izpis_h1_title_alt

Vpliv dveh različnih gibalnih nalog na kazalce stabilnosti trupa : Doktorska disertacija
ID Rošker, Jernej (Avtor), ID Šarabon, Nejc (Mentor) Več o mentorju... Povezava se odpre v novem oknu

.pdfPDF - Predstavitvena datoteka, prenos (2,92 MB)
MD5: FEF2323ED01E704602F37A5E5073BD10
.pdfPDF - Priloga, prenos (376,88 KB)
MD5: 53E01A93B00CF50A46276F1A79849FCC

Izvleček
Hrbtenica in trup sta pomembna člena kinetične verige človeškega telesa. Hrbtenica nudi osrednjo oporo skeletu in ščiti hrbtenjačo, medtem ko stabilen trup omogoča mobilnost okončin in skrbi za prenos energije preko telesa med gibanjem. Ključni dejavniki, ki določajo stabilnost trupa, so: anatomska zasnova telesa, lastnosti mišično-tetivnega sistema in delovanje upravljalnega sistema. Upad stabilnost trupa lahko negativno vpliva na športno zmogljivost in privede do nastanka poškodb. Med pomembnejše dejavnike, ki lahko zmanjšajo stabilnost, sodi upad mišične zmogljivosti po dolgotrajnem in visoko intenzivnem izvajanju gibalnih nalog. Slednje bi lahko v grobem delili na (i) gibalne naloge, pri katerih prihaja do izoliranega obremenjevanja predelov telesa, kot na primer med izoliranimi krepilnimi vajami, in (ii) gibalne naloge, pri katerih prihaja do povečane aktivnosti celotnega telesa in podpornih sistemov, kot je tek. Čeprav so v literaturi znani nekateri učinki lokalnega upada mišične zmogljivosti na aktivnost mišic trupa med stabilizacijskimi odzivi na pričakovano in nepričakovano motnjo drže, učinkov teka na slednje ne poznamo. Z vidika priprave varne in učinkovite športne vadbe bi bilo smiselno poznati učinke obeh tipov gibalnih nalog na stabilnost trupa. S tem namenom smo v naši študiji preverjali učinek lokalnih krepilnih vaj za mišice trupa in srednje do visoko intenzivnega teka na stabilizacijske odzive mišic trupa med predpripravljenimi prilagoditvami drže in refleksnimi odzivi. V študiji je sodeloval 101 preiskovanec. Razdeljeni so bili v dve skupini. V prvi skupini (TEK) (51 preiskovancev, 20 žensk in 31 moških, 1,78 ± 3,2 m; 73,5 ± 6,8 kg; 24,5 ± 2,2 let), smo preverjali učinke 12-minutnega srednje do visoko intenzivnega teka in v drugi skupini (MOČ) (50 preiskovancev, 29 žensk in 21 moških, 1,74 ± 2,9 m; 71,5 ± 5,9 kg; 24,7 ± 3,1 let) učinke lokalnih krepilnih vaj za upogib, izteg in oba stranska upogiba trupa. Preiskovanci so pred in po utrujajoči gibalni nalogi izvedli sklop naslednjih meritev; meritve predpripravljenih prilagoditev in refleksnih odzivov mišic trupa na motnjo drže, meritve ravnotežja med sedenjem na nestabilni podlagi, aktivne repozicijske napake v smeri predklona trupa in meritve največjega zavestno proizvedenega navora v smeri iztega in upogiba trupa. Gibalni nalogi sta imeli statistično značilno različen vpliv na upad največjega navora v smeri iztega in upogiba trupa. V skupini MOČ se je ta znižal v smeri iztega in upogiba trupa, česar nismo zasledili v skupini TEK. Sprememb v največjem navoru v nobeni od skupin niso spremljale spremembe v vrednostih integriranega elektromiografskega signala. Ravno tako v nobeni od skupin ni prišlo do sprememb v aktivni repozicijski napaki trupa. Hitrejši pričetek mišične aktivnosti med refleksnim odzivom smo v skupini MOČ opazili za zunanjo poševno trebušno mišico. Med predpripravljenimi prilagoditvami drže je prišlo do skrajšanja latenc preme trebušne mišice v skupini TEK in zunanje poševne trebušne mišice v skupini MOČ. Spremembe vrednosti integriranega elektromiografskega signala med predpripravljenimi prilagoditvami drže in refleksnimi odzivi nismo zasledili. Ravno tako v teh dveh nalogah ni prišlo do značilnih sprememb v velikosti pomika skupne točke pritiska telesa na podlago. Med sedečo ravnotežno nalogo so se v skupini TEK zmanjšale vse hitrostne in amplitudne spremenljivke in v skupini MOČ vse frekvenčne spremenljivke. V skupini MOČ je po gibalni nalogi prišlo tudi so povečanja hitrosti in amplitude gibanja skupne točke pritiska v medialno-lateralni smeri. Povezanost med velikostjo sprememb posameznih spremenljivk se je razlikovala med obema skupinama, kar nakazuje na specifične odzive na gibalno nalogo. Rezultati študije nakazujejo, da uporabljeni gibalni nalogi povzročita značilne spremembe v stabilizacijskih strategijah mišic trupa, ki so odvisne od narave gibalne naloge. V skupini TEK smo zaznali specifične spremembe v mišicah, ki med tekom skrbijo za koordinirano gibanje medenice in prsnega koša, medtem ko smo v skupini MOČ zaznali predvsem strategijo hitrejše aktivacije mišic trebušne stene, ki pomagajo dodatno stabilizirati hrbtenico. V skupini TEK se je izboljšalo tudi ravnotežje med sedečo gibalno nalogo, medtem ko je v skupini moč prišlo do upada te sposobnosti. Pridobljeni podatki nakazujejo, da ima lahko izvajanje lokalnih krepilnih vaj za mišice trupa izvedene do odpovedi negativne učinke na stabilnost trupa, nasprotno je imel tek pozitivne učinki na stabilnost trupa. Izsledki naše študije omogočajo pomemben prenos izhodišč v športno prakso z namenom preventivnega delovanja in izboljšanja športne zmogljivosti.

Jezik:Slovenski jezik
Ključne besede:Trup, hrbtenica, stabilnost, krepilne vaje, tek, mišična zmogljivost, predpripravljene prilagoditve telesne drže, refleksni odzivi
Vrsta gradiva:Doktorsko delo/naloga
Tipologija:2.08 - Doktorska disertacija
Organizacija:FŠ - Fakulteta za šport
Leto izida:2018
PID:20.500.12556/RUL-107747 Povezava se odpre v novem oknu
COBISS.SI-ID:300936960 Povezava se odpre v novem oknu
Datum objave v RUL:22.05.2019
Število ogledov:2366
Število prenosov:492
Metapodatki:XML DC-XML DC-RDF
:
Kopiraj citat
Objavi na:Bookmark and Share

Sekundarni jezik

Jezik:Angleški jezik
Naslov:Changes in trunk stability indicators following two types of physical activities
Izvleček:
Spine and trunk are important parts of the human kinetic chain. The spine represent the central axis of the skeletal system and is responsible for protecting the spinal cord. Stabile trunk on the other hand enables mobility of the limbs and is responsible for transferring forces between the limbs during movement. Key elements defining trunk stability are passive, active and controlling systems. Decreased trunk stability can have detrimental effects on athletes performance and can lead to injury. One of such factors causing decreased stability is a decrease in muscle performance resulting from a strenuous physical activity. In general these could be divided into (i) isolated loading of individual body parts such as during resistance training and (ii) general, whole body activities such as running. There are some reports in the literature, how local decrease in the ability to produce force affects trunk muscle responses during anticipatory postural adjustments and reflex responses. However, no such reports can be found on the effects of running interventions. Coaches and athletes need to be familiar with the effects of such activities on trunk function in order to be able to prepare safer and more effective training regimes. The purpose of this study was to analyse the effects of local strengthening exercises performed to exhaustion and 12-min middle-to-high intensity running on trunk stabilizing functions. One hundred and one participants were divided in two groups. In the first group (51 participants, 20 women and 31 males, 1,78 ± 3,2 m; 73,5 ± 6,8 kg; 24,5 ± 2,2 years), the effects of 12-min middle-to-high intensity running were studied. In the second group (50 participants, 29 women and 21 males, 1,74 ± 2,9 m; 71,5 ± 5,9 kg; 24,7 ± 3,1 years), the effects of localized strengthening exercises on trunk stabilizing functions were studied. Before and after the intervention, following tests were performed; measures of anticipatory postural adjustments and reflex responses, balance during sitting on an unstable surface, trunk repositioning error and maximal voluntary contraction during trunk flexion and extension. Local intervention has had an effect on the ability to develop maximal voluntary force in trunk extension and flexion, however no such changes were observed after running. No changes in integrated electromyogram during maximal voluntary contractions were observed. The trunk repositioning error also stayed unchanged following both interventions. Changes in the muscle activation latency during RR after running were observed in the obliquus externus, accompanied by changes in the latency average concurrent differences of trunk extensors. During anticipatory postural adjustments changes in latencies of the rectus abdominis were observed after running and of the obliquus externus after performing local strengthening exercises. No changes in the integrated electromyogram were observed after neither of the two interventions. No changes in the movement of the center of pressure during anticipatory postural adjustments and reflex responses were observed. However prominent changes were present for balance during sitting on unstable surface. Velocity and amplitude of the center of pressure movement in anterior-posterior and medial-lateral direction changed after performing a running protocol and all frequency parameters as well as medial-lateral velocity and amplitude after performing local strengthening exercises. Correlation analysis between the change-size for all parameters differed between the two groups. The results of this study show, that the two interventions used cause intervention specific changes in the selected trunk stability indicators. After running, specific adaptations were observed, that could be caused by demands for coordinating pelvic and upper-body movement during running. On the other hand, local trunk muscle strengthening exercises cause earlier activation of the abdominal muscles, possibly indicating their compensatory role following fatigue of trunk musculature. In addition, running improved balance during sitting balance tasks, and local trunk strengthening exercises had the opposite effect. Data from this study indicate, that strength training of the trunk muscles could have detrimental effects on trunk stability and spinal health. On the opposite, running proved to have some positive effects on trunk stability. These results land some important guidelines for preparing safer and more effective workouts.

Ključne besede:Trunk, spine, stability, strengthening exercises, running, muscle performance, anticipatory postural adjustments, reflex responses

Podobna dela

Podobna dela v RUL:
Podobna dela v drugih slovenskih zbirkah:

Nazaj