Fatigue Clinical Trial
Official title:
The Effect of Fatigue and Biofreeze® on the Biomechanics of Running
Delayed onset muscle soreness (DOMS) can be identified as the muscular pain that occurs due
to intense use of skeletal muscle through exercise or other activities performed intense
enough or long enough to cause minor damage(Cheung et al., 2003). DOMS usually begins to show
symptoms 24 hours post-activity, becomes most intense 48-72 hours post-activity and can
sometimes last up to 5-10 days in ordinary cases(Cheung et al., 2003; Dutto and Braun 2004).
Typical less severe cases still can cause an individual to alter proper movement mechanics -
this alteration in mechanics can lead to the further injuring of the involved or compensating
skeletal muscle tissues and the associated joints and skeletal structures. DOMS-related
muscular pain can lead to functional deficits and altered movement mechanics that can lead to
a greater risk of further injury or sources of pain. The body does this by trying to avoid
the initial source of pain by adopting some form of compensation (such as a limp when
walking) which may help reduce pain at the initial source but lead to another source of pain
or risk injury at another joint or limb. DOMS is a common complaint of many runners from
novice to expert and due to the increased forces in running, a compensatory pattern in
walking is exaggerated in running and can affect the compensating structures to an even
greater extent, further increasing the risk of injury. Biofreeze®, a topical analgesic, is
used to block the pain signal from the affected structures to the brain when applied to
muscles experiencing delayed onset muscle soreness. Blocking the pain signal from DOMS should
allow an individual to restore their natural movement mechanics.
The purpose of this study is to assess the interaction between Biofreeze® and delayed onset
muscle soreness and how it affects movement mechanics and muscle function.
Hypothesis: The application of a topical analgesic (Biofreeze®) on muscles experiencing
delayed onset muscle soreness (DOMS) will increase force production and return running
biomechanics to pre-DOMS values.
Delayed onset muscle soreness (DOMS) is a common complaint of many runners, from novice to
expert. DOMS can affect the primary movers in locomotion, including but not limited to the
hip flexors and extensors, knee flexors and extensors, and the ankle plantar flexors. When
running with DOMS, hip, knee, and ankle mechanics can be affected in such that they may cause
protective compensation in order to prevent further damage or attenuate pain in the affected
musculature. One common occurrence is DOMS in the knee extensors following prolonged running.
DOMS occurring in the knee extensors can greatly affect sagittal knee joint biomechanics
(Dutto and Braun 2004; Paquette et al., 2017). More specifically, these changes in knee
mechanics can increase knee stiffness at initial stance, resulting in an increase in vertical
leg stiffness. This change in knee stiffness potentially serves as a protective compensation
mechanism against lengthening of the knee extensors (Paschalis et al., 2007; Tsatalas et al.,
2010). Changing running mechanics (as a result of DOMS, or fatigue) can potentially lead to
an increased risk of running related injury.
One potential way to reduce or alleviate the influence of muscle soreness on running
biomechanics is via topical analgesic (Ellis et al., 2005). Topical analgesics, such as
Biofreeze® work by attaching to the pain receptors that transmit a signal to the brain and
relay a signal back to the muscle to protect the muscle by staying in a shortened position,
affecting both force production and running biomechanics (Johar et al., 2012). The blocking
of this signal should allow the individual to alleviate muscular pain and return muscle
function and joint mechanics to pre-DOMS levels. However, the interactive effect of muscle
soreness and a topical analgesic on the biomechanics of running remains unknown. A reduction
in muscular pain related to DOMS can lead to improved performance in running, or at least
more comfortability in daily living when dealing with DOMS. To date, there has been little
research on the interactive effect of DOMS treated with a topical analgesic on running
biomechanics.
Experiment protocol
Subjects: Twenty subjects aged 17-40 years will be recruited for the study. Participants will
be considered recreational runners (minimum 17 years old, running 20km per week with no
recent or current injuries). Written informed consent will be obtained from all subjects.
Experimental Procedures: Before any experimental procedures, participants will be a short
familiarization session and anthropometric measurements that required for motion capture
analysis will be taken. Next, participants will be allowed to warm up with their regular
walk/run/stretching routine. After completion, participants will be instrumented with our
biomechanics equipment (see below). Next, participants will run on a treadmill. Each running
session will last for 5-10 minutes and participants will run at two different speeds (2 and 3
m/s) because the effects of eccentric exercise of both knee extensors and flexors on
particular tempo-spatial parameters and knee kinematics of running are speed-dependent.
Following the running session at both speeds, participants will perform our DOMS protocol
(see below). At 48 hours post DOMS protocol, participants will return to the lab for the
exact same running protocol as described above. Next, participants will have Biofreeze® (or
placebo) applied (see below) and 15 minutes following the application, participants will
again perform the running protocol (see timeline below)
Day 1:
- Familiarization with protocol and lab area
- Anthropometric Measurements
- Running kinematic analysis - BASELINE (EMG and Motion Capture)
- DOMS protocol (Decline treadmill running) Day 2: (48 hours post- DOMS protocol)
- Measurement of DOMS (Pressure Pain Threshold - see appendix, Subjective Analysis)
- DOMS-induced running kinematic analysis
- Biofreeze application / Control (Placebo) application
- Intervention running kinematic analysis
- EMG and Motion Capture throughout both sessions
DOMS protocol to induce pain: The DOMS protocol will consist of participants performing a
30-minute decline treadmill running protocol. The participant will first warm up for 5
minutes at an easy walking pace on a 0% grade. Once the participant is familiar with the
treadmill and is prepared, the treadmill will be set to a -10% grade (decline) and
participants will work up to 85% of their predicted heart rate maximum (PHRM). Once 85% PHRM
is achieved, a 30-minute timer will begin and the participant will aim to maintain that level
of intensity with monitoring by a spotter that will remain by the participants side. The
participant will be clipped into the safety key on the treadmill at all times when on the
treadmill.
Kinematics: Three-dimensional lower body kinematics will be tracked using a 10-camera Vicon
motion capture system (Vicon, Oxford, UK). Individual markers will be placed over anatomical
landmarks including, medial and lateral malleoli, foot (heel, distal metatarsals), medial and
lateral condyles of the knee, greater trochanters of the hip, pelvis (anterior superior iliac
spines, posterior superior iliac spines), and torso (xiphoid process, suprasternal notch, T10
vertebrae, C7 vertebrae, and a medio-inferior scapular landmark for positional
identification). Additionally, custom-molded rigid bodies consisting of light weight
reflective markers will be secured to the dorsal surface of the foot, mid-shank laterally,
mid-thigh laterally, and pelvis posteriorly (sacral-iliac region). The rigid bodies will be
used to track segment movement during experimental testing. A static calibration will
determine the relationship between the rigid bodies and the calibration markers over the
anatomical landmarks, and subsequently joint centers and segment coordinate systems. Markers
will be attached by either a velcro-nylon strap, medical tape, or double-sided tape depending
on each individual location.
Electromyography (EMG): Muscle activity will be recorded using surface electromyography
(SEMG) and prior to electrode placement, standard preparations, including shaving the surface
and cleansing the skin with alcohol will be performed (SOP 07 - Surface EMG). The
investigators will require localized shaving on the specified locations below prior to
electrode placement to improve the quality of our recording sites. A single-use, disposable
razor will be used and if bleeding or razor burn occurs, this will become the priority,
rather than continuing the protocol. SEMG will be recorded from 8 lower extremity muscles
(bilaterally). Selected muscle groups will include:
1. Knee extensors: vastus medialis, vastus lateralis, rectus femoris, vastus intermedius
2. Knee flexors: biceps femoris, semimembranosus, semitendinosus
3. Ankle plantar flexors: lateral gastrocnemius
Following electrode preparation that included shaving and scrubbing with alcohol, disposable
bipolar Ag-AgCl surface electrodes (MediTrace 130, Kendall, Mansfield, MA, USA) will be
placed over each muscle belly aligned with muscle fiber orientation with an interelectrode
center-to-center distance of 2.5 cm. EMG will be band-pass filtered (10-1000 Hz) and
differentially amplified (CMRR > 115 dB at 60 Hz; input impedance -10 GQ; Model AMT-8, Bortec
Biomedical Ltd., Calgary, AB, Canada).
Following preparation, participants will perform a series of maximal voluntary contractions
to normalize the EMG signals. Participants will perform isometric maximal knee flexion and
extension contractions to normalize the EMG signals. All EMG data will be digitally recorded
at a rate of 2048 Hz.
Pressure Pain Threshold: Pressure pain threshold will be used to assess muscle tenderness and
is defined as the minimal amount of pressure that causes pain. A higher-pressure pain
threshold indicates a lower amount of muscle tenderness. The pressure pain threshold will be
measured for each participants' right quadricep at the beginning of each exercise session
prior to any other testing. Participants will be instructed to say "yes" the instant they
feel pain rather than pressure. With the participant in a relaxed standing position, the
investigator will place the probe of the algometer into the midline of the right quadriceps
midway between the iliac crest and the superior border of the patella. The investigator will
gradually apply force at a constant rate of 50-60kPa s-1 until the participant indicates
pain. Three trials, with a 30-second interval between measurement will be measured with an
algometer with a 1.0cm2 stimulation area (Lafayette Instrument Company, Manual Muscle Tester,
Model 01163, Lafayette, Indiana, USA.) and data will be recorded in kilograms/cm2 with a
conversion to kilopascals (1kg/cm2=98.1 kPa). The average of three trials will be used for
analysis.
Perceived Pain (Subjective Pain Analysis): Muscle soreness will also be measured using the
BS-11 Numerical Rating Scale (NRS). The NRS will allow participants to express the amount of
pain, in reference to muscle soreness they experienced. The NRS is an 11-point scale ranging
0-10, with 0 defined as "absolutely no muscle soreness", and 10 defined as "worst muscle
soreness ever felt".
Rate of Perceived Exertion: A simplified scale to measure the rate of perceived exertion will
be used (1-10, 1 being minimal effort and 10 being maximal effort sustainable for only a few
seconds). This will be collected and averaged during every running portion of the study
(Baseline, DOMS, Biofreeze/Control).
Biofreeze® (or placebo) Application: A topical cream will be applied over the quadriceps. If
Biofreeze, 8ml of the topical analgesic will be applied over the muscle belly of the
quadriceps. The mode of application will not involve any substantial force, pressure or
rubbing, and thus any reflex activation will not be expected. This dose of Biofreeze®, is
based upon the estimate that the average skin surface area over the quadriceps is
approximately 1600cm2 and the recommended dosage of Biofreeze® of 1ml per 200cm. The same
process will occur for the placebo cream. The researchers will be blind to application of
either Biofreeze® or a placebo. Groups will be randomized into either the control or the
experimental condition.
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