V6 BODYSCIENCE Athlete Compression Tights have been Designed and made in Australia.
V6 BODYSCIENCE Athlete Compression Tights specified panel design forms the corner stone of these unique garments.
With specific muscle panel alignment providing unmatched strength, support and fit to targeted muscle groups. KNOWN AS “TARGETED COMPRESSION.” Take your athletic performance to the next level.
Our Athlete Series V6 compression tights are hand crafted from our unique high performance compression fabric which includes superior moisture wicking qualities, meaning that the material is able to ‘draw’ sweat away from where it is produced helping to dissipate body heat. Warp Knit construction resulting in an increased number of fibres means greater durability. A greater ‘elastometric fibre content,’ creates material that can stretch further and return to it’s original shape without distortion and a UV Protection of 50+ protects from the harsh Australian sun.
V6 BODYSCIENCE Athlete Compression Tights are finished with a seamless hem. This new technology creates a slimmer and firmer compression fit while also aiding in putting the garment on in a smoother and easier way. Simply stretch the hems out using your hands, breaking the seal, before putting the garment on while pointing your toes these tights are now free of all irritating seams.
Muscle Specific Compression:
A complex muscle in design, the Hamstrings consists of 3 muscles which are predominantly responsible for flexion of the knee and extension of the thigh making it a central muscle in athletic disciplines. The cut of BSc targeted compression hamstring panel has been designed to keep these 3 muscles in line and at optimal position. This allows a reduction in the delayed onset of muscle soreness (DOMS) by accelerating the inflammatory and repair timeframe within the muscle.
The action of running involves constant movements between extension and flexion causing a great degree of oscillatory movement to occur in skeletal muscles particularly the Quadriceps as they are forced to accelerate, decelerate and absorb impact shocks. The panel arrangement implemented by BSc targeted compression garment acts to enclose each of the 4 Quadriceps muscles like a sheath significantly reducing longitudinal and anterior-posterior muscle oscillation, ultimately aiding muscle recovery post exercise. Often problems with the knees come back to poor alignment of these muscles which eventuates with injury under fatigue. The hand crafted cut of the targeted compression garment reduces muscle and ligament strain of the knee by improving spatial awareness of the muscles and improving lactic acid removal allowing a reduction in fatigue.
The Adductors or Groin consists of 4 muscles which are responsible for Adduction, hip flexion and lateral rotation of the thigh. Groin Strains are quite common with these muscles due to muscles becoming hypertonic with use and when stretched often tear. BSc targeted compression panels have been designed to increase groin proprioception via greater feedback from skin proprioceptors as a consequence of the tactile interaction between the garments and the skin surface whiles also enhancing the core muscle temperature, ultimately resulting in fewer incidents of injury.
Explosive actions of the leg often start from the Gluteal muscle. One of the strongest muscles in the human body, special attention has been made in BSc targeted compression design in targeting this muscle group. Seam and panel alignment provide the ultimate in compression by enhancing blood flow to the Gluteal muscle group and acting as an elastic band by providing stored potential energy in the compression garments to facilitate explosive power.
INCREASED VO2MAX AND ANAEROBIC THRESHOLD
Recent research in trained athletes reported that compression garments increased VO2max by 10% and anaerobic threshold by 40% (13). Given that these two physiological variables are highly correlated to success in endurance sports compression garments may provide a significant competitive advantage for endurance athletes.
REDUCED MUSCLE OSCILLATION
It has been suggested that excess oscillatory displacement of a muscle during a dynamic movement may contribute to fatigue and interfere with neurotransmission and optimal muscle recruitment patterns (14). Recent research reported that compression garments were able to significantly reduce longitudinal and anterior-posterior muscle oscillation by 0.32 and 0.40cm respectively upon landing from a maximal vertical jump (7).
Proprioception or joint position sense has major implications to athletic performance, particularly in the areas of technique and injury prevention. Research investigating hip joint proprioception reported significantly greater joint position sense at both 45 and 60 degrees hip flexion (11).
INCREASED EXPLOSIVE MUSCULAR POWER
Explosive muscular power is highly correlated with success in most sports. Research in track and field athletes has reported a 5.2% increase in maximal vertical jump height when vertical jumps are measured wearing compression garments (7).
REDUCED BLOOD LACTATE CONCENTRATIONS
High intensity exercise produces lactic acid which presents a challenge to the body’s ability to maintain pH within the narrow physiological range. This in turn can negatively impact the force generating capacity of the muscle which results in muscle fatigue and impaired athletic performance. Data published by Berry and McMurray (1) showed a 14% decrease in blood lactate concentrations 15 minutes following high intensity exercise when compression garments were worn during and after exercise.
Muscle damage is an inevitable consequence of high intensity exercise and any technique that can facilitate muscle repair and faster recovery is of large benefit to the athlete. A study in elite Rugby Union players reported that compression garments worn immediately after a rugby match significantly reduced markers of muscle damage (creatine kinase) compared to passive recovery at 36 and 84 hours post match (8)
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(2) Bringard, A. S. Perrey, N. Belluye. Aerobic Energy Cost and Sensation Responses During Submaximal Running Exercise - Positive Effects of Wearing Compression Tights Int J Sports Med. 27:373-378, 2006.
(3) Caraffa, A., Cerulli, G., Projetti, M., Aisa, G., Rizzo, A. Prevention of anterior cruciate ligament injuries in soccer. Knee surgery, sports traumatology, arthroscopy) 4:19-21, 1996.
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(7) Doan, B.K., Kwon, Y.H. Newton, R.U. Shim, J. Popper, E.M. Rogers, R.A. Bolt, L.R. Robertson, M. Kraemer, W.J. Evaluation of a lower-body compression garment. Journal of Sports Sciences. 21:601-610, 2003.
(8) Gill, N.D. Beaven, C.M. and Cook, C. Effectiveness of post-match recovery strategies in rugby players British Journal of Sports Medicine. 40:260-263, 2006.
(9) Kraemer, W.J., Bush, J.A., Bauer, J.A., Triplett-McBride, N.T., Paxton, N.J., Clemson, A., Koziris, L.P., Mangino, L.C., Fry, A.C., Newton, R.U. Influence of compression garments on vertical jump performance in NCAA Division I volleyball players. Journal of strength and conditioning research 10:180-183, 1996.
(10) Kraemer, W.J., Bush, J.A., Triplett-McBride, N.T., Koziris, L.P., Mangino, L.C., Fry, A.C., McBride, J.M., Johnston, J., Volek, J.S., Young, C.A., Gomez, A.L., Newton, R.U. Compression garments: influence on muscle fatigue. Journal of strength and conditioning research 12: 211-215, 1998
(11) Kraemer, W.J., Bush, J.A., Newton, R.U., Duncan, N.D., Volek, J.S., Denegar, C.R., Canavan, P., Johnston, J., Putukian, M., Sebastianelli, W.J. Influence of a compression garment on repetitive power output production before and after different types of muscle fatigue. Sports medicine, training and rehabilitation 8:163-184, 1998
(12) Kraemer, W.J., Bush, J.A., Wickham, R.B., Denegar, C.R., Gomez, A.L., Gotshalk, L.A., Duncan, N.D., Volek, J.S., Putukian, M., Sebastianelli, W.J. Influence of compression therapy on symptoms following soft tissue injury from maximal eccentric exercise. The journal of orthopaedic & sports physical therapy 31: 282-290, 2001.
(13) Lambert, S. A crossover trial on the effects of graded compression garments exercise and recovery. Journal of Science and Medicine in Sport. 8:S222, 2005.
(14) McComas, A.J. Skeletal Muscle: Form and Function.Champaign,IL, Human Kinetics. 1996.
(15) Parkkari, J. Kujala, U.M. Kannus, P. Is it possible to prevent sports injuries? Review of controlled clinical trials and recommendations for future work. Sports Medicine. 31:985-995, 2001.
(16) Powers, S.K. and Howley, E.T. Exercise Physiology: Theory and Application to Fitness and Performance.McGraw-Hill,USA. 1998.
(17) Trenell, M.I. Rooney, K.B. Sue, C.M. and Thompson, C.H. Compression garments and recovery from eccentric exercise: A 31P-MRS study. Journal of Sports Science and Medicine. 2006 5: 106-114.