Lumbar Spinal Manipulation in Stroke
26. maj 2026 opdateret af: Omer Dursun, Bitlis Eren University
Effects of Lumbar Spinal Manipulation on Balance and Fall Risk in Patients With Chronic Stroke: A Randomized Crossover Trial
The aim of the study is to investigate the effects of lumbar spinal manipulation on balance and fall risk of the patients with chronic stroke.
Studieoversigt
Status
Ikke rekrutterer endnu
Betingelser
Intervention / Behandling
Detaljeret beskrivelse
The study, utilizing a randomized crossover design, is planned to be conducted on a minimum of 26 patients with stroke who meet the inclusion and exclusion criteria.
Patients included in the study will be randomly assigned to receive both placebo lumbar spinal manipulation and lumbar spinal manipulation interventions.
Undersøgelsestype
Interventionel
Tilmelding (Anslået)
52
Fase
- Ikke anvendelig
Kontakter og lokationer
Dette afsnit indeholder kontaktoplysninger for dem, der udfører undersøgelsen, og oplysninger om, hvor denne undersøgelse udføres.
Studiekontakt
- Navn: Burak Mavuş, M.Sc.
- Telefonnummer: +90 5388178351
- E-mail: a.burakmavus@gmail.com
Undersøgelse Kontakt Backup
- Navn: Ömer Dursun, Assoc. Prof.
- Telefonnummer: 05426088687
- E-mail: fztomrdrsn@gmail.com
Studiesteder
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Bolu, Merkez
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Bolu, Bolu, Merkez, Tyrkiet (Türkiye), 14280
- Bolu İzzet Baysal Fizik Tedavi ve Rehabilitasyon Eğitim ve Araştırma Hastanesi
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Kontakt:
- Birkan Özkardaş, Mr.
- Telefonnummer: +90 5550639585
- E-mail: brknzkrds31@gmail.com
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Kontakt:
- Burak Mavuş, M.Sc.
- Telefonnummer: +90 5388178351
- E-mail: a.burakmavus@gmail.com
-
-
Deltagelseskriterier
Forskere leder efter personer, der passer til en bestemt beskrivelse, kaldet berettigelseskriterier. Nogle eksempler på disse kriterier er en persons generelle helbredstilstand eller tidligere behandlinger.
Berettigelseskriterier
Aldre berettiget til at studere
- Voksen
- Ældre voksen
Tager imod sunde frivillige
Ingen
Beskrivelse
Inclusion Criteria:
- Having chronic stroke,
- A Mini-Mental State Examination score of 24 or higher,
- Ability to stand independently for 20 seconds or more,
- Being between 18 and 75 years of age,
- Ability to walk independently for 10 meters, using assistive devices or orthoses if necessary,
- Daily blood pressure not exceeding 140/90 mmHg (or controlled with antihypertensive medication)
Exclusion Criteria:
- Presence of severe cardiac, pulmonary, hepatic, or renal dysfunction,
- Presence of severe bone or joint disease, particularly affecting the spine,
- Presence of risk factors for osteoporosis, especially involving the spine,
- Orthopedic conditions limiting spinal rotation,
- History of cancer or diabetic neuropathy,
- Presence of vestibular disorders,
- Presence of lower extremity ulceration or amputation,
- Alcohol consumption within the last 24 hours,
- Hemodynamic instability,
- Diagnosis of posterior circulation stroke involving the basilar artery and cerebellum,
- Presence of neurological diseases such as multiple sclerosis or Parkinson's disease,
- History of acute lower extremity injury within the last 6 weeks,
- History of lower extremity surgery
Studieplan
Dette afsnit indeholder detaljer om studieplanen, herunder hvordan undersøgelsen er designet, og hvad undersøgelsen måler.
Hvordan er undersøgelsen tilrettelagt?
Design detaljer
- Primært formål: Behandling
- Tildeling: Randomiseret
- Interventionel model: Crossover opgave
- Maskning: Dobbelt
Våben og indgreb
Deltagergruppe / Arm |
Intervention / Behandling |
|---|---|
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Placebo komparator: Placebo Comparator: Placebo Lumbar Spinal Manipulation Group
Participants will receive placebo lumbar spinal manipulation in the first session and lumbar spinal manipulation after a washout period.
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This technique is based on the application of a high-velocity, low-amplitude force to the lumbar spine with the aim of increasing mobility.
This intervention is a classic method used to evaluate the effect of lumbar spinal manipulation.
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Aktiv komparator: Active Comparator: Lumbar Spinal Manipulation Group
Participants will receive lumbar spinal manipulation in the first session and placebo lumbar spinal manipulation after a washout period.
|
This technique is based on the application of a high-velocity, low-amplitude force to the lumbar spine with the aim of increasing mobility.
This intervention is a classic method used to evaluate the effect of lumbar spinal manipulation.
|
Hvad måler undersøgelsen?
Primære resultatmål
Resultatmål |
Foranstaltningsbeskrivelse |
Tidsramme |
|---|---|---|
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Overall Postural Stability Index Measurement
Tidsramme: Change from baseline overall postural stability index immediately after the intervention
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This index will be assessed by measuring deviations of the center of gravity in the anteroposterior and mediolateral directions.
Lower scores indicate smaller deviations and better postural stability.
The test will be performed on a stable platform with three trials of 30 seconds each.
The average of the three trials will be automatically calculated by the TechnoBody balance system.
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Change from baseline overall postural stability index immediately after the intervention
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Fall Risk Assessment
Tidsramme: Change from baseline fall risk immediately after the intervention
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Fall risk will be assessed by measuring the patient's ability to maintain balance on an unstable platform.
Based on their ability to maintain balance, a fall risk score will be generated, with higher scores indicating a greater risk of falling.
The test will be performed with three 30-second trials.
The average of the three trials will be calculated automatically by the TechnoBody balance system.
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Change from baseline fall risk immediately after the intervention
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Sekundære resultatmål
Resultatmål |
Foranstaltningsbeskrivelse |
Tidsramme |
|---|---|---|
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Anteroposterior Stability Index Measurement
Tidsramme: Change from baseline anteroposterior postural stability index immediately after the intervention
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The anteroposterior stability index will be assessed by measuring deviations of the center of gravity in the anteroposterior direction.
Lower scores indicate smaller deviations and better anteroposterior postural stability.
The test will be performed on a stable platform with three trials of 30 seconds each.
The average of the three trials will be automatically calculated by the TechnoBody balance system.
|
Change from baseline anteroposterior postural stability index immediately after the intervention
|
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Mediolateral Stability Index Measurement
Tidsramme: Change from baseline mediolateral stability index immediately after the intervention
|
The mediolateral stability index will be assessed by measuring deviations of the center of gravity in the mediolateral direction.
Lower scores indicate smaller deviations and better mediolateral postural stability.
The test will be performed on a stable platform with three trials of 30 seconds each.
The average of the three trials will be automatically calculated by the TechnoBody balance system.
|
Change from baseline mediolateral stability index immediately after the intervention
|
Samarbejdspartnere og efterforskere
Det er her, du vil finde personer og organisationer, der er involveret i denne undersøgelse.
Sponsor
Efterforskere
- Ledende efterforsker: Burak Mavuş, M.Sc., Bolu Abant İzzet Baysal Physiotherapy and Rehabilitation Training and Research Hospital
- Ledende efterforsker: Merve Tunçdemir, Asst. Prof., Bitlis Eren University
- Ledende efterforsker: Ömer Dursun, Assoc. Prof., Bitlis Eren University
Publikationer og nyttige links
Den person, der er ansvarlig for at indtaste oplysninger om undersøgelsen, leverer frivilligt disse publikationer. Disse kan handle om alt relateret til undersøgelsen.
Generelle publikationer
- Geurts AC, de Haart M, van Nes IJ, Duysens J. A review of standing balance recovery from stroke. Gait Posture. 2005 Nov;22(3):267-81. doi: 10.1016/j.gaitpost.2004.10.002. Epub 2004 Dec 7.
- Arene N, Hidler J. Understanding motor impairment in the paretic lower limb after a stroke: a review of the literature. Top Stroke Rehabil. 2009 Sep-Oct;16(5):346-56. doi: 10.1310/tsr1605-346.
- Speelman AD, van de Warrenburg BP, van Nimwegen M, Petzinger GM, Munneke M, Bloem BR. How might physical activity benefit patients with Parkinson disease? Nat Rev Neurol. 2011 Jul 12;7(9):528-34. doi: 10.1038/nrneurol.2011.107.
- Pollock A, Baer G, Campbell P, Choo PL, Forster A, Morris J, Pomeroy VM, Langhorne P. Physical rehabilitation approaches for the recovery of function and mobility following stroke. Cochrane Database Syst Rev. 2014 Apr 22;2014(4):CD001920. doi: 10.1002/14651858.CD001920.pub3.
- Khalifeloo M, Naghdi S, Ansari NN, Akbari M, Jalaie S, Jannat D, Hasson S. A study on the immediate effects of plantar vibration on balance dysfunction in patients with stroke. J Exerc Rehabil. 2018 Apr 26;14(2):259-266. doi: 10.12965/jer.1836044.022. eCollection 2018 Apr.
- Yates JS, Lai SM, Duncan PW, Studenski S. Falls in community-dwelling stroke survivors: an accumulated impairments model. J Rehabil Res Dev. 2002 May-Jun;39(3):385-94.
- Divani AA, Vazquez G, Barrett AM, Asadollahi M, Luft AR. Risk factors associated with injury attributable to falling among elderly population with history of stroke. Stroke. 2009 Oct;40(10):3286-92. doi: 10.1161/STROKEAHA.109.559195. Epub 2009 Jul 23.
- Lamb SE, Ferrucci L, Volapto S, Fried LP, Guralnik JM; Women's Health and Aging Study. Risk factors for falling in home-dwelling older women with stroke: the Women's Health and Aging Study. Stroke. 2003 Feb;34(2):494-501.
- del Pozo-Cruz B, Adsuar JC, Parraca JA, del Pozo-Cruz J, Olivares PR, Gusi N. Using whole-body vibration training in patients affected with common neurological diseases: a systematic literature review. J Altern Complement Med. 2012 Jan;18(1):29-41. doi: 10.1089/acm.2010.0691. Epub 2012 Jan 10.
- Wenning GK, Ebersbach G, Verny M, Chaudhuri KR, Jellinger K, McKee A, Poewe W, Litvan I. Progression of falls in postmortem-confirmed parkinsonian disorders. Mov Disord. 1999 Nov;14(6):947-50. doi: 10.1002/1531-8257(199911)14:63.0.co;2-o.
- Chen JC, Shaw FZ. Progress in sensorimotor rehabilitative physical therapy programs for stroke patients. World J Clin Cases. 2014 Aug 16;2(8):316-26. doi: 10.12998/wjcc.v2.i8.316.
- Tyson SF, Hanley M, Chillala J, Selley A, Tallis RC. Balance disability after stroke. Phys Ther. 2006 Jan;86(1):30-8. doi: 10.1093/ptj/86.1.30.
- Joo S, Lee Y, Song CH. Immediate Effects of Thoracic Spinal Manipulation on Pulmonary Function in Stroke Patients: A Preliminary Study. J Manipulative Physiol Ther. 2018 Sep;41(7):602-608. doi: 10.1016/j.jmpt.2017.12.005. Epub 2018 Aug 16.
- Chen C, Yan B, He S, Wu R, Han X, Chen Y, Chen H, Xie L. Effects of lumbar joint mobilization on trunk control, balance, and gait in patients with stroke: study protocol for a randomized controlled trial. Trials. 2025 Feb 12;26(1):50. doi: 10.1186/s13063-025-08767-0.
- Park SJ, Cho KH. The Immediate Effects of Lumbar Rotational Mobilization on Trunk Control and Gait Parameter in Patients with Stroke. J Stroke Cerebrovasc Dis. 2022 Aug;31(8):106582. doi: 10.1016/j.jstrokecerebrovasdis.2022.106582. Epub 2022 Jun 24.
- Dursun O, Mavus AB. The effect of talocrural joint manipulation on static balance in patients with stroke: a randomized crossover trial. Physiother Theory Pract. 2025 Nov;41(11):2352-2364. doi: 10.1080/09593985.2025.2556133. Epub 2025 Sep 5.
- Diao Y, Liu Y, Pan J, Chen J, Pan J, Liao M, Liu H, Liao L. Efficacy and safety of spinal manipulative therapy in the management of acute neck pain: a systematic review and meta-analysis. Syst Rev. 2025 May 1;14(1):97. doi: 10.1186/s13643-025-02855-7.
Datoer for undersøgelser
Disse datoer sporer fremskridtene for indsendelser af undersøgelsesrekord og resumeresultater til ClinicalTrials.gov. Studieregistreringer og rapporterede resultater gennemgås af National Library of Medicine (NLM) for at sikre, at de opfylder specifikke kvalitetskontrolstandarder, før de offentliggøres på den offentlige hjemmeside.
Studer store datoer
Studiestart (Anslået)
15. august 2026
Primær færdiggørelse (Anslået)
15. december 2026
Studieafslutning (Anslået)
15. december 2026
Datoer for studieregistrering
Først indsendt
26. maj 2026
Først indsendt, der opfyldte QC-kriterier
26. maj 2026
Først opslået (Faktiske)
2. juni 2026
Opdateringer af undersøgelsesjournaler
Sidste opdatering sendt (Faktiske)
2. juni 2026
Sidste opdatering indsendt, der opfyldte kvalitetskontrolkriterier
26. maj 2026
Sidst verificeret
1. maj 2026
Mere information
Begreber relateret til denne undersøgelse
Nøgleord
Yderligere relevante MeSH-vilkår
Andre undersøgelses-id-numre
- BEUFTR-12
Lægemiddel- og udstyrsoplysninger, undersøgelsesdokumenter
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Studerer et amerikansk FDA-reguleret enhedsprodukt
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