives might arise from poor form during a training set. If the desired muscle group is not challenged sufficiently, the threshold of overload is never reached and the muscle does not gain in strength. At a particularly advanced level, however, "cheating" can be used to break through strength plateaus and encourage neurological and muscular adaptation.[6]

Maintaining proper form is one of the many steps in order to perfectly perform a certain technique. Correct form in weight training improves strength, muscle tone, and maintaining a healthy weight. Improper form can lead to strains and fractures.[7]

Stretching and warm-up

[edit]

Weight trainers often spend time warming up before starting a workout, a practice strongly recommended by the National Strength and Conditioning Association (NSCA). A warm-up may include cardiovascular activity such as light stationary biking (a "pulse raiser"), flexibility and joint mobility exercises, static and/or dynamic stretching, "passive warm up" such as applying heat pads or taking a hot shower, and workout-specific warm up,[8] such as rehearsal of the intended exercise with no weights or light weights. The intended purpose of warming up is to enhance exercise effectiveness and reduce the risk of injury.[9]

Evidence is limited regarding whether warming up reduces injuries during strength training.[9] As of 2015, no articles existed on the effects of warm up for upper body injury prevention.[10] For the lower limbs, several programs significantly reduce injuries in sports and military training, but no universal injury prevention program has emerged, and it is unclear if warm ups designed for these areas will also be applicable to strength training.[11] Static stretching can increase the risk of injury due to its analgesic effect and cellular damage caused by it.[12]

The effects of warming up on exercise effectiveness are clearer. For 1RM trials, an exercise rehearsal has significant benefits. For submaximal strength training (3 sets of 80% of 1RM to failure), exercise rehearsal does not provide any benefits regarding fatigue or total repetitions for exercises such as bench press, squats, and arm curl, compared to no warm-up.[9] Dynamic warm-ups (performed with greater than 20% of maximal effort) enhance strength and power in upper-body exercises.[10] When properly warmed up the lifter will have more strength and stamina since the blood has begun to flow to the muscle groups.[13] Pulse raisers do not have any effect on either 1RM or submaximal training.[9] Static stretching induces strength loss, and should therefore probably not be performed before strength training. Resistance training functions as an active form of flexibility training, with similar increases in range of motion when compared to performing a static stretching protocol. Static stretching, performed either before or after exercise, also does not reduce muscle soreness in healthy adults.[9]

Breathing

[edit]

In weight training, as with most forms of exercise, there is a tendency for the breathing pattern to deepen. This helps to meet increased oxygen requirements. One approach to breathing during weight training consists of avoiding holding one's breath and breathing shallowly. The benefits of this include protecting against a lack of oxygen, passing out, and increased blood pressure. The general procedure of this method is to inhale when lowering the weight (the eccentric portion) and exhale when lifting the weight (the concentric portion). However, the reverse, inhaling when lifting and exhaling when lowering, may also be recommended. There is little difference between the two techniques in terms of their influence on heart rate and blood pressure.[14]

On the other hand, for people working with extremely heavy loads (such as powerlifters), breathing à la the Valsalva maneuver is often used. This involves deeply inhaling and then bracing down with the abdominal and lower back muscles as the air is held in during the entire rep. Air is then expelled once the rep is done, or after a number of reps is done. The Valsalva maneuver leads to an increase in intrathoracic and intra-abdominal pressure. This enhances the structural integrity of the torso—protecting against excessive spinal flexion or extension and providing a secure base to lift heavy weights effectively and securely.[15] However, as the Valsalva maneuver increases blood pressure, lowers heart rate, and restricts breathing, it can be a dangerous method for those with hypertension or for those who faint easily.

Training volume

[edit]

Training volume is commonly defined as sets × reps × load. That is, an individual moves a certain load for some number of repetitions, rests, and repeats this for some number of sets, and the volume is the product of these numbers. For non-weightlifting exercises, the load may be replaced with intensity, the amount of work required to achieve the activity. Training volume is one of the most critical variables in the effectiveness of strength training. There is a positive relationship between volume and hypertrophy.[16][17]

The load or intensity is often normalized as the percentage of an individual's one-repetition maximum (1RM). Due to muscle failure, the intensity limits the maximum number of repetitions that can be carried out in one set, and is correlated with the repetition ranges chosen. Depending on the goal, different loads and repetition amounts may be appropriate:[18]

  • Strength development (1RM performance): Gains may be achieved with a variety of loads. However, training efficiency is maximized by using heavy loads (80% to 100% of 1RM). The number of repetitions is secondary and may be 1 to 5 repetitions per set.[18]
  • Muscle growth (hypertrophy): Hypertrophy can be maximized by taking sets to failure or close to failure. Any load 30% of 1RM or greater may be used. The NCSA recommends "medium" loads of 8 to 12 repetitions per set with 60% to 80% of 1RM.[18]
  • Endurance: Endurance may be trained by performing many repetitions, such as 15 or more per set. The NCSA recommends "light" loads below 60% of 1RM, but some studies have found conflicting results suggesting that "moderate" 15-20RM loads may work better when performed to failure.[18]

Training to muscle failure is not necessary for increasing muscle strength and muscle mass, but it also is not harmful.[19]

Movement tempo

[edit]

The speed or pace at which each repetition is performed is also an important factor in strength and muscle gain. The emerging format for expressing this is as a 4-number tempo code such as 3/1/4/2, meaning an eccentric phase lasting 3 seconds, a pause of 1 second, a concentric phase of 4 seconds, and another pause of 2 seconds. The letter X in a tempo code represents a voluntary explosive action whereby the actual velocity and duration is not controlled and may be involuntarily extended as fatigue manifests, while the letter V implies volitional freedom "at your own pace". A phase's tempo may also be measured as the average movement velocity. Less precise but commonly used characterizations of tempo include the total time for the repetition or a qualitative characterization such as fast, moderate, or slow. The ACSM recommends a moderate or slower tempo of movement for novice- and intermediate-trained individuals, but a combination of slow, moderate, and fast tempos for advanced training.[20]

Intentionally slowing down the movement tempo of each repetition can increase muscle activation for a given number of repetitions. However, the maximum number of repetitions and the maximum possible load for a given number of repetitions decreases as the tempo is slowed. Some trainers calculate training volume using the time under tension (TUT), namely the time of each rep times the number of reps, rather than simply the number of reps.[20] However, hypertrophy is similar for a fixed number of repetitions and each repetition's duration varying from 0.5 s - 8 s. There is however a marked decrease in hypertrophy for "very slow" durations greater than 10 s.[21] There are similar hypertrophic effects for 50-60% 1RM loads with a slower 3/0/3/0 tempo and 80-90% 1RM loads with a faster 1/1/1/0 tempo. It may be beneficial for both hypertrophy and strength to use fast, short concentric phases and slower, longer eccentric phases. Research has not yet isolated the effects of concentric and eccentric durations, or tested a wide variety of exercises and populations.[20]

Weekly frequency

[edit]

In general, more weekly training sessions lead to higher increases in physical strength. However, when training volume was equalized, training frequency had no influence on muscular strength. In addition, greater frequency had no significant effect on single-joint exercises. There may be a fatigue recovery effect in which spreading the same amount of training over multiple days boosts gains, but this has to be confirmed by future study.[22]

For muscle growth, a training frequency of two sessions per week had greater effects than once per week. Whether training a muscle group three times per week is superior to a twice-per-week protocol remains to be determined.[23]

Rest period

[edit]

The rest period is defined as the time dedicated to recovery between sets and exercises. Exercise causes metabolic stress, such as the buildup of lactic acid and the depletion of adenosine triphosphate and phosphocreatine.[24] Resting 3–5 minutes between sets allows for significantly greater repetitions in the next set versus resting 1–2 minutes.[25]

For untrained individuals (no previous resistance training experience), the effect of resting on muscular strength development is small and other factors such as volitional fatigue and discomfort, cardiac stress, and the time available for training may be more important. Moderate rest intervals (60-160s) are better than short (20-40 s), but long rest intervals (3–4 minutes) have no significant difference from moderate.[24]

For trained individuals, rest of 3–5 minutes[26] is sufficient to maximize strength gain, compared to shorter intervals 20s-60s and longer intervals of 5 minutes. Intervals of greater than 5 minutes have not been studied.[24] Starting at 2 minutes and progressively decreasing the rest interval over the course of a few weeks to 30s can produce similar strength gains to a constant 2 minutes.[27][24]

Regarding older individuals, a 1 minute rest is sufficient in females.[24]

Order

[edit]

The largest increases in strength happen for the exercises in the beginning of a session.[28]

Supersets are defined as a pair of different exercise sets performed without rest, followed by a normal rest period. Common superset configurations are two exercises for the same muscle group, agonist-antagonist muscles, or alternating upper and lower body muscle groups.[29] Exercises for the same muscle group (flat bench press followed by the incline bench press) result in a significantly lower training volume than a traditional exercise format with rests.[30] However, agonist–antagonist supersets result in a significantly higher training volume when compared to a traditional exercise format.[31] Similarly, holding training volume constant but performing upper–lower body supersets and tri-sets reduce elapsed time but increased perceived exertion rate.[32] These results suggest that specific exercise orders may allow more intense, more time-efficient workouts with results similar to longer workouts.[29]

Periodization

[edit]

Periodization refers to the organization of training into sequential phases and cyclical periods, and the change in training over time. The simplest strength training periodization involves keeping a fixed schedule of sets and reps (e.g. 2 sets of 12 reps of bicep curls every 2 days), and steadily increasing the intensity on a weekly basis. This is conceptually a parallel model, as several exercises are done each day and thus multiple muscles are developed simultaneously. It is also sometimes called linear periodization, but this designation is considered a misnomer.[33]

Sequential or block periodization concentrates training into periods ("blocks"). For example, for athletes, performance can be optimized for specific events based on the competition schedule. An annual training plan may be divided hierarchically into several levels, from training phases down to individual sessions. Traditional periodization can be viewed as repeating one weekly block over and over. Block periodization has the advantage of focusing on specific motor abilities and muscle groups.[33] Because only a few abilities are worked on at a time, the effects of fatigue are minimized. With careful goal selection and ordering, there may be synergistic effects. A traditional block consists of high-volume, low-intensity exercises, transitioning to low-volume, high-intensity exercises. However, to maximize progress to specific goals, individual programs may require different manipulations, such as decreasing the intensity and increasing volume.[34]

Undulating periodization is an extension of block periodization to frequent changes in volume and intensity, usually daily or weekly. Because of the rapid changes, it is theorized that there will be more stress on the neuromuscular system and better training effects. Undulating periodization yields better strength improvements on 1RM than non-periodized training.[33] For hypertrophy, it appears that daily undulating periodization has similar effect to more traditional models.[35]

Training splits

[edit]

A training split refers to how the trainee divides and schedules their training volume, or in other words which muscles are trained on a given day over a period of time (usually a week). Popular training splits include full body, upper/lower, push/pull/legs, and the "bro" split. Some training programs may alternate splits weekly.[36][better source needed]

Exercise selection

[edit]

Exercise selection depends on the goals of the strength training program. If a specific sport or activity is targeted, the focus will be on specific muscle groups used in that sport. Various exercises may target improvements in strength, speed, agility, or endurance.[37] For other populations such as older individuals, there is little information to guide exercise selection, but exercises can be selected on the basis of specific functional capabilities as well as the safety and efficiency of the exercises.[38]

For strength and power training in able-bodied individuals, the NCSA recommends emphasizing integrated or compound movements (multi-joint exercises), such as with free weights, over exercises isolating a muscle (single-joint exercises), such as with machines.[39] This is due to the fact that only the compound movements improve gross motor coordination and proprioceptive stabilizing mechanisms.[37] However, single-joint exercises can result in greater muscle growth in the targeted muscles,[40] and are more suitable for injury prevention and rehabilitation.[39] Low variation in exercise selection or targeted muscle groups, combined with a high volume of training, is likely to lead to overtraining and training maladaptation.[41] Many exercises such as the squat have several variations. Some studies have analyzed the differing muscle activation patterns, which can aid in exercise selection.[42]

Equipment

[edit]

Commonly used equipment for resistance training include free weights—including dumbbells, barbells, and kettlebellsweight machines, and resistance bands.[43]

Resistance can also be generated by inertia in flywheel training instead of by gravity from weights, facilitating variable resistance throughout the range of motion and eccentric overload.[44][45]

Some bodyweight exercises do not require any equipment, and others may be performed with equipment such as suspension trainers or pull-up bars.[46]

Types of strength training exercises

[edit]

Aerobic exercise versus anaerobic exercise

[edit]

Strength training exercise is primarily anaerobic.[47] Even while training at a lower intensity (training loads of ~20-RM), anaerobic glycolysis is still the major source of power, although aerobic metabolism makes a small contribution.[48] Weight training is commonly perceived as anaerobic exercise, because one of the more common goals is to increase strength by lifting heavy weights. Other goals such as rehabilitation, weight loss, body shaping, and bodybuilding often use lower weights, adding aerobic character to the exercise.

Except in the extremes, a muscle will fire fibres of both the aerobic or anaerobic types on any given exercise, in varying ratio depending on the load on the intensity of the contraction.[47] This is known as the energy system continuum. At higher loads, the muscle will recruit all muscle fibres possible, both anaerobic ("fast-twitch") and aerobic ("slow-twitch"), to generate the most force. However, at maximum load, the anaerobic processes contract so forcefully that the aerobic fibers are completely shut out, and all work is done by the anaerobic processes. Because the anaerobic muscle fibre uses its fuel faster than the blood and intracellular restorative cycles can resupply it, the maximum number of repetitions is limited.[49] In the aerobic regime, the blood and intracellular processes can maintain a supply of fuel and oxygen, and continual repetition of the motion will not cause the muscle to fail.

Circuit weight training is a form of exercise that uses a number of weight training exercise sets separated by short intervals. The cardiovascular effort to recover from each set serves a function similar to an aerobic exercise, but this is not the same as saying that a weight training set is itself an aerobic process.

Strength training is typically associated with the production of lactate, which is a limiting factor of exercise performance. Regular endurance exercise leads to adaptations in skeletal muscle which can prevent lactate levels from rising during strength training. This is mediated via activation of PGC-1alpha which alter the LDH (lactate dehydrogenase) isoenzyme complex composition and decreases the activity of the lactate generating enzyme LDHA, while increasing the activity of the lactate metabolizing enzyme LDHB.[50]

Nutrition and supplementation

[edit]

Supplementation of protein in the diet of healthy adults increases the size and strength of muscles during prolonged resistance exercise training (RET); protein intakes of greater than 1.62 grams per kilogram of body weight a day did not additionally increase fat–free mass (FFM), muscle size, or strength,[51] with the caveat that "Increasing age reduces… the efficacy of protein supplementation during RET."[51]

It is not known how much carbohydrate is necessary to maximize muscle hypertrophy. Strength adaptations may not be hindered by a low-carbohydrate diet.[52]

A light, balanced meal prior to the workout (usually one to two hours beforehand) ensures that adequate energy and amino acids are available for the intense bout of exercise. The type of nutrients consumed affects the response of the body, and nutrient timing whereby protein and carbohydrates are consumed prior to and after workout has a beneficial impact on muscle growth.[53] Water is consumed throughout the course of the workout to prevent poor performance due to dehydration. A protein shake is often consumed immediately[54] following the workout. However, the anabolic window is not particularly narrow and protein can also be consumed before or hours after the exercise with similar effects.[55] Glucose (or another simple sugar) is often consumed as well since this quickly replenishes any glycogen lost during the exercise period. If consuming recovery drink after a workout, to maximize muscle protein anabolism, it is suggested that the recovery drink contain glucose (dextrose), protein (usually whey) hydrolysate containing mainly dipeptides and tripeptides, and leucine.[56]

Some weight trainers also take ergogenic aids such as creatine[57] or anabolic steroids to aid muscle growth.[58] In a meta-analysis study that investigated the effects of creatine supplementation on repeated sprint ability, it was discovered that creatine increased body mass and mean power output.[59] The creatine-induced increase in body mass was a result of fluid retention.[59] The increase in mean power output was attributed to creatine's ability to counteract the lack of intramuscular phosphocreatine.[59] Creatine does not have an effect on fatigue or maximum power output.[59]

Hydration

[edit]

As with other sports, weight trainers should avoid dehydration throughout the workout by drinking sufficient water. This is particularly true in hot environments, or for those older than 65.[60][61][62][63][64]

Some athletic trainers advise athletes to drink about 7 imperial fluid ounces (200 mL) every 15 minutes while exercising, and about 80 imperial fluid ounces (2.3 L) throughout the day.[65]: 75 

However, a much more accurate determination of how much fluid is necessary can be made by performing appropriate weight measurements before and after a typical exercise session, to determine how much fluid is lost during the workout. The greatest source of fluid loss during exercise is through perspiration, but as long as fluid intake is roughly equivalent to the rate of perspiration, hydration levels will be maintained.[62]

Under most circumstances, sports drinks do not offer a physiological benefit over water during weight training.[65]: 76 

Insufficient hydration may cause lethargy, soreness or muscle cramps.[65]: 153  The urine of well-hydrated persons should be nearly colorless, while an intense yellow color is normally a sign of insufficient hydration.[65]: 153 

Effects

[edit]

The effects of strength training include greater muscular strength, improved muscle tone and appearance, increased endurance, cardiovascular health, and enhanced bone density.[66]

Bones, joints, frailty, posture and in people at risk

[edit]

Strength training also provides functional benefits. Stronger muscles improve posture,[vague] provide better support for joints,[vague] and reduce the risk of injury from everyday activities.[67][68]

Progressive resistance training may improve function, quality of life and reduce pain in people at risk of fracture, with rare adverse effects.[69] Weight-bearing exercise also helps to prevent osteoporosis and to improve bone strength in those with osteoporosis.[70] For many people in rehabilitation or with an acquired disability, such as following stroke or orthopaedic surgery, strength training for weak muscles is a key factor to optimise recovery.[71] Consistent exercise can actually strengthen bones and prevent them from getting frail with age. [72]

Mortality, longevity, muscle and body composition

[edit]

Strength training appears to be associated with a "10–17% lower risk of all-cause mortality, cardiovascular disease (CVD), total cancer, diabetes and lung cancer".[73] Two key outcomes of strength training are muscle hypertrophy and muscular strength gain which are associated with reduced all-cause mortality.[74]

Strength training causes endocrine responses that could have positive effects.[75] It also reduces blood pressure (SBP and DBP)[76][77] and alters body composition, reducing body fat percentage, body fat mass and visceral fat,[78] which is usually beneficial as obesity predisposes towards several chronic diseases and e.g. body fat distribution is one predictor of insulin resistance and related complications.[79]

Neurobiological effects

[edit]

Strength training also leads to various beneficial neurobiological effects – likely including functional brain changes, lower white matter atrophy,[80] neuroplasticity[81] (including some degree of BDNF expression),[82] and white matter-related structural and functional changes in neuroanatomy.[83] Although resistance training has been less studied for its effect on depression than aerobic exercise, it has shown benefits compared to no intervention.[84]

Lipid and inflammatory outcomes

[edit]

Moreover, it also promotes decreases in total cholesterol (TC), triglycerides (TG), low-density lipoprotein (LDL), and C-reactive protein (CRP) as well as increases in high-density lipoprotein (HDL) and adiponectin concentrations.[85]

Sports performance

[edit]

Stronger muscles improve performance in a variety of sports. Sport-specific training routines are used by many competitors. These often specify that the speed of muscle contraction during weight training should be the same as that of the particular sport.[86] Strength training can substantially prevent sports injuries,[87] increase jump height and improve change of direction.

Neuromuscular Adaptations

[edit]

Strength training is not only associated with an increase in muscle mass, but also an improvement in the nervous system's ability to recruit muscle fibers and activate them at a faster rate.[88] Neural adaptations can occur in the motor cortex, the spinal cord, and/or neuromuscular junctions. The initial significant improvements in strength amongst new lifters are a result of increased neural drive, motor unit synchronization, motor unit excitability, rate of force development, muscle fiber conduction velocity, and motor unit discharge rate.[88] Together, these improvements provide an increase in strength separate from muscle hypertrophy. Typically, the main barbell lifts (squat, bench, and deadlift) are performed with a full range of motion, which provides the greatest neuromuscular improvements compared to one-third or two-thirds range of motion.[89] However, there are reasons to perform these lifts with less range of motion, particularly in the powerlifting community. By limiting range of motion, lifters can target a specific joint angle in order to improve their sticking points by training their neural drive. Neuromuscular adaptations are critical for the development of strength, but are especially important in the aging adult population, as the decline in neuromuscular function is roughly three times as great (~3% per year) as the loss of muscle mass (~1% per year).[90] By staying active and following a resistance training program, older adults can maintain their movement, stability, balance, and independence.

History

[edit]
Arthur Saxon performing a Two Hands Anyhow with an early kettlebell and plate-loaded barbell

The genealogy of lifting can be traced back to the beginning of recorded history[91] where humanity's fascination with physical abilities can be found among numerous ancient writings. In many prehistoric tribes, they would have a big rock they would try to lift, and the first one to lift it would inscribe their name into the stone. Such rocks have been found in Greek and Scottish castles.[92] Progressive resistance training dates back at least to Ancient Greece, when legend has it that wrestler Milo of Croton trained by carrying a newborn calf on his back every day until it was fully grown. Another Greek, the physician Galen, described strength training exercises using the halteres (an early form of dumbbell) in the 2nd century.

Ancient Greek sculptures also depict lifting feats. The weights were generally stones, but later gave way to dumbbells. The dumbbell was joined by the barbell in the later half of the 19th century. Early barbells had hollow globes that could be filled with sand or lead shot, but by the end of the century these were replaced by the plate-loading barbell commonly used today.[93]

Weightlifting was first introduced in the Olympics in the 1896 Athens Olympic Games as a part of track and field, and was officially recognized as its own event in 1914.[94]

The 1960s saw the gradual introduction of exercise machines into the still-rare strength training gyms of the time. Weight training became increasingly popular in the 1970s, following the release of the bodybuilding movie Pumping Iron, and the subsequent popularity of Arnold Schwarzenegger. Since the late 1990s, increasing numbers of women have taken up weight training; currently, nearly one in five U.S. women engage in weight training on a regular basis.[95]

Subpopulations

[edit]

Sex differences

[edit]

Men and women have similar reactions to resistance training with comparable effect sizes for hypertrophy and lower body strength, although some studies have found that women experience a greater relative increase in upper-body strength. Because of their greater starting strength and muscle mass, absolute gains are higher in men.[96] In older adults, women experienced a larger increase in lower-body strength.[97]

[edit]

Orthopaedic specialists used to recommend that children avoid weight training because the growth plates on their bones might be at risk. The very rare reports of growth plate fractures in children who trained with weights occurred as a result of inadequate supervision, improper form or excess weight, and there have been no reports of injuries to growth plates in youth training programs that followed established guidelines.[98][99] The position of the National Strength and Conditioning Association is that strength training is safe for children if properly designed and supervised.[100] The effects of training on youth have been shown to depend on the methods of training being implemented. Studies from the Journal of Strength and Conditioning Research concluded that both Resistance Training and Plyometric training led to significant improvements in peak torque, peak rate of torque development, and jump performance, with Plyometric showing a greater improvement in jump performance compared to Resistance training. [101]Another study saw results that suggest that both high-load, low-repetition and moderate-load, high-repetition resistance training can be prescribed to improve muscular fitness in untrained adolescents, as well as the jump height had also increased. [102] [103] These finding can be used in the future to develop training programs for youth athletes.[101] The big takeaway from these studies is that not only in training important for the development of strength for young athletes, but also it shows that when developing a program, having both plyometrics exercise and resistance training will result in better adaptations in the short and long term.[101] This can be attributed to the effect of neuromuscular development and the principle that it comes faster for adolescents than muscular hypertrophy. Understanding this is crucial for those in charge of creating programs for the youth to avoid injury and/or overtraining.[102][103] Since adolescents are still in growing and are not done with developing not only musculature but also bone and joint structures. Younger children are at greater risk of injury than adults if they drop a weight on themselves or perform an exercise incorrectly; further, they may lack understanding of, or ignore the safety precautions around weight training equipment. As a result, supervision of minors is considered vital to ensuring the safety of any youth engaging in strength training.[98][99]

Older adults

[edit]

Aging is associated with sarcopenia, a decrease in muscle mass and strength.[104][105][106] Resistance training can mitigate this effect,[104][106][107] and even the oldest old (those above age 85) can increase their muscle mass with a resistance training program, although to a lesser degree than younger individuals.[104] With more strength older adults have better health, better quality of life, better physical function[106] and fewer falls.[106] Resistance training can improve physical functioning in older people, including the performance of activities of daily living.[106][104] Resistance training programs are safe for older adults, can be adapted for mobility and disability limitations, and may be used in assisted living settings.[104] Resistance training at lower intensities such as 45% of 1RM can still result in increased muscular strength.[108]

See also

[edit]

References

[edit]
  1. ^ "Strength Training". FitnessHealth101. Retrieved 19 March 2020.
  2. ^ Schoenfeld BJ, Grgic J, Ogborn D, Krieger JW (December 2017). "Strength and Hypertrophy Adaptations Between Low- vs. High-Load Resistance Training: A Systematic Review and Meta-analysis". Journal of Strength and Conditioning Research. 31 (12): 3508–23. doi:10.1519/JSC.0000000000002200. PMID 28834797. S2CID 24994953.
  3. ^ Brooks GA, Fahey TD, White TP (1996). Exercise Physiology: Human Bioenergetics and Its Applications. Mayfield Publishing Co. ISBN 978-0-07-255642-1.
  4. ^ Jenkins ND, Miramonti AA, Hill EC, Smith CM, Cochrane-Snyman KC, Housh TJ, Cramer JT (2017). "Greater Neural Adaptations following High- vs. Low-Load Resistance Training". Frontiers in Physiology. 8: 331. doi:10.3389/fphys.2017.00331. PMC 5447067. PMID 28611677. Lay summary in: "Why strength depends on more than muscle: Neural adaptations could account for differing strength gains despite similar muscle mass". ScienceDaily. 10 July 2017.
  5. ^ In the first picture, the knees are too close and get twisted. For appropriate muscular development and safety the knee should be in line with the foot. Rippetoe M, Lon Kilgore (2005). "Knees". Starting Strength. The Aasgard Company. pp. 46–49. ISBN 978-0-9768054-0-3.
  6. ^ Hughes, David C.; Ellefsen, Stian; Baar, Keith (June 2018). "Adaptations to Endurance and Strength Training". Cold Spring Harbor Perspectives in Medicine. 8 (6): a029769. doi:10.1101/cshperspect.a029769. ISSN 2157-1422. PMC 5983157. PMID 28490537.
  7. ^ "Weight training: Do's and don'ts of proper technique - Mayo Clinic". www.mayoclinic.org. Retrieved 13 June 2016.
  8. ^ Kar, Subhabrata; Alok Banerjee, K. (July 2013). "Influence of Active and Passive Warming up on Motor Performance of the Athletes". International Journal of Sports Sciences & Fitness. 3 (2): 216–234.
  9. ^ a b c d e Iversen, VM; Norum, M; Schoenfeld, BJ; Fimland, MS (October 2021). "No Time to Lift? Designing Time-Efficient Training Programs for Strength and Hypertrophy: A Narrative Review". Sports Medicine (Auckland, N.Z.). 51 (10): 2079–2095. doi:10.1007/s40279-021-01490-1. PMC 8449772. PMID 34125411. S2CID 235419384.
  10. ^ a b McCrary, J Matt; Ackermann, Bronwen J; Halaki, Mark (July 2015). "A systematic review of the effects of upper body warm-up on performance and injury". British Journal of Sports Medicine. 49 (14): 935–942. doi:10.1136/bjsports-2014-094228. PMID 25694615. S2CID 12818377.
  11. ^ Herman, Katherine; Barton, Christian; Malliaras, Peter; Morrissey, Dylan (December 2012). "The effectiveness of neuromuscular warm-up strategies, that require no additional equipment, for preventing lower limb injuries during sports participation: a systematic review". BMC Medicine. 10 (1): 75. doi:10.1186/1741-7015-10-75. PMC 3408383. PMID 22812375.
  12. ^ Moore, Marjorie A.; Hutton, Robert S. (1980). "Electromyographic investigation of muscle stretching techniques". Medicine & Science in Sports & Exercise. 12 (5): 322–329. doi:10.1249/00005768-198012050-00004. PMID 7453508.
  13. ^ McMillian, Danny J.; Moore, Josef H.; Hatler, Brian S.; Taylor, Dean C. (2006). "Dynamic vs. Static-Stretching Warm Up: The Effect on Power and Agility Performance". The Journal of Strength and Conditioning Research. 20 (3): 492–9. CiteSeerX 10.1.1.455.9358. doi:10.1519/18205.1. PMID 16937960. S2CID 16389590.
  14. ^ Fleck SJ, Kraemer WJ (2014). Designing resistance training programs (Fourth ed.). Leeds: Human Kinetics. p. 12. ISBN 978-0-7360-8170-2.
  15. ^ Hackett, Daniel A.; Chow, Chin-Moi (August 2013). "The Valsalva maneuver: its effect on intra-abdominal pressure and safety issues during resistance exercise". Journal of Strength and Conditioning Research. 27 (8): 2338–2345. doi:10.1519/JSC.0b013e31827de07d. ISSN 1533-4287. PMID 23222073.
  16. ^ Schoenfeld, Brad J; Ogborn, Dan; Krieger, James W (2017). "Dose-response relationship between weekly resistance training volume and increases in muscle mass: A systematic review and meta-analysis". J Sports Sci. 35 (11): 1073–1082. doi:10.1080/02640414.2016.1210197. PMID 27433992. S2CID 28012566.
  17. ^ Schoenfeld, Brad J; Contreras, Bret; Krieger, James; Grgic, Jozo; Delcastillo, Kenneth; Belliard, Ramon; Alto, Andrew (2019). "Resistance Training Volume Enhances Muscle Hypertrophy but Not Strength in Trained Men". Med Sci Sports Exerc. 51 (1): 94–103. doi:10.1249/MSS.0000000000001764. PMC 6303131. PMID 30153194.
  18. ^ a b c d Schoenfeld, Brad J.; Grgic, Jozo; Van Every, Derrick W.; Plotkin, Daniel L. (2021). "Loading Recommendations for Muscle Strength, Hypertrophy, and Local Endurance: A Re-Examination of the Repetition Continuum". Sports. 9 (2): 32. doi:10.3390/sports9020032. ISSN 2075-4663. PMC 7927075. PMID 33671664.
  19. ^ Grgic, Jozo; Schoenfeld, Brad J; Orazem, John; Sabol, Filip (2022). "Effects of resistance training performed to repetition failure or non-failure on muscular strength and hypertrophy: A systematic review and meta-analysis". J Sport Health Sci. 11 (2): 202–211. doi:10.1016/j.jshs.2021.01.007. PMC 9068575. PMID 33497853.
  20. ^ a b c Wilk, Michal; Zajac, Adam; Tufano, James J. (August 2021). "The Influence of Movement Tempo During Resistance Training on Muscular Strength and Hypertrophy Responses: A Review". Sports Medicine. 51 (8): 1629–1650. doi:10.1007/s40279-021-01465-2. PMC 8310485. PMID 34043184.
  21. ^ Schoenfeld, Brad J.; Ogborn, Dan I.; Krieger, James W. (April 2015). "Effect of Repetition Duration During Resistance Training on Muscle Hypertrophy: A Systematic Review and Meta-Analysis". Sports Medicine. 45 (4): 577–585. doi:10.1007/s40279-015-0304-0. PMID 25601394. S2CID 22641572.
  22. ^ Grgic, Jozo; Schoenfeld, Brad J.; Davies, Timothy B.; Lazinica, Bruno; Krieger, James W.; Pedisic, Zeljko (22 February 2018). "Effect of Resistance Training Frequency on Gains in Muscular Strength: A Systematic Review and Meta-Analysis" (PDF). Sports Medicine. 48 (5): 1207–1220. doi:10.1007/s40279-018-0872-x. PMID 29470825. S2CID 3447605.
  23. ^ Schoenfeld, Brad J.; Ogborn, Dan; Krieger, James W. (21 April 2016). "Effects of Resistance Training Frequency on Measures of Muscle Hypertrophy: A Systematic Review and Meta-Analysis". Sports Medicine. 46 (11): 1689–1697. doi:10.1007/s40279-016-0543-8. PMID 27102172. S2CID 207494003.
  24. ^ a b c d e Grgic, Jozo; Schoenfeld, Brad J; Skrepnik, Mislav; Davies, Timothy B; Mikulic, Pavle (2018). "Effects of Rest Interval Duration in Resistance Training on Measures of Muscular Strength: A Systematic Review". Sports Med. 48 (1): 137–151. doi:10.1007/s40279-017-0788-x. PMID 28933024. S2CID 20767297.
  25. ^ Gonzalez, Adam M. (December 2016). "Effect of Interset Rest Interval Length on Resistance Exercise Performance and Muscular Adaptation". Strength & Conditioning Journal. 38 (6): 65–68. doi:10.1519/SSC.0000000000000257. S2CID 58335780.
  26. ^ de Salles, Belmiro Freitas; Simão, Roberto; Miranda, Fabrício; da Silva Novaes, Jefferson; Lemos, Adriana; Willardson, Jeffrey M. (2009-09). "Rest Interval between Sets in Strength Training:". Sports Medicine. 39 (9): 765–777. doi:10.2165/11315230-000000000-00000. ISSN 0112-1642. {{cite journal}}: Check date values in: |date= (help)
  27. ^ de Souza, Tácito P; Fleck, Steven J; Simão, Roberto; Dubas, João P; Pereira, Benedito; de Brito Pacheco, Elisa M; da Silva, Antonio C; de Oliveira, Paulo R (July 2010). "Comparison Between constant and decreasing rest intervals: influence on maximal strength and hypertrophy". Journal of Strength and Conditioning Research. 24 (7): 1843–1850. doi:10.1519/JSC.0b013e3181ddae4a. PMID 20543741. S2CID 17314141.
  28. ^ Nunes, João Pedro; Grgic, Jozo; Cunha, Paolo M; Ribeiro, Alex S; Schoenfeld, Brad J; de Salles, Belmiro F; Cyrino, Edilson S (2021). "What influence does resistance exercise order have on muscular strength gains and muscle hypertrophy? A systematic review and meta-analysis". Eur J Sport Sci. 21 (2): 149–157. doi:10.1080/17461391.2020.1733672. PMID 32077380. S2CID 211214313.
  29. ^ a b Krzysztofik, M; Wilk, M; Wojdała, G; Gołaś, A (4 December 2019). "Maximizing Muscle Hypertrophy: A Systematic Review of Advanced Resistance Training Techniques and Methods". International Journal of Environmental Research and Public Health. 16 (24): 4897. doi:10.3390/ijerph16244897. PMC 6950543. PMID 31817252.  This article incorporates text from this source, which is available under the CC BY 4.0 license.
  30. ^ Wallace, W; Ugrinowitsch, C; Stefan, M; Rauch, J; Barakat, C; Shields, K; Barninger, A; Barroso, R; De Souza, EO (6 January 2019). "Repeated Bouts of Advanced Strength Training Techniques: Effects on Volume Load, Metabolic Responses, and Muscle Activation in Trained Individuals". Sports. 7 (1): 14. doi:10.3390/sports7010014. PMC 6359665. PMID 30621334.
  31. ^ Robbins, Daniel W; Young, Warren B; Behm, David G (October 2010). "The Effect of an Upper-Body Agonist-Antagonist Resistance Training Protocol on Volume Load and Efficiency". Journal of Strength and Conditioning Research. 24 (10): 2632–2640. doi:10.1519/JSC.0b013e3181e3826e. PMID 20847705. S2CID 19670323.
  32. ^ Weakley, JJS; Till, K; Read, DB; Roe, GAB; Darrall-Jones, J; Phibbs, PJ; Jones, B (September 2017). "The effects of traditional, superset, and tri-set resistance training structures on perceived intensity and physiological responses". European Journal of Applied Physiology. 117 (9): 1877–1889. doi:10.1007/s00421-017-3680-3. PMC 5556132. PMID 28698987. S2CID 253892268.
  33. ^ a b c Williams, Tyler D.; Tolusso, Danilo V.; Fedewa, Michael V.; Esco, Michael R. (2017). "Comparison of Periodized and Non-Periodized Resistance Training on Maximal Strength: A Meta-Analysis". Sports Medicine. 47 (10): 2083–2100. doi:10.1007/s40279-017-0734-y. ISSN 1179-2035. PMID 28497285. S2CID 41575929.
  34. ^ Campos GE, Luecke TJ, Wendeln HK, Toma K, Hagerman FC, Murray TF, et al. (November 2002). "Muscular adaptations in response to three different resistance-training regimens: specificity of repetition maximum training zones". European Journal of Applied Physiology. 88 (1–2): 50–60. doi:10.1007/s00421-002-0681-6. PMID 12436270. S2CID 21473855.
  35. ^ Grgic, Jozo; Mikulic, Pavle; Podnar, Hrvoje; Pedisic, Zeljko (2017). "Effects of linear and daily undulating periodized resistance training programs on measures of muscle hypertrophy: a systematic review and meta-analysis". PeerJ. 5: e3695. doi:10.7717/peerj.3695. ISSN 2167-8359. PMC 5571788. PMID 28848690.
  36. ^ Kraemer WJ, Zatsiorsky VM (2006). Science and Practice of Strength Training, Second Edition. Champaign, Ill: Human Kinetics Publishers. p. 161. ISBN 978-0-7360-5628-1.
  37. ^ a b Sheppard, Jeremy M. (August 2003). "Strength and Conditioning Exercise Selection in Speed Development". Strength & Conditioning Journal. 25 (4): 26–30. doi:10.1519/00126548-200308000-00006. ISSN 1524-1602.
  38. ^ Ribeiro, Alex S.; Nunes, João Pedro; Schoenfeld, Brad J. (June 2020). "Selection of Resistance Exercises for Older Individuals: The Forgotten Variable". Sports Medicine. 50 (6): 1051–1057. doi:10.1007/s40279-020-01260-5. PMID 32008175. S2CID 210985951.
  39. ^ a b Essentials of strength training and conditioning (Fourth ed.). Champaign, IL Windsor, ON Leeds: Human Kinetics. 2016. p. 444. ISBN 978-1-4925-0162-6.
  40. ^ Mannarino, P; Matta, T; Lima, J; Simão, R; Freitas de Salles, B (1 October 2021). "Single-Joint Exercise Results in Higher Hypertrophy of Elbow Flexors Than Multijoint Exercise". Journal of Strength and Conditioning Research. 35 (10): 2677–2681. doi:10.1519/JSC.0000000000003234. PMID 31268995. S2CID 195798475.
  41. ^ Grandou, Clementine; Wallace, Lee; Impellizzeri, Franco M.; Allen, Nicholas G.; Coutts, Aaron J. (April 2020). "Overtraining in Resistance Exercise: An Exploratory Systematic Review and Methodological Appraisal of the Literature". Sports Medicine. 50 (4): 815–828. doi:10.1007/s40279-019-01242-2. PMID 31820373. S2CID 208869268.
  42. ^ Gene-Morales, Javier; Flandez, Jorge; Juesas, Alvaro; Gargallo, Pedro; Miñana, Iván; Colado, Juan C. (2020). "A systematic review on the muscular activation on the lower limbs with five different variations of the squat exercise". Journal of Human Sport and Exercise. doi:10.14198/jhse.2020.15.Proc4.28. S2CID 242661004.
  43. ^ "Types of resistance training equipment". Human Kinetics.
  44. ^ Petré, Henrik; Wernstål, Fredrik; Mattsson, C. Mikael (13 December 2018). "Effects of Flywheel Training on Strength-Related Variables: a Meta-analysis". Sports Medicine - Open. 4 (1): 55. doi:10.1186/s40798-018-0169-5. PMC 6292829. PMID 30547232. S2CID 56485869.
  45. ^ Wonders, Jaap (14 December 2019). "Flywheel Training in Musculoskeletal Rehabilitation: A Clinical Commentary". International Journal of Sports Physical Therapy. 14 (6): 994–1000. doi:10.26603/ijspt20190994 (inactive 14 November 2024). PMC 6878857. PMID 31803531.{{cite journal}}: CS1 maint: DOI inactive as of November 2024 (link)
  46. ^ "19 Bodyweight Exercises You Can Do At Home for a Quick Workout". Verywell Fit. Retrieved 19 October 2022.
  47. ^ a b Kraemer WJ (August 2003). "Strength training basics: designing workouts to meet patients' goals". The Physician and Sportsmedicine. 31 (8): 39–45. doi:10.3810/psm.2003.08.457. PMID 20086485. S2CID 5384504.
  48. ^ Knuttgen HG (March 2003). "What is exercise? A primer for practitioners". The Physician and Sportsmedicine. 31 (3): 31–49. doi:10.1080/00913847.2003.11440567. PMID 20086460. S2CID 58736006.
  49. ^ Griner T (2000). "Muscle Metabolism: Aerobic vs. Anaerobic". Dynamic Chiropractic. Vol. 18, no. 7.
  50. ^ Summermatter S, Santos G, Pérez-Schindler J, Handschin C (May 2013). "Skeletal muscle PGC-1α controls whole-body lactate homeostasis through estrogen-related receptor α-dependent activation of LDH B and repression of LDH A". Proceedings of the National Academy of Sciences of the United States of America. 110 (21): 8738–43. Bibcode:2013PNAS..110.8738S. doi:10.1073/pnas.1212976110. PMC 3666691. PMID 23650363.
  51. ^ a b Morton, Robert W; Murphy, Kevin T; McKellar, Sean R; Schoenfeld, Brad J; Henselmans, Menno; Helms, Eric; Aragon, Alan A; Devries, Michaela C; Banfield, Laura; Krieger, James W; Phillips, Stuart M (March 2018). "A systematic review, meta-analysis and meta-regression of the effect of protein supplementation on resistance training-induced gains in muscle mass and strength in healthy adults". British Journal of Sports Medicine. 52 (6): 376–384. doi:10.1136/bjsports-2017-097608. PMC 5867436. PMID 28698222.
  52. ^ Cholewa, Jason M.; Newmire, Daniel E.; Zanchi, Nelo Eidy (2019). "Carbohydrate restriction: Friend or foe of resistance-based exercise performance?". Nutrition. 60: 136–146. doi:10.1016/j.nut.2018.09.026. ISSN 0899-9007. PMID 30586657. S2CID 58625613.
  53. ^ Volek JS (April 2004). "Influence of nutrition on responses to resistance training". Medicine and Science in Sports and Exercise. 36 (4): 689–96. CiteSeerX 10.1.1.562.4723. doi:10.1249/01.mss.0000121944.19275.c4. PMID 15064597.
  54. ^ Cribb PJ, Hayes A (November 2006). "Effects of supplement timing and resistance exercise on skeletal muscle hypertrophy". Medicine and Science in Sports and Exercise. 38 (11): 1918–25. CiteSeerX 10.1.1.320.6223. doi:10.1249/01.mss.0000233790.08788.3e. PMID 17095924.
  55. ^ Schoenfeld, Brad Jon; Aragon, Alan; Wilborn, Colin; Urbina, Stacie L; Hayward, Sara E; Krieger, James (2017). "Pre- versus post-exercise protein intake has similar effects on muscular adaptations". PeerJ. 5 (eCollection 2017): e2825. doi:10.7717/peerj.2825. PMC 5214805. PMID 28070459. S2CID 3914278.
  56. ^ Manninen AH (November 2006). "Hyperinsulinaemia, hyperaminoacidaemia and post-exercise muscle anabolism: the search for the optimal recovery drink". British Journal of Sports Medicine. 40 (11): 900–5. doi:10.1136/bjsm.2006.030031. PMC 2465040. PMID 16950882.
  57. ^ Butts, Jessica; Jacobs, Bret; Silvis, Matthew (2017). "Creatine Use in Sports". Sports Health. 10 (1): 31–34. doi:10.1177/1941738117737248. ISSN 1941-7381. PMC 5753968. PMID 29059531.
  58. ^ PEREIRA, Ericson; MOYSES, Samuel Jorge; IGNÁCIO, Sérgio Aparecido; MENDES, Daniel Komarchewski; SILVA, Diego Sgarbi D. A.; CARNEIRO, Everdan; HARDY, Ana Maria Trindade Grégio; ROSA, Edvaldo Antônio Ribeiro; BETTEGA, Patrícia Vida Cassi; JOHANN, Aline Cristina Batista Rodrigues (2019). "Prevalence and profile of users and non-users of anabolic steroids among resistance training practitioners". BMC Public Health. 19 (1): 1650. doi:10.1186/s12889-019-8004-6. ISSN 1471-2458. PMC 6902556. PMID 31818274.
  59. ^ a b c d Glaister, Mark; Rhodes, Lauren (1 November 2022). "Short-Term Creatine Supplementation and Repeated Sprint Ability—A Systematic Review and Meta-Analysis" (PDF). International Journal of Sport Nutrition and Exercise Metabolism. 32 (6): 491–500. doi:10.1123/ijsnem.2022-0072. ISSN 1526-484X. PMID 36041731. S2CID 251952408.
  60. ^ "Water, Water, Everywhere". WebMD.
  61. ^ Dedomenico M. "Metabolism Myth #5". MSN Health.[permanent dead link]
  62. ^ a b Sawka MN, Burke LM, Eichner ER, Maughan RJ, Montain SJ, Stachenfeld NS (February 2007). "American College of Sports Medicine position stand. Exercise and fluid replacement". Medicine and Science in Sports and Exercise. 39 (2): 377–390. doi:10.1249/mss.0b013e31802ca597. PMID 17277604.
  63. ^ Cordes N (2 April 2008). "Busting The 8-Glasses-A-Day Myth". CBS. Archived from the original on 9 May 2013. Retrieved 17 April 2020.
  64. ^ Valtin H (November 2002). ""Drink at least eight glasses of water a day." Really? Is there scientific evidence for "8 x 8"?" (PDF). American Journal of Physiology. Regulatory, Integrative and Comparative Physiology. 283 (5): R993–1004. doi:10.1152/ajpregu.00365.2002. PMID 12376390.
  65. ^ a b c d Johnson-Cane D, Glickman J, Cane J (December 2002). The Complete Idiot's Guide to Weight Training. Penguin. ISBN 978-0-02-864433-2.
  66. ^ "Strength training: Get stronger, leaner, healthier". Mayo Clinic. Retrieved 16 August 2022.
  67. ^ Aguirre, Lina E.; Villareal, Dennis T. (2015). "Physical Exercise as Therapy for Frailty". Nestle Nutrition Institute Workshop Series. 83: 83–92. doi:10.1159/000382065. ISBN 978-3-318-05477-4. ISSN 1664-2155. PMC 4712448. PMID 26524568.[better source needed]
  68. ^ Tieland, Michael; Trouwborst, Inez; Clark, Brian C. (19 November 2017). "Skeletal muscle performance and ageing". Journal of Cachexia, Sarcopenia and Muscle. 9 (1): 3–19. doi:10.1002/jcsm.12238. ISSN 2190-5991. PMC 5803609. PMID 29151281.
  69. ^ Ponzano M, Rodrigues IB, Hosseini Z, Ashe MC, Butt DA, Chilibeck PD, Stapleton J, Thabane L, Wark JD, Giangregorio LM (February 2021). "Progressive resistance training for improving health-related outcomes in people at risk of fracture: a systematic review and meta-analysis of randomized controlled trials". Physical Therapy. 101 (2): 1–12. doi:10.1093/ptj/pzaa221. PMID 33367736.
  70. ^ Body JJ, Bergmann P, Boonen S, Boutsen Y, Bruyere O, Devogelaer JP, et al. (November 2011). "Non-pharmacological management of osteoporosis: a consensus of the Belgian Bone Club". Osteoporosis International. 22 (11): 2769–88. doi:10.1007/s00198-011-1545-x. PMC 3186889. PMID 21360219.
  71. ^ Ada L, Dorsch S, Canning CG (2006). "Strengthening interventions increase strength and improve activity after stroke: a systematic review". The Australian Journal of Physiotherapy. 52 (4): 241–8. doi:10.1016/S0004-9514(06)70003-4. PMID 17132118.
  72. ^ "Strength training: Get stronger, leaner, healthier". Mayo Clinic. Retrieved 31 October 2024.
  73. ^ Momma, Haruki; Kawakami, Ryoko; Honda, Takanori; Sawada, Susumu S. (19 January 2022). "Muscle-strengthening activities are associated with lower risk and mortality in major non-communicable diseases: a systematic review and meta-analysis of cohort studies". British Journal of Sports Medicine. 56 (13): 755–763. doi:10.1136/bjsports-2021-105061. ISSN 0306-3674. PMC 9209691. PMID 35228201. S2CID 247169550.
  74. ^ Fisher, James P.; Steele, James; Gentil, Paulo; Giessing, Jürgen; Westcott, Wayne L. (1 December 2017). "A minimal dose approach to resistance training for the older adult; the prophylactic for aging". Experimental Gerontology. 99: 80–86. doi:10.1016/j.exger.2017.09.012. ISSN 1873-6815. PMID 28962853. S2CID 38110163.
  75. ^ Kraemer, Robert R.; Castracane, V. Daniel (February 2015). "Endocrine alterations from concentric vs. eccentric muscle actions: a brief review". Metabolism: Clinical and Experimental. 64 (2): 190–201. doi:10.1016/j.metabol.2014.10.024. ISSN 1532-8600. PMID 25467839.
  76. ^ Cornelissen, Veronique A.; Smart, Neil A. (1 February 2013). "Exercise training for blood pressure: a systematic review and meta-analysis". Journal of the American Heart Association. 2 (1): e004473. doi:10.1161/JAHA.112.004473. ISSN 2047-9980. PMC 3603230. PMID 23525435.
  77. ^ Figueroa, Arturo; Okamoto, Takanobu; Jaime, Salvador J.; Fahs, Christopher A. (March 2019). "Impact of high- and low-intensity resistance training on arterial stiffness and blood pressure in adults across the lifespan: a review". Pflügers Archiv: European Journal of Physiology. 471 (3): 467–478. doi:10.1007/s00424-018-2235-8. ISSN 1432-2013. PMID 30426247. S2CID 53293149.
  78. ^ Wewege, Michael A.; Desai, Imtiaz; Honey, Cameron; Coorie, Brandon; Jones, Matthew D.; Clifford, Briana K.; Leake, Hayley B.; Hagstrom, Amanda D. (February 2022). "The Effect of Resistance Training in Healthy Adults on Body Fat Percentage, Fat Mass and Visceral Fat: A Systematic Review and Meta-Analysis". Sports Medicine (Auckland, N.Z.). 52 (2): 287–300. doi:10.1007/s40279-021-01562-2. ISSN 1179-2035. PMID 34536199. S2CID 237551461.
  79. ^ Goossens, Gijs H. (2017). "The Metabolic Phenotype in Obesity: Fat Mass, Body Fat Distribution, and Adipose Tissue Function". Obesity Facts. 10 (3): 207–215. doi:10.1159/000471488. ISSN 1662-4033. PMC 5644968. PMID 28564650.
  80. ^ Herold, Fabian; Törpel, Alexander; Schega, Lutz; Müller, Notger G. (2019). "Functional and/or structural brain changes in response to resistance exercises and resistance training lead to cognitive improvements - a systematic review". European Review of Aging and Physical Activity. 16: 10. doi:10.1186/s11556-019-0217-2. ISSN 1813-7253. PMC 6617693. PMID 31333805.
  81. ^ Chow, Zi-Siong; Moreland, Ashleigh T.; Macpherson, Helen; Teo, Wei-Peng (December 2021). "The Central Mechanisms of Resistance Training and Its Effects on Cognitive Function". Sports Medicine (Auckland, N.Z.). 51 (12): 2483–2506. doi:10.1007/s40279-021-01535-5. ISSN 1179-2035. PMID 34417978. S2CID 237247819.
  82. ^ Loprinzi, Paul D.; Moore, Damien; Loenneke, Jeremy P. (December 2020). "Does Aerobic and Resistance Exercise Influence Episodic Memory through Unique Mechanisms?". Brain Sciences. 10 (12): 913. doi:10.3390/brainsci10120913. ISSN 2076-3425. PMC 7761124. PMID 33260817.
  83. ^ Aagaard, Per; Bojsen-Møller, Jens; Lundbye-Jensen, Jesper (October 2020). "Assessment of Neuroplasticity With Strength Training". Exercise and Sport Sciences Reviews. 48 (4): 151–162. doi:10.1249/JES.0000000000000229. ISSN 0091-6331. PMID 32658038. S2CID 220501435.
  84. ^ Zhao, Jin-Lei; Jiang, Wan-Ting; Wang, Xing; Cai, Zhi-Dong; Liu, Zu-Hong; Liu, Guo-Rong (September 2020). "Exercise, brain plasticity, and depression". CNS Neuroscience & Therapeutics. 26 (9): 885–895. doi:10.1111/cns.13385. ISSN 1755-5949. PMC 7415205. PMID 32491278.
  85. ^ Costa, Rochelle Rocha; Buttelli, Adriana Cristine Koch; Vieira, Alexandra Ferreira; Coconcelli, Leandro; Magalhães, Rafael de Lima; Delevatti, Rodrigo Sudatti; Kruel, Luiz Fernando Martins (1 June 2019). "Effect of Strength Training on Lipid and Inflammatory Outcomes: Systematic Review With Meta-Analysis and Meta-Regression". Journal of Physical Activity and Health. 16 (6): 477–491. doi:10.1123/jpah.2018-0317. ISSN 1543-5474. PMID 31023184. S2CID 133606401.
  86. ^ Phillips N (1997). "Essentials of Strength Training and Conditioning". Physiotherapy. 83 (1): 47. doi:10.1016/s0031-9406(05)66120-2.
  87. ^ Lauersen, Jeppe Bo; Bertelsen, Ditte Marie; Andersen, Lars Bo (1 June 2014). "The effectiveness of exercise interventions to prevent sports injuries: a systematic review and meta-analysis of randomised controlled trials". British Journal of Sports Medicine. 48 (11): 871–877. doi:10.1136/bjsports-2013-092538. hdl:11250/279729. ISSN 0306-3674. PMID 24100287. S2CID 1763077.
  88. ^ a b Hedayatpour, Nosratollah; Falla, Deborah (2015). "Physiological and Neural Adaptations to Eccentric Exercise: Mechanisms and Considerations for Training". BioMed Research International. 2015: 1–7. doi:10.1155/2015/193741. ISSN 2314-6133. PMC 4620252. PMID 26543850.
  89. ^ Martínez-Cava, Alejandro; Hernández-Belmonte, Alejandro; Courel-Ibáñez, Javier; Morán-Navarro, Ricardo; González-Badillo, Juan J.; Pallarés, Jesús G. (January 2022). "Bench Press at Full Range of Motion Produces Greater Neuromuscular Adaptations Than Partial Executions After Prolonged Resistance Training". Journal of Strength and Conditioning Research. 36 (1): 10–15. doi:10.1519/JSC.0000000000003391. ISSN 1064-8011. PMID 31567719.
  90. ^ Lavin, Kaleen M.; Roberts, Brandon M.; Fry, Christopher S.; Moro, Tatiana; Rasmussen, Blake B.; Bamman, Marcas M. (1 March 2019). "The Importance of Resistance Exercise Training to Combat Neuromuscular Aging". Physiology. 34 (2): 112–122. doi:10.1152/physiol.00044.2018. ISSN 1548-9213. PMC 6586834. PMID 30724133.
  91. ^ "The History of Weightlifting". USA Weightlifting. United States Olympic Committee. Archived from the original on 7 July 2013. Retrieved 3 September 2018. The genealogy of lifting traces back to the beginning of recorded history where man's fascination with physical prowess can be found among numerous ancient writings. A 5,000-year-old Chinese text tells of prospective soldiers having to pass lifting tests.
  92. ^ "Weightlifting | sport". Encyclopædia Britannica. Retrieved 19 April 2018.
  93. ^ Todd, Jan (1995). From Milo to Milo: A History of Barbells, Dumbbells, and Indian Clubs. Archived 2012-07-31 at the Wayback Machine Iron Game History (Vol.3, No.6).
  94. ^ "weightlifting | sport". Encyclopedia Britannica. 29 August 2023.
  95. ^ "Sculpted trend spurs women to pump iron". NBC News. Associated Press. 20 July 2006. Archived from the original on 8 April 2013. Retrieved 1 February 2007.
  96. ^ Roberts, Brandon M.; Nuckols, Greg; Krieger, James W. (2020). "Sex Differences in Resistance Training: A Systematic Review and Meta-Analysis". The Journal of Strength & Conditioning Research. 34 (5): 1448–1460. doi:10.1519/JSC.0000000000003521. ISSN 1064-8011. PMID 32218059. S2CID 214681362.
  97. ^ Jones, Matthew D.; Wewege, Michael A.; Hackett, Daniel A.; Keogh, Justin W. L.; Hagstrom, Amanda D. (2021). "Sex Differences in Adaptations in Muscle Strength and Size Following Resistance Training in Older Adults: A Systematic Review and Meta-analysis". Sports Medicine. 51 (3): 503–517. doi:10.1007/s40279-020-01388-4. hdl:1959.4/unsworks_83599. ISSN 1179-2035. PMID 33332016. S2CID 229302688.
  98. ^ a b Dowshen S, Homeier B (2005). "Strength Training and Your Child". kidshealth.org. Archived from the original on 2 July 2008. Retrieved 18 January 2008.
  99. ^ a b Faigenbaum AD. "Youth Resistance Training" (PDF). National Strength and Conditioning Association. Archived from the original on 17 July 2011. Retrieved 18 January 2008.{{cite web}}: CS1 maint: unfit URL (link)
  100. ^ "Position statement: Youth Resistance Training" (PDF). National Strength and Conditioning Association. Archived from the original on 17 July 2011. Retrieved 18 January 2008.{{cite web}}: CS1 maint: unfit URL (link)
  101. ^ a b c McKinlay, Brandon J.; Wallace, Phillip; Dotan, Raffy; Long, Devon; Tokuno, Craig; Gabriel, David A.; Falk, Bareket (November 2018). "Effects of Plyometric and Resistance Training on Muscle Strength, Explosiveness, and Neuromuscular Function in Young Adolescent Soccer Players". The Journal of Strength & Conditioning Research. 32 (11): 3039–3050. doi:10.1519/JSC.0000000000002428. ISSN 1064-8011. PMID 29337833.
  102. ^ a b Assunção, Ari R.; Bottaro, Martim; Ferreira-Junior, João B.; Izquierdo, Mikel; Cadore, Eduardo L.; Gentil, Paulo (10 August 2016). "The Chronic Effects of Low- and High-Intensity Resistance Training on Muscular Fitness in Adolescents". PLOS ONE. 11 (8): e0160650. doi:10.1371/journal.pone.0160650. ISSN 1932-6203. PMC 4979886. PMID 27509050.
  103. ^ a b Kurihara, Toshiyuki; Terada, Masafumi; Numasawa, Shun; Kusagawa, Yuki; Maeo, Sumiaki; Kanehisa, Hiroaki; Isaka, Tadao (31 December 2021). "Effects of age and sex on association between toe muscular strength and vertical jump performance in adolescent populations". PLOS ONE. 16 (12): e0262100. doi:10.1371/journal.pone.0262100. ISSN 1932-6203. PMC 8719687. PMID 34972181.
  104. ^ a b c d e Fragala, Maren S.; Cadore, Eduardo L.; Dorgo, Sandor; Izquierdo, Mikel; Kraemer, William J.; Peterson, Mark D.; Ryan, Eric D. (2019). "Resistance Training for Older Adults: Position Statement From the National Strength and Conditioning Association". The Journal of Strength & Conditioning Research. 33 (8): 2019–2052. doi:10.1519/JSC.0000000000003230. ISSN 1064-8011. PMID 31343601. S2CID 198492682.
  105. ^ Christie J (September 2011). "Progressive resistance strength training for improving physical function in older adults". International Journal of Older People Nursing. 6 (3): 244–6. doi:10.1111/j.1748-3743.2011.00291.x. PMID 21884490.
  106. ^ a b c d e Liu CJ, Latham NK (July 2009). "Progressive resistance strength training for improving physical function in older adults". The Cochrane Database of Systematic Reviews. 2009 (3): CD002759. doi:10.1002/14651858.CD002759.pub2. PMC 4324332. PMID 19588334.
  107. ^ Lai, Chih-Chin; Tu, Yu-Kang; Wang, Tyng-Guey; Huang, Yi-Ting; Chien, Kuo-Liong (17 February 2018). "Effects of resistance training, endurance training and whole-body vibration on lean body mass, muscle strength and physical performance in older people: a systematic review and network meta-analysis". Age and Ageing. 47 (3): 367–373. doi:10.1093/ageing/afy009. ISSN 0002-0729. PMID 29471456.
  108. ^ Csapo, R.; Alegre, L. M. (24 August 2015). "Effects of resistance training with moderate vs heavy loads on muscle mass and strength in the elderly: A meta-analysis". Scandinavian Journal of Medicine & Science in Sports. 26 (9): 995–1006. doi:10.1111/sms.12536. ISSN 0905-7188. PMID 26302881. S2CID 34659847.