Year-to-year changes in sprinting in youth tennis players were examined in a mixed-longitudinal study (256 male players, aged 10–15 years: 993 measurements). Height (h), body mass (BM), lower limb explosive strength (LLES), and a 5-m sprint were measured over five years. During that period, players were classified as elite or sub-elite. To account for the repeated measurements within the individual nature of longitudinal data, multilevel random effects regression analyses were used. Sprint performance improved with age at each additional 1 year of age, thus predicting ∼.016 sec improvement in five-meter sprint time by all variables of the model. It was possible to predict the performance of elite tennis players in the 5-m sprint (sec) for elite players (1.1493 – (0.0159 ċ centered age) – (0.009 ċ BM) – (0.044 ċ LLES) and sub-elite players (1.1493 – (0.0159 ċ centered age) + 0.0135 – (0.009 ċ BM) – (0.044 ċ LLES) – (0.0557 ċ centered age). Sprint performance differences between elite and sub-elite players was related to longitudinal changes in body size and lower limb strength up until age 13.
ArmstrongN.WelsmanJ. R. (2000) Anaerobic performance. In: ArmstrongN.MechelenW. V. (eds) Paediatric Exercise Science and Medicine, Oxford: Oxford University Press, pp. 37–46.
2.
ArmstrongN.WelsmanJ. R.WilliamsC. A.KirbyB. J. (2000) Longitudinal changes in young people's short-term power output. Medicine and Science in Sports and Exercise32(6): 1140–1145.
3.
Baxter-JonesA.MirwaldR. (2004) Multilevel modeling. In: HaupsieR. C.CameronN.MolinariL. (eds) Methods in Human Growth Research, Cambridge, UK: Cambridge University Press, pp. 306–330.
4.
Baxter-JonesA. D.HelmsP.MaffulliN.Baines-PreeceJ. C.PreeceM. (1995) Growth and development of male gymnasts, swimmers, soccer and tennis players: a longitudinal study. Annals of Human Biology22(5): 381–394.
5.
BennettJ. P.SayersM. G.BurkettB. J. (2009) The impact of lower extremity mass and inertia manipulation on sprint kinematics. Journal of Strength and Conditioning Research23(9): 2542–2547. doi: 10.1519/JSC.0b013e3181b86b3d.
6.
BergeronM. F.MareshC. M.KraemerW. J.AbrahamA.ConroyB.GabareeC. (1991) Tennis: a physiological profile during match play. International Journal of Sports Medicine12(5): 474–479. doi: 10.1055/s-2007-1024716.
7.
BeunenG.MalinaR. M. (1988) Growth and physical performance relative to the timing of the adolescent spurt. Exercise and Sports Sciences Reviews16: 503–540.
8.
BloomfieldJ.BlanksbyB. A.BeardD. F.AcklandT. R.ElliottB. C. (1984) Biological characteristics of young swimmers, tennis players and non-competitors. British Journal of Sports Medicine18(2): 97–103.
9.
BoscoC.LuhtanenP.KomiP. V. (1983) A simple method for measurement of mechanical power in jumping. European Journal of Applied Physiology50(2): 273–282.
10.
CarlingC.Le GallF.MalinaR. M. (2012) Body size, skeletal maturity, and functional characteristics of elite academy soccer players on entry between 1992 and 2003. Journal of Sports Sciences30(15): 1683–1693. doi: 10.1080/02640414.2011.637950.
11.
CarvalhoH. M.Coelho-e-SilvaM. J.FigueiredoA. J.GoncalvesC. E.PhilippaertsR. M.CastagnaC.MalinaR. M. (2011) Predictors of maximal short-term power outputs in basketball players 14–16 years. European Journal of Applied Physiology111: 789–796. doi: 10.1007/s00421-010-1703-4.
12.
CheuvrontS. N.CarterR.DeruisseauK. C.MoffattR. J. (2005) Running performance differences between men and women: an update. Sports Medicine35: 1017–1024.
13.
ChristmassM. A.RichmondS. E.CableN. T.ArthurP. G.HartmannP. E. (1998) Exercise intensity and metabolic response in singles tennis. Journal of Sports Sciences16(8): 739–747. doi: 10.1080/026404198366371.
14.
DaveyP. R.ThorpeR. D.WillamsC. (2003) Simulated tennis matchplay in a controlled environment. Journal of Sports Sciences21(6): 459–467. doi: 10.1080/0264041031000101926.
15.
De Ste CroixM. B.ArmstrongN.ChiaM. Y.WelsmanJ. R.ParsonsG.SharpeP. (2001) Changes in short-term power output in 10- to 12-year-olds. Journal of Sports Sciences19(2): 141–148. doi: 10.1080/026404101300036352.
16.
DuchéP.FalgairetteG.BeduM.FellmannN.LacG.RobertA.CoudertJ. (1992) Longitudinal approach of bio-energetic profile in boys before and during puberty. In: CoudertJ.Van PraaghE. (eds) Pediatric Work Physiology, Paris: Masson, pp. 43–45.
17.
Elferink-GemserM. T.JordetG.Coelho-E-SilvaM. J.VisscherC. (2011) The marvels of elite sports: how to get there?British Journal of Sports Medicine45(9): 683–684. doi: 45/9/683 [pii]10.1136/bjsports-2011-090254.
18.
EllenbeckerT. S.RoetertE. P. (2004) Velocity of a tennis serve and measurement of isokinetic muscular performance: brief review and comment. Perceptual and Motor Skills98(3 Pt 2): 1368–1370. doi: 10.2466/pms.98.3c.1368-1370.
19.
FalkB.Bar-OrO. (1993) Longitudinal changes in peak aerobic and anaerobic mechanical power of circumpubertal boys. Pediatric Exercise Sciences5: 318–331.
20.
FernandezJ.Mendez-VillanuevaA.PluimB. M. (2006) Intensity of tennis match play. British Journal of Sports Medicine40(5): 387–391; discussion 391. doi: 40/5/387 [pii]10.1136/bjsm.2005.023168.
21.
FerrautiA.BastiaensK. (2007) Short-term effects of light and heavy load interventions on service velocity and precision in elite young tennis players. British Journal of Sports Medicine41(11): 750–753. discussion 753. doi: 41/11/750 [pii]10.1136/bjsm.2007.036855.
22.
FigueiredoA. J.GoncalvesC. E.Coelho-E-SilvaM. J.MalinaR. M. (2009) Youth soccer players, 11–14 years: maturity, size, function, skill and goal orientation. Annals of Humman Biology36(1): 60–73. doi: 10.1080/03014460802570584.
23.
Garcia-GonzalezL.MorenoA.MorenoM. P.IglesiasD.del VillarF. (2012) Tactical knowledge in tennis: a comparison of two groups with different levels of expertise. Perceptual and Motor Skills115(2): 567–580. doi: 10.2466/30.10.25.PMS.115.5.567-580.
24.
GirardO.MilletG. P. (2009) Physical determinants of tennis performance in competitive teenage players. Journal of Strength and Conditioning Research23(6): 1867–1872. doi: 10.1519/JSC.0b013e3181b3df89.
25.
HarrissD. J.AtkinsonG. (2013) Ethical standards in sport and exercise science research: 2014 update. International Journal of Sports Medicine34(12): 1025–1028. doi: 10.1055/s-0033-1358756.
26.
HopkinsW. G.MarshallS. W.BatterhamA. M.HaninJ. (2009) Progressive statistics for studies in sports medicine and exercise science. Medicine and Science in Sports and Exercise41(1): 3–13. doi: 10.1249/MSS.0b013e31818cb278.
27.
HuijgenB. C.Elferink-GemserM. T.PostW. J.VisscherC. (2009) Soccer skill development in professionals. International Journal of Sports Medicine30(8): 585–591. doi: 10.1055/s-0029-1202354.
28.
KanehisaH.KunoS.KatsutaS.FukunagaT. (2006) A 2-year follow-up study on muscle size and dynamic strength in teenage tennis players. Scandinavian Journal of Medicine and Science in Sports16(2): 93–101. doi: SMS470 [pii]10.1111/j.1600-0838.2005.00470.x.
29.
KovacsM. S. (2006) Applied physiology of tennis performance. Br J Sports Med40(5): 381–385; discussion 386. doi: 40/5/381 [pii]10.1136/bjsm.2005.023309.
30.
KovacsM. S. (2007) Tennis physiology: training the competitive athlete. Sports Medicine37(3): 189–198. doi: 3731 [pii].
31.
KramerT.HuijgenB. C.Elferink-GemserM. T.LyonsT.VisscherC. (2010) Physical development of young talented tennis players. In: Coelho-e-SilvaM. J.FigueiredoA. J.Elferink-GemserM. T.MalinaR. M. (eds) Youth Sports Participation, Trainability and Readiness, Portugal: Coimbra University Press, pp. 93–114.
32.
LittleN. G.DayJ. A.SteinkeL. (1997) Relationship of physical performance to maturation in perimenarcheal girls. American Journal of Human Biology9: 163–171.
MalinaR. M.BouchardC.Bar-OrO. (2004) Growth, Maturation, and Physical Activity, 2nd ed. Champaign, IL: Human Kinetics.
35.
MalinaR. M.Coelho-E-SilvaM. J.FigueiredoA. J.CarlingC.BeunenG. P. (2012) Interrelationships among invasive and non-invasive indicators of biological maturation in adolescent male soccer players. Journal of Sports Sciences30(15): 1705–1717. doi: 10.1080/02640414.2011.639382.
36.
MalinaR. M.KozielS. M. (2014) Validation of maturity offset in a longitudinal sample of Polish boys. Journal of Sports Sciences32(5): 434–437. doi: 10.1080/02640414.2013.828850.
37.
MartinJ. C.MalinaR. M. (1998) Developmental variations in anaerobic performance associated with age and sex. In: Van PraaghE. (ed.) Pediatric Anaerobic Performance, Champaign, IL: Human Kinetics, pp. 45–64.
38.
MeroA.JaakkolaL.KomiP. V. (1989) Neuromuscular, metabolic and hormonal profiles of young tennis players and untrained boys. Journal of Sports Sciences7(2): 95–100. doi: 10.1080/02640418908729828.
39.
NevillA. M.HolderR. L.Baxter-JonesA.RoundJ. M.JonesD. A. (1998) Modeling developmental changes in strength and aerobic power in children. Journal of Applied Physiology (1985)84(3): 963–970.
40.
PowersS. K.HowleyE. T. (2008) Exercise prescription for health and fitness. In: PowersE. T. H. S. K. (ed.) Exersice Physiology: Theory and Application to Fitness and Performance, New York: McGraw-Hill, pp. 325–342.
41.
RasbashJ.BrowneW.GoldsteinH.YangM.PlewisI.DraperD.WoodhouseE. (1999) A user's guide to MLwiN, London: Institute of Education.
42.
RowlandT. W. (2005) The importance of body size. In: RowlandT. W. (ed.) Children's Exercise Physiology, Champaign, IL: Human Kinetics, pp. 1–41.
43.
SignorileJ. F.SandlerD. J.SmithW. N.StoutenbergM.PerryA. C. (2005) Correlation analyses and regression modeling between isokinetic testing and on-court performance in competitive adolescent tennis players. Journal of Strength and Conditioning Research19(3): 519–526. doi: 10.1519/R-15514.1.
44.
SmekalG.von DuvillardS. P.RihacekC.PokanR.HofmannP.BaronR.BachlN. (2001) A physiological profile of tennis match play. Medicine and Science in Sports and Exercise33(6): 999–1005.
45.
Te WierikeS. C.de JongM. C.TrompE. J.VuijkP. J.LemminkK. A.MalinaR. M.VisscherC. (2014) Development of repeated sprint ability in talented youth basketball players. Journal of Strength and Conditioning Research28(4): 928–934. doi: 10.1097/JSC.000000000000022300124278-201404000-00008 [pii].
46.
Valente-dos-SantosJ.Coelho-e-SilvaM. J.MartinsR. A.FigueiredoA. J.CyrinoE. S.SherarL. B.MalinaR. M. (2012) Modelling developmental changes in repeated-sprint ability by chronological and skeletal ages in young soccer players. International Journal of Sports Medicine33(10): 773–780. doi: 10.1055/s-0032-1308996.
