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Authors are the souls of any journal, and deserve much respect. To publish a journal manuscripts are needed from authors. Authors have a great responsibility for producing facts of their work in terms of number and results truthfully and an individual honesty is expected from authors in this regards. Both ways its true "No authors-No manuscripts-No journals" and "No journals–No manuscripts–No authors". Reviewing a manuscript is also a very responsible and important task of any peer-reviewed journal and to be taken seriously. It needs knowledge on the subject, sincerity, honesty and determination. Although the process of reviewing a manuscript is a time consuming task butit is expected to give one's best remarks within the time frame of the journal.
Salient features of the JCDR: It is a biomedical, multidisciplinary (including all medical and dental specialities), e-journal, with wide scope and extensive author support. At the same time, a free text of manuscript is available in HTML and PDF format. There is fast growing authorship and readership with JCDR as this can be judged by the number of articles published in it i e; in Feb 2007 of its first issue, it contained 5 articles only, and now in its recent volume published in April 2011, it contained 67 manuscripts. This e-journal is fulfilling the commitments and objectives sincerely, (as stated by Editor-in-chief in his preface to first edition) i e; to encourage physicians through the internet, especially from the developing countries who witness a spectrum of disease and acquire a wealth of knowledge to publish their experiences to benefit the medical community in patients care. I also feel that many of us have work of substance, newer ideas, adequate clinical materials but poor in medical writing and hesitation to submit the work and need help. JCDR provides authors help in this regards.
Timely publication of journal: Publication of manuscripts and bringing out the issue in time is one of the positive aspects of JCDR and is possible with strong support team in terms of peer reviewers, proof reading, language check, computer operators, etc. This is one of the great reasons for authors to submit their work with JCDR. Another best part of JCDR is "Online first Publications" facilities available for the authors. This facility not only provides the prompt publications of the manuscripts but at the same time also early availability of the manuscripts for the readers.
Indexation and online availability: Indexation transforms the journal in some sense from its local ownership to the worldwide professional community and to the public.JCDR is indexed with Embase & EMbiology, Google Scholar, Index Copernicus, Chemical Abstracts Service, Journal seek Database, Indian Science Abstracts, to name few of them. Manuscriptspublished in JCDR are available on major search engines ie; google, yahoo, msn.
In the era of fast growing newer technologies, and in computer and internet friendly environment the manuscripts preparation, submission, review, revision, etc and all can be done and checked with a click from all corer of the world, at any time. Of course there is always a scope for improvement in every field and none is perfect. To progress, one needs to identify the areas of one's weakness and to strengthen them.
It is well said that "happy beginning is half done" and it fits perfectly with JCDR. It has grown considerably and I feel it has already grown up from its infancy to adolescence, achieving the status of standard online e-journal form Indian continent since its inception in Feb 2007. This had been made possible due to the efforts and the hard work put in it. The way the JCDR is improving with every new volume, with good quality original manuscripts, makes it a quality journal for readers. I must thank and congratulate Dr Hemant Jain, Editor-in-Chief JCDR and his team for their sincere efforts, dedication, and determination for making JCDR a fast growing journal.
Every one of us: authors, reviewers, editors, and publisher are responsible for enhancing the stature of the journal. I wish for a great success for JCDR."
Thanking you
With sincere regards
Dr. Rajendra Kumar Ghritlaharey, M.S., M. Ch., FAIS
Associate Professor,
Department of Paediatric Surgery, Gandhi Medical College & Associated
Kamla Nehru & Hamidia Hospitals Bhopal, Madhya Pradesh 462 001 (India)
E-mail: drrajendrak1@rediffmail.com
On May 11,2011
Dr. Shankar P.R.
"On looking back through my Gmail archives after being requested by the journal to write a short editorial about my experiences of publishing with the Journal of Clinical and Diagnostic Research (JCDR), I came across an e-mail from Dr. Hemant Jain, Editor, in March 2007, which introduced the new electronic journal. The main features of the journal which were outlined in the e-mail were extensive author support, cash rewards, the peer review process, and other salient features of the journal.
Over a span of over four years, we (I and my colleagues) have published around 25 articles in the journal. In this editorial, I plan to briefly discuss my experiences of publishing with JCDR and the strengths of the journal and to finally address the areas for improvement.
My experiences of publishing with JCDR: Overall, my experiences of publishing withJCDR have been positive. The best point about the journal is that it responds to queries from the author. This may seem to be simple and not too much to ask for, but unfortunately, many journals in the subcontinent and from many developing countries do not respond or they respond with a long delay to the queries from the authors 1. The reasons could be many, including lack of optimal secretarial and other support. Another problem with many journals is the slowness of the review process. Editorial processing and peer review can take anywhere between a year to two years with some journals. Also, some journals do not keep the contributors informed about the progress of the review process. Due to the long review process, the articles can lose their relevance and topicality. A major benefit with JCDR is the timeliness and promptness of its response. In Dr Jain's e-mail which was sent to me in 2007, before the introduction of the Pre-publishing system, he had stated that he had received my submission and that he would get back to me within seven days and he did!
Most of the manuscripts are published within 3 to 4 months of their submission if they are found to be suitable after the review process. JCDR is published bimonthly and the accepted articles were usually published in the next issue. Recently, due to the increased volume of the submissions, the review process has become slower and it ?? Section can take from 4 to 6 months for the articles to be reviewed. The journal has an extensive author support system and it has recently introduced a paid expedited review process. The journal also mentions the average time for processing the manuscript under different submission systems - regular submission and expedited review.
Strengths of the journal: The journal has an online first facility in which the accepted manuscripts may be published on the website before being included in a regular issue of the journal. This cuts down the time between their acceptance and the publication. The journal is indexed in many databases, though not in PubMed. The editorial board should now take steps to index the journal in PubMed. The journal has a system of notifying readers through e-mail when a new issue is released. Also, the articles are available in both the HTML and the PDF formats. I especially like the new and colorful page format of the journal. Also, the access statistics of the articles are available. The prepublication and the manuscript tracking system are also helpful for the authors.
Areas for improvement: In certain cases, I felt that the peer review process of the manuscripts was not up to international standards and that it should be strengthened. Also, the number of manuscripts in an issue is high and it may be difficult for readers to go through all of them. The journal can consider tightening of the peer review process and increasing the quality standards for the acceptance of the manuscripts. I faced occasional problems with the online manuscript submission (Pre-publishing) system, which have to be addressed.
Overall, the publishing process with JCDR has been smooth, quick and relatively hassle free and I can recommend other authors to consider the journal as an outlet for their work."
Dr. P. Ravi Shankar
KIST Medical College, P.O. Box 14142, Kathmandu, Nepal.
E-mail: ravi.dr.shankar@gmail.com
On April 2011 Anuradha
Dear team JCDR, I would like to thank you for the very professional and polite service provided by everyone at JCDR. While i have been in the field of writing and editing for sometime, this has been my first attempt in publishing a scientific paper.Thank you for hand-holding me through the process.
Dr. Anuradha
E-mail: anuradha2nittur@gmail.com
On Jan 2020
Original article / research
Full Version
Effect of Training to Hold Paretic Lower Limb on an Unstable Surface on the Lower Extremity Motor Control in Patients with Hemiplegia: A Randomised Controlled Trial
Correspondence Address :
Dr. Sivakumar Ramachandran,
Faculty of Physiotherapy, Sri Ramachandra Institute of Higher Education and Research, Porur, Chennai-600116, Tamil Nadu, India.
E-mail: rsivkumar@gmail.com
Introduction: Activities on unstable surfaces provoke greater muscle contractions than those on stable surfaces. The literature suggests that the effort to hold the paretic extremity on an unstable surface could stimulate muscle contractions in patients with hemiplegia. In the present study, we tested the effect of training to hold the hemiparetic lower limb over an unstable surface on contractions of selected muscles in the lower extremity of patients in the early subacute phase of stroke.
Aim: To investigate the effect of training to hold the paretic lower limb on an unstable surface on motor control in the lower extremity of patients with hemiplegia in early subacute phase of stroke.
Materials and Methods: The study is a randomised control trial. Subjects were recruited from an acute stroke care centre affiliated with a university teaching hospital. First-time ischaemic stroke patients admitted to the acute stroke care center were enrolled in the study. Patients who could follow commands and had a Brunnstrom stage 2 or below in the lower extremity were included. A total of 78 patients were screened, and 56 patients were included in the study. Patients were randomised into two groups. The control group received conventional physiotherapy, while the experimental group was asked to maintain their paretic lower extremity on an unstable surface, such as a Swiss ball, as part of their training, in addition to conventional physiotherapy. Surface Electromyography (SEMG) was recorded from the paretic hip abductor, tensor fascia lata and quadriceps femoris before and after 10 sessions of training. Student’s t-test was used to assess the findings, with significance set at p-value ≤0.05.
Results: The mean age of participants in the control group was 65.53±8.19 years, while the mean age of participants in the experimental group was 57.96±10.89 years. A total of 28 participants in the control group and 28 participants in the experimental group completed the training. Both groups showed an increase in activity in the tensor fascia lata, gluteus medius and quadriceps femoris muscles after 10 sessions of training. Furthermore, the electromyographic activity in all the tested muscles was higher in the experimental group compared to the control group and the difference was statistically significant (p-value <0.01).
Conclusion: Training that involves sustaining the paretic lower extremity on an unstable surface, such as a Swiss ball, provoked muscle activity in the paretic lower extremity. Such training can be utilised to improve motor control in the early subacute phase of stroke, where training with minimal movements will be easier for the patient to perform.
Stroke, Surface electromyography, Rehabilitation
Central Nervous System (CNS) infarction refers to the death of brain, spinal cord, or retinal cells attributable to ischaemia, based on pathological, imaging, or other objective evidence of cerebral, spinal cord, or retinal focal ischaemic injury in a defined vascular distribution. Alternatively, it can be identified through clinical evidence of cerebral, spinal cord, or retinal focal ischaemic injury based on symptoms persisting for atleast 24 hours or until death, with other aetiologies excluded (1).
Motor impairments are a common consequence of stroke, affecting approximately 80% of all cases and leading to permanent disability and reduced quality of life (2). The prevalence of motor impairment post-stroke is notably high, with a reported rate of 77% in the upper limb and 72% in the lower limb. This indicates that a significant proportion of stroke survivors struggle with motor deficits, which can greatly impact their ability to carry out daily activities and lead to a diminished quality of life (3).
Approaches focusing on specific tasks or functional training are frequently employed to enhance motor control and functional abilities in the paretic lower limbs (4),(5),(6). Functional training has been shown to enhance neuroplastic changes, leading to better motor recovery (7). Weight-bearing in standing, gait training and sit-to-stand exercises are common functional training methods employed for the lower extremities (8),(9),(10). The majority of these interventions have been tested in individuals in the late subacute or chronic phases of stroke. The implementation of functional training in the early subacute phase of stroke is scarce in research (11). The initiation of early rehabilitation interventions has been reported to result in better motor recovery (12),(13). Profound muscle weakness in the early phases of stroke could be one of the major limitations in implementing functional activities similar to those used in the late subacute and chronic phases of stroke. Ramachandran S et al., (14) reported that even minimal attempts to hold the upper limb on an unstable surface, such as a therapy ball, can provoke contractions in the proximal muscles of the upper limb in early subacute stroke subjects. The authors assumed that activities like holding the limb on an unstable surface could be attempted by post-stroke individuals with minimal motor control. We sought to replicate a similar intervention in the lower extremity of subjects in the early subacute phase of stroke. We hypothesise that the inclusion of simple exercises like these is likely to improve adherence to exercise interventions post-stroke, where muscle weakness is one of the limiting factors for adherence to therapy (15). The aim of the present study was to test the effect of training that involves holding the paretic lower extremity on an unstable surface on the motor control of the paretic lower extremity. We hypothesised that such training could improve the contractions of selected muscles in the paretic lower extremity, reflecting the improvement in motor control. To investigate this, we aimed to assess changes in muscle contractions using surface electromyography (SEMG).
Null hypothesis: Postintervention SEMG values between participants who received specific training and those who did not receive such training will not reach statistical significance.
Alternate hypothesis: The postintervention SEMG values in patients who underwent training with efforts to hold the paretic lower extremity on an unstable surface will be higher and statistically significant compared to those who did not receive such an intervention.
The study is a randomised control trial in which subjects were recruited from an acute stroke care center associated with a university teaching hospital at Sri Ramachandra Institute of Higher Education and Research, Chennai, Tamil Nadu, India, from February 2024 to June 2024. It was approved by the Institutional Ethical Committee (REF: CSP/23/SEP/136/821). The present study was registered in the Clinical Trial Registry India with the reference number CTRI/2024/02/062808. Subjects meeting the inclusion criteria were included in the study after obtaining written informed consent from willing participants.
Inclusion and Exclusion criteria: Subjects with a first-time ischaemic stroke who can follow commands to perform the activities for the study, who exhibit motor recovery at Brunnstrom stage 2 or below in the lower extremity (16) and who have the ability to maintain unsupported sitting in bed were included in the study. Subjects with any other neurological or orthopaedic impairments that would limit their ability to undertake the activities, those with profound spasticity and those with a history of lower limb injury that could affect the outcome of the study were not included. Subjects with a profound proprioception deficit in the paretic lower extremity were also excluded.
Sample size calculation: The sample size was calculated based on an initial sample of 10 stroke survivors who met the inclusion criteria. They underwent training in a supine position, similar to the study protocol, to stimulate muscle contraction in the gluteus medius. Pre- and postintervention surface electromyographic measurements were taken according to the standard protocol. The difference was considered for sample size calculation, with an alpha error of 0.05, a power of 0.95 and an effect size of 0.9.
The sample size was calculated using the formula N={(r+1)(Zα/2+Z1-β)2 Sp2} / rd2, where r is the ratio of the sample size between the groups, Zα/2 is the Z value for alpha, Z1-β is the Z value for power, Sp is the pooled standard deviation of the groups obtained from the pilot study (3.61) and d is the difference between the means (4 μV) (17). The calculated number was 25 subjects in each group. Considering a 10% attrition rate, the sample size was determined to be 28 per group.
Study Procedure
The SEMG recordings were taken from the paretic gluteus medius, tensor fasciae latae and quadriceps femoris muscles of all participants on the day of inclusion in the study. Baseline SEMG for the tensor fasciae latae and gluteus medius muscles was recorded with participants in a supine position, while participants were positioned in a high sitting position for the quadriceps femoris muscle. Electrode positioning for EMG was standardised based on the SEMG for the Non Invasive Assessment of Muscles (SENIAM) guidelines. The SENIAM guidelines were developed through a grant from the European Community as part of the BIOMED-2 program. Detailed information can be found at www.seniam.org (18).
According to the guidelines, for the tensor fasciae latae, the active electrode was placed on the lateral aspect of the thigh, the reference electrode was placed on the anterior superior iliac spine and the ground electrode was placed on the lateral condyle of the femur. Participants were instructed to attempt to abduct their paretic limb. For the gluteus medius, the active electrode was placed on the posterolateral aspect of the muscle belly, the reference electrode was placed on the posterior superior iliac spine and the ground electrode was placed on the lateral condyle of the femur. Participants were similarly instructed to attempt to abduct their paretic limb. For the quadriceps femoris, the active electrode was placed at the muscle belly, the reference electrode was placed 5 cm below the anterior superior iliac spine and the ground electrode was placed above the patella. Participants were instructed to attempt to extend their paretic limb. SEMG was recorded using Neuro Trac Software 4.0 from VM (Verity Medical Ltd., United Kingdom) with silver chloride adhesive electrodes. Participants were randomly allocated using block randomisation of four into two groups (Table/Fig 1).
The control group received routine care, while the experimental group received routine care along with training to hold their paretic lower limb on unstable surfaces in both supine lying and high sitting positions. In routine care, participants in both groups received 45 minutes of physiotherapy, including facilitatory techniques for the upper extremity, lower extremity and trunk, as well as functional training based on the concept of the Motor Relearning Program (Table/Fig 2) (5). Additionally, the participants in the experimental group were instructed to stabilise or hold their paretic limb on a ball, ensuring that the ball remained in place (Table/Fig 3),(Table/Fig 4),(Table/Fig 5). The interventions were provided for 10 sessions over 10 days.
Postintervention, the SEMG recordings from the gluteus medius, tensor fascia lata and quadriceps femoris muscles were taken six hours after the completion of ten sessions of therapy, following a procedure similar to that of the baseline recording. The postintervention measurement of EMG was taken six hours after the 10th session of therapy to avoid the immediate effects of training.
Statistical Analysis
The average SEMG values of each muscle were taken for data analysis. The maximum value among the three trials was considered for analysis. Within-group and between-group data were tested using paired and unpaired t-tests, with a significance level set at p≤0.05.
A total of 74 subjects were screened for eligibility, and 56 subjects were included to meet the sample size. All 28 subjects enrolled in the control and experimental groups completed the study. The mean age of participants in the control group was 65.53±8.19 years, while the mean age of participants in the experimental group was 57.96±10.89 years. The number of individuals with a right cerebrovascular accident in the experimental group and control group were 13 and 12, respectively. The number of individuals with a left cerebrovascular accident in the experimental group and control group were 15 and 16, respectively.
The pre- and postintervention values of surface EMG obtained from both the experimental and control groups is shown in (Table/Fig 6). Within-group testing demonstrated that the changes in the EMG recordings of the Quadriceps, Tensor Fascia Lata and Gluteus Medius were statistically significant at p-value <0.05. The increase in EMG activity indicates an increase in the contraction of all three muscles in both the control and experimental groups; however, it is noteworthy that the magnitude of increase in the EMG recordings was greater in the experimental group compared to the control group for all three muscles. The change in muscle activity was assessed using the difference between pre- and postintervention values. These values reveal that the change in quadriceps activity in the experimental group was marginally higher compared to the Tensor Fascia Lata and Gluteus Medius, whereas, in the control group, the changes in the Tensor Fascia Lata and Gluteus Medius activity were equal and marginally higher than that observed in the quadriceps (Table/Fig 6).
Preintervention values were analysed to ascertain the comparability of the groups at the commencement of the intervention. The independent t-test indicated no significant difference for the mean surface EMG values of Quadriceps Femoris, t(54)=1.34, p=0.09; Tensor Fascia Lata, t(54)=1.35, p=0.09; and Gluteus Medius, t(54)=1.01, p=0.15, revealing that the groups were statistically identical before the initiation of the intervention. The pre- and postintervention difference within each group was used to test the difference between the experimental and control groups. It is evident that the difference in EMG values of all three muscles is higher in the experimental group compared to the control group, reaching statistical significance at p-value <0.05. As EMG represents muscle activity, the increase in Quadriceps contraction is higher in the experimental group compared to the control group, followed by Tensor Fascia Lata and Gluteus Medius (Table/Fig 6).
The effect size of the intervention was determined using Cohen’s d. The effect size was larger for all three recordings in the study. The Cohen’s d for Quadriceps Femoris, Tensor Fascia Lata and Gluteus Medius were 4.60, 2.76 and 2.45, respectively. This reveals that the intervention had a significant impact on the outcome.
In the present study, it was observed that an attempt to hold the hemiparetic lower limb on an unstable surface stimulated muscle contractions in selected muscles in the paretic lower extremity. We limited the testing to the gluteus medius, tensor fasciae latae and quadriceps femoris and found that after training, the muscle contractions in both groups improved. The action of holding the paretic foot on an unstable surface, such as a ball, may be construed as a goal-directed activity. Neuroplasticity is said to be enhanced by goal-directed activities. Ramachandran S et al., tested the impact of attempts to hold the affected upper extremity on an unstable surface and reported that the training improved muscle contraction around the shoulder girdle (14).
Functional training, or goal-directed activity for the lower extremity, is frequently utilised to enhance functions such as sitting to standing (9),(19) and standing and walking (20). These interventions are predominantly applied in the late subacute and chronic phases of stroke (11). There is a dearth of studies exploring the effects of functional training in the early subacute phase of stroke. Given the anticipated enhancement of neuroplasticity through functional training (7), its implementation in the early phases of stroke is presumed to offer greater benefits for motor recovery (12) and may be more appealing for patients’ engagement in rehabilitation. In the present study, the intervention has been tested in the early subacute phase of stroke.
A scoping review on functional training for the lower extremity reveals that stroke rehabilitation currently lacks a standard protocol for this type of training. As part of functional training, the review also suggests incorporating activities such as object manipulation with the lower extremity (11) and recommends controlling a ball with the affected lower extremity as a training component (21). The present study revealed that efforts to hold the lower extremity on an unstable surface, such as a ball, could provoke muscle contractions in the paretic lower extremity. This form of exercise, which we assumed to require minimal motor activity and minimal caregiver assistance, would be suitable for patients in the early subacute phase of stroke with profound weakness. Additionally, adherence to these exercises may be better compared to traditional exercises that involve greater mobility, as patients can easily perform these exercises with less physical effort and minimal equipment (15).
Typically, involvement in therapy and engagement in therapy are expected to improve when training replicates everyday activities. Generally, the lower extremity is used to manipulate objects, such as adjusting footwear, picking up items from the ground, or moving and kicking objects to create space when the upper extremities are occupied. In the present study, the participants were instructed to hold the lower extremity on a ball; similarly, functional activities such as moving objects, kicking objects, sliding the foot into footwear and picking up objects from the floor could be integrated into functional training for the lower extremity.
Many stroke patients report difficulty adhering to exercises at home. A frequent yet significant obstacle in adhering to home-based rehabilitation is muscle weakness, along with the absence of necessary equipment and facilities for training, as well as the inability of family members to provide the same level of guidance and supervision that a therapist offers (15),(22). The exercise used to hold the hemiparetic lower limb on an unstable surface in order to provoke muscle contractions involves a ball and a slippery, rectangular board was applied in the present study. These exercises are easy for the patient to perform, as they require only a ball as an instrument, which is simple to acquire and demand less caregiver handling and less motor activity. This concept can be utilised to create a range of exercises that target various muscle groups and offer diverse training options.
The present study demonstrates that training to hold the paretic lower limb on an unstable surface is a successful technique for inducing muscle contraction in specific lower extremity muscles. As a result, this approach can be incorporated into training regimens to aid in the recovery of paretic lower limbs during the early subacute stage of stroke rehabilitation.
Limitation(s)
All participants had middle cerebral artery infarcts. Although it was not intentional, subjects with anterior cerebral artery infarcts were not included in the study group. The outcome may vary in subjects with anterior cerebral artery infarcts due to its predominant supply to cortical areas responsible for lower extremity control.
An effort to hold the hemiparetic lower limb on an unstable surface provokes muscle contraction in selected muscles of the lower extremity. Adherence to these exercises may be better compared to traditional exercises that involve greater mobility, as patients can easily perform them with less physical effort and minimal equipment. This approach can be used as training with minimal movement to help elicit muscle contraction.
DOI: 10.7860/JCDR/2025/75030.20735
Date of Submission: Aug 28, 2024
Date of Peer Review: Oct 28, 2024
Date of Acceptance: Dec 14, 2024
Date of Publishing: Mar 01, 2025
AUTHOR DECLARATION:
• Financial or Other Competing Interests: None
• Was Ethics Committee Approval obtained for this study? Yes
• Was informed consent obtained from the subjects involved in the study? Yes
• For any images presented appropriate consent has been obtained from the subjects. Yes
PLAGIARISM CHECKING METHODS:
• Plagiarism X-checker: Aug 31, 2024
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ETYMOLOGY: Author Origin
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