Is digital photography an accurate and precise method for measuring range of motion of the hip and knee?


RESEARCH Open Access

Is digital photography an accurate and
precise method for measuring range of
motion of the hip and knee?
Russell R. Russo1, Matthew B. Burn1, Sabir K. Ismaily2, Brayden J. Gerrie1, Shuyang Han2, Jerry Alexander2,
Christopher Lenherr2, Philip C. Noble2, Joshua D. Harris1 and Patrick C. McCulloch1*

Abstract

Background: Accurate measurements of knee and hip motion are required for management of musculoskeletal
pathology. The purpose of this investigation was to compare three techniques for measuring motion at the hip and
knee. The authors hypothesized that digital photography would be equivalent in accuracy and show higher
precision compared to the other two techniques.

Methods: Using infrared motion capture analysis as the reference standard, hip flexion/abduction/internal rotation/
external rotation and knee flexion/extension were measured using visual estimation, goniometry, and photography
on 10 fresh frozen cadavers. These measurements were performed by three physical therapists and three
orthopaedic surgeons. Accuracy was defined by the difference from the reference standard, while precision was
defined by the proportion of measurements within either 5° or 10°. Analysis of variance (ANOVA), t-tests, and
chi-squared tests were used.

Results: Although two statistically significant differences were found in measurement accuracy between the three
techniques, neither of these differences met clinical significance (difference of 1.4° for hip abduction and 1.7° for
the knee extension). Precision of measurements was significantly higher for digital photography than: (i) visual
estimation for hip abduction and knee extension, and (ii) goniometry for knee extension only.

Conclusions: There was no clinically significant difference in measurement accuracy between the three techniques
for hip and knee motion. Digital photography only showed higher precision for two joint motions (hip abduction
and knee extension). Overall digital photography shows equivalent accuracy and near-equivalent precision to visual
estimation and goniometry.

Keywords: Hip, Knee, Range of motion, Digital photography, Goniometry, Visual estimation

Background
When assessing hip and knee pathology, range of
motion (ROM) is a commonly used clinical parameter
utilized by medical professionals. Accurate measure-
ments of ROM are important for diagnosis, monitoring
progression or resolution of symptoms, clinical decision-
making, surgical planning, assessing treatment response,
for research, and to evaluate permanent disability or im-
pairment (Lavernia et al. 2008; Lea and Gerhardt 1995;

Mai et al. 2012). In addition, it allows the patient to
appreciate their own progress during clinical visits and
can be used as goals for rehabilitation (e.g. knee flexion
needed to ascend and descend stairs) (Brosseau et al.
2001; Lavernia et al. 2008). Within orthopaedic surgery,
accurate measurement of hip and knee ROM is critical
for assessing the outcomes of surgery.
The two most commonly used techniques for assessing

range of motion are visual estimation and goniometry
(Chevillotte et al. 2009; Ferriero et al. 2013; Gajdosik and
Bohannon 1987; Lavernia et al. 2008; Murphy et al. 2013).
Of these, goniometry is often believed to offer more accur-
ate and reliable measurements than visual estimation

* Correspondence: PCMcculloch@houstonmethodist.org
1Department of Orthopedics & Sports Medicine, Houston Methodist Hospital,
6445 Main Street, Outpatient Center, Suite 2500, Houston, TX 77030, USA
Full list of author information is available at the end of the article

Journal of
Experimental Orthopaedics

© The Author(s). 2017 Open Access This article is distributed under the terms of the Creative Commons Attribution 4.0
International License (http://creativecommons.org/licenses/by/4.0/), which permits unrestricted use, distribution, and
reproduction in any medium, provided you give appropriate credit to the original author(s) and the source, provide a link to
the Creative Commons license, and indicate if changes were made.

Russo et al. Journal of Experimental Orthopaedics  (2017) 4:29 
DOI 10.1186/s40634-017-0103-7

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(Brosseau et al. 2001; Chevillotte et al. 2009; Edwards
et al. 2004; Ferriero et al. 2013; Gajdosik and Bohannon
1987; Herrero et al. 2011; Holm et al. 2000; Lavernia et al.
2008; Lea and Gerhardt 1995; Murphy et al. 2013; Roach
et al. 2013; Watkins et al. 1991). However, it requires two
hands for use (leaving neither hand free for limb
stabilization) and more time than visual estimation
(Nussbaumer et al. 2010). Many other less commonly uti-
lized techniques have been studied within the literature
(Charlton et al. 2015; Chevillotte et al. 2009; Herrero et al.
2011; Holm et al. 2000; Lea and Gerhardt 1995; Roach
et al. 2013). The accuracy and reliability of any of these
techniques has been shown to improve with repeated
measurements, either by different investigators or the
same investigator multiple times (Boone et al. 1978;
Edwards et al. 2004; Watkins et al. 1991). Digital photog-
raphy offers additional benefits as it allows for comparison
between observations of the same measurement, different
measurements separated by time, and allows for off-site
measurements over long distances (such as for telemedi-
cine or internet-based healthcare) (Naylor et al. 2011).
Smartphone technology, which has become almost uni-
versally available, facilitates this technique (Charlton et al.
2015; Chevillotte et al. 2009; Herrero et al. 2011; Murphy
et al. 2013; Naylor et al. 2011; Russell et al. 2003;
Verhaegen et al. 2010).
The purpose of this study was to compare the accuracy

of ROM measurements of hip and knee motion using
multiple techniques (visual estimation, goniometric
measurement, and digital photographic measurement).
The authors hypothesized that digital photography would
be equivalent in accuracy and show higher precision com-
pared to the other two techniques.

Methods
Using G*Power software (Universität Mannheim,
Mannheim, Germany) and assuming mean measurement
error of 3° ±5° (effect size 0.6) between each of the meas-
urement techniques (goniometry, digital photography,
visual estimation), an a priori power analysis (β = 0.20,
α = 0.05) predicted that we would require 45 measure-
ments with each of the three techniques. This require-
ment would be met with 3 investigators each taking
measurements on 16 lower extremities [8 cadavers] with
each of the 3 techniques, however it was decided to include
6 investigators from two different specialties (orthopaedic
surgery and physical therapy) to broaden the scope and
generalizability (Faul et al. 2009; Faul et al. 2007).
After institutional review board (IRB) approval, ten

fresh-frozen human cadavers were obtained without
specifying race, gender, ethnicity, age, or cause of death.
The only exclusion criteria were gross limb deformity or
amputated limbs. All specimens were stored at −5 °C
and thawed 24 h prior to testing. Ten cadavers were

used (20 lower extremities, measured by six investigators
using three different techniques, 120 measurements by
each technique) for measurements in two different ses-
sions (5 different cadavers were used in each session)
separated by a two-month period. For each of the two
sessions, the five cadavers used were not refrozen after
initial thawing and thus all measurements were obtained
over a 3-day period.
Three of the investigators were licensed physical thera-

pists (PT) with greater than 6 months of clinical experi-
ence and three were board-certified fellowship-trained
orthopaedic surgeons. The orthopedic surgeons included
two sports medicine fellowship trained surgeons and
one adult reconstructive fellowship trained surgeon. All
investigators took measurements of six selected motions
(hip flexion, hip abduction, hip internal rotation, hip ex-
ternal rotation, knee flexion, and knee extension) using
three techniques (visual estimation, goniometric meas-
urement, and digital photographic measurement) on
each cadaveric specimen bilaterally (both lower limbs).

Cadaver & Motion Analysis Setup
Prior to beginning each measurement session, specific
sites on each of the five cadavers (to be used for that
session) were dissected down to bone bilaterally where
mounting plates were secured rigidly with screw fixation
and cementation (using polymethyl methacrylate) to
three sites. The three mounting sites used bilaterally, in-
cluded (1) the iliac crest, (2) the anterolateral aspect of
the femoral midshaft, and (3) the anterior aspect of the
tibial midshaft. Arrays of reflective markers (NDI,
Waterloo, Canada – shown in Fig. 1) including passive
reflective spheres were attached to each mounting site to
track three-dimensional (3D) spatial location of each of
these bones during the measurement session.
Prior studies have used radiographic (two-dimensional)

measurements as their “gold standard” with which to
compare other measurements (Chapleau et al. 2011).
Computed tomography (CT)-based motion analysis offers
an additional advantage of being able to measure the joint
angle in three-dimensions and being able to account for
rotation (e.g. measurement of elbow flexion with differing
humeral rotation). To define the “gold standard” used for
this study (motion capture analysis), the lower extremities
of all 10 cadavers underwent computer tomographic (CT)
scans with mounting sites and markers attached. This
Digital Imaging and Communications in Medicine
(DICOM) data was used to construct three-dimensional
(3D) models of each joint to be measured with software
from Materialise Mimics (Materialise, Leuven, Belgium).
Each 3D model was imported into Rapidform (INUS
Technology Inc., Seoul, Korea) to be used with the motion
capture device in combination with a custom MATLAB
program (The MathWorks Inc., Massachusetts, USA).

Russo et al. Journal of Experimental Orthopaedics  (2017) 4:29 Page 2 of 8



This process allowed for accurate joint angle calculations
to be performed in real-time during measurement sessions.
Arrays of markers, but not the mounting plates, would

be rearranged once each joints’ angle was to be measured.
For example, when testing knee flexion and extension, the
markers would be attached to the femur and tibia on one
side of the body only. Markers would be removed from
the contralateral lower extremity. This was done to aid
the accuracy of motion analysis by avoiding confusion of
the twelve motion analysis cameras (Motion Analysis,
Santa Rose, CA), which were set up in a semi-circle
surrounding an operating room (OR) table holding the ca-
daver (Fig. 2). The position of the table and cameras were
calibrated prior to beginning a measurement session and
remained constant for all investigators’ measurements.
Clear visualization of the arrays by at least two cameras
simultaneously is the minimum requirement for accurate

localization, but this study used a minimum of three
cameras to guarantee accuracy (Furtado et al. 2013).

Measurement technique
During measurement sessions, each of the cadavers, one
at a time, was positioned supine on an operating room
(OR) table in the center of the twelve calibrated motion
analysis cameras (Fig. 2). A single assistant ( )
would position the limb at the maximum joint motion
and hold it in place for all measurements. First, the exact
skeletal location (joint angle) would be calculated by
computer-assisted infrared camera motion capture ana-
lysis (Furtado et al. 2013). This would establish the gold
standard measure for comparison by this investigator of
this joint motion to all three other techniques.
Second, while the assistant held the limb, the investi-

gator would stand three feet from the joint in question
at a standardized position (depending on the joint and
motion being measured) and make a visual estimation of
the joint angle based on each measurers’ estimation of
the underlying bone axis of each long bone (as demon-
strated in Fig. 3). This distance was chosen as it has been
utilized in prior digital photography studies and offered
adequate visualization of the bone long axes for all joints
(Bennett et al. 2009; Naylor et al. 2011). Third, the inves-
tigator would take a digital photograph of the joint angle
using a Sony Alpha DSLR-A100 10.2 Megapixel digital
camera (Sony Corporation, Tokyo, Japan), but without
using a tripod. Finally, a standard plastic goniometer
(Patterson Medical, Warrenville, Illinois, USA) was used
to measure the joint angle without blinding of the
investigator.
Overall, 120 measurements were obtained for each

joint motion using each of the three techniques. This
was repeated for (A) hip flexion, (B) hip abduction, (C)
hip internal rotation, (D) hip external rotation, (E) knee
extension, and (F) knee flexion (see Fig. 3). Digital

Fig. 1 Photograph demonstrating the arrays of reflective markers used for infrared motion capture analysis, which are fixed to the femur (right)
and the tibia (left) using a combination of screw fixation and bone cement

Fig. 2 Room set up for the measurements. An operating room
(OR) table was positioned in the center of twelve motion analysis
cameras on tripods at different heights and angles. These cameras
were pre-calibrated prior to each measurement session

Russo et al. Journal of Experimental Orthopaedics  (2017) 4:29 Page 3 of 8



photographs were taken perpendicular to the axis of ro-
tation. The camera was aimed lateral-to-medial (relative
to the cadaver) at the hip joint (for hip flexion) and at
the knee joint line (for knee extension, and flexion). The
camera from anterior-to-posterior (relative to the ca-
daver) through the hip joint while the investigator stood
on a ladder aiming down towards the floor (for hip
abduction, internal rotation, and external rotation).
These measurements were done bilaterally on each ca-
daver and repeated for all five cadavers during each of
two sessions (total of 10 cadavers measured bilaterally).
Digital photographs of each joint were reviewed after the
cadaver measurement session, where joint angles were
measured using Image J digital measurement software
(National Institutes of Health, Bethesda, Maryland) on a
20-in. liquid crystal display computer screen (Dell,
Round Rock, TX). ImageJ is free, publically available,
Java-based image-processing software designed by the
National Institutes of Health (NIH), which allows the
angle between two straight lines to be measured on mul-
tiple image formats. Lines were drawn as demonstrated
in Fig. 3 for each of the six motions described.

Statistical analysis
Motion capture analysis was used as the “gold standard”
with which all measurements by the six investigators
using three different techniques (i.e. visual estimation,
digital photography, and goniometry) were compared.
For analysis, the measurements of all six investigators
were combined. Accuracy was defined by the authors as
the mean measurement error (defined as absolute value
of the difference between measurement and gold stand-
ard) and was compared between the three measurement
techniques. These comparisons were made using
analysis of variance (ANOVA) for significant differences
between each measurement technique for each hip or
knee motion individually. If significant differences were
found by ANOVA, a Tukey post-hoc test was performed
to identify subgroups with significant differences.
ANOVA results are reported along with the degrees of
freedom, F-statistic, and statistical significance.
The precision of measurements was defined as the pro-

portion of measurement errors less than the minimally
clinically important difference (MCID) (Edwards et al.
2004; Gajdosik and Bohannon 1987). These proportions

Fig. 3 Examples of the investigator’s view during visual estimation, photographing of the limb position (for subsequent angle measurement), and
goniometric measurement. All measured positions are shown, including: a hip flexion, b hip abduction, c hip internal rotation, d hip external
rotation, e knee extension, and f knee flexion. A stepladder was used when necessary to obtain a “bird’s eye” view of the joint (i.e. hip abduction,
internal rotation, and external rotation)

Russo et al. Journal of Experimental Orthopaedics  (2017) 4:29 Page 4 of 8



were compared by measurement technique using a Chi
squared test (MedCalc, Ostend, Belgium). Statistical sig-
nificance was defined by an α-value <0.05. The authors
chose 10° as the minimal clinically important difference
(MCID), or clinically significant difference, for all
measurements with the exception of knee extension. Five
degrees (5°) was chosen as the MCID for knee extension
because less loss of motion would be tolerated clinically
with flexion contractures at the knee joint (Edwards et al.
2004; Gajdosik and Bohannon 1987).

Results
Hip range of motion (flexion, abduction, internal rotation,
external rotation)
There was no significant difference in measurement
error between measurement techniques for hip flexion
(F(2355) = 2.32; p = 0.100), hip internal rotation
(F(2354) = 1.97; p = 0.140), or hip external rotation
(F(2356) = 2.13; p = 0.121), shown in Table 1. There was
a significant difference in measurement error for hip abduc-
tion (F(2357) = 4.18; p = 0.016). A Tukey post-hoc test for
hip abduction revealed that digital photographic (4.8° ±3.8)
measurement had a significantly lower measurement error
than visual estimation (6.2° ±4.1, p = 0.015).
When comparing the proportion of measurements

with measurements errors greater than 10° (Table 2), the
only significant differences identified were that hip ab-
duction was more precisely measured with digital pho-
tography than visual estimation (93% vs. 83%, p = 0.019).

Knee ROM (flexion, extension)
There was a significant difference in measurement error
for knee flexion (F(2356) = 3.17; p = 0.043) and for knee
extension (F(2347) = 15.95; p < 0.001), shown in Table 3.
However, a Tukey post-hoc test for knee flexion did not
reveal any significant comparisons (p > 0.05). A Tukey
post-hoc test for knee extension revealed that digital
photographic (3.5° ±2.3) measurement had a significantly

lower measurement error than visual estimation (4.7° ±2.5,
p = 0.001) and goniometry (5.2° ±2.6, p = 0.001).
When comparing the proportion of measurements

with measurements errors within the defined clinically
significant difference (Table 4), the only significant
difference identified was that knee extension was more
precisely measured with digital photography than with
visual estimation (74% vs. 49%, p < 0.001) and with
goniometry (74% vs 50%, p < 0.001).

Discussion
The authors hypothesized that digital photography
would be equivalent in accuracy and show higher preci-
sion compared to visual estimation and goniometric
measurement when measuring motion at the hip and
knee. Overall, there were only two statistically significant
differences in measurement accuracy found with digital
photography showing higher accuracy than: (i) visual
estimation for hip abduction, and (ii) visual estimation
and goniometry for knee extension. Neither of these
statistical differences met the authors’ definition of
clinical significance confirming the equivalent accuracy
of digital photography (compared to goniometry and
visual estimation). The maximum difference in measure-
ment error between the three techniques was 1.4° for
hip abduction and 1.7° for knee extension. Digital pho-
tography proved to have higher precision only for two
motions (hip abduction & knee extension) compared to

Table 1 Accuracy (Measurement Error) by Technique for Hip
Range of Motion

Visual
estimation
(Mean ± SDa)

Goniometry
(Mean ± SD)

Digital
photography
(Mean ± SD)

Hip Flexion 3.9° ±3.4 3.1° ±2.5 3.5° ±2.7

Hip Abduction 6.2° ±4.1 5.8° ±3.7 4.8° ±3.8

Hip Internal Rotation 7.3° ±5.7 6.8° ±5.1 5.9° ±4.8

Hip External Rotation 10.1° ±6.7 9.7° ±6.0 8.6° ±5.1

Accuracy of measurements (measurement error, in degrees) calculated as the
absolute value of the difference between the measurement taken by the
investigator using each technique (visual estimation, goniometry, digital
photography) and the reference standard (motion capture analysis) for all four
hip motions
aSD standard deviation

Table 2 Precision by technique for hip range of motion
(proportions of measurement errors within 10° of motion
capture analysis)

Visual
estimation

Goniometry Digital
photography

Hip Flexion 91% 96% 96%

Hip Abduction 83% 88% 93%

Hip Internal Rotation 76% 75% 85%

Hip External Rotation 58% 53% 61%

Precision of measurements or the proportion of measurement errors that were
within 10°, defined as the minimally clinically significant difference by the
authors, of the reference standard (motion capture analysis) for all four
hip motions

Table 3 Accuracy (measurement error) by technique for knee
range of motion

Visual estimation
(Mean ± SDa)

Goniometry
(Mean ± SD)

Digital photography
(Mean ± SD)

Knee Flexion 5.2° ±3.9 4.3° ±3.1 5.2° ±3.4

Knee Extension 5.2° ±2.6 4.7° ±2.5 3.5° ±2.3

Accuracy of measurements (measurement error, in degrees) calculated as the
absolute value of the difference between the measurement taken by the
investigator using each technique (visual estimation, goniometry, digital
photography) and the reference standard (motion capture analysis) for both
knee motions
aSD standard deviation

Russo et al. Journal of Experimental Orthopaedics  (2017) 4:29 Page 5 of 8



visual estimation and one motion (knee extension) com-
pared to goniometry. Thus, overall digital photography
shows equivalent accuracy and precision to visual esti-
mation and goniometry, except for measurements of hip
abduction & knee extension. Many studies look specific-
ally at the accuracy and/or reliability of one technique or
motion without comparing two or more techniques or
motions (Ferriero et al. 2013; Krause et al. 2015; Naylor
et al. 2011). Few studies have looked specifically at visual
estimation of hip or knee motion (Edwards et al. 2004;
Holm et al. 2000; Rachkidi et al. 2009). Edwards et al.
found higher accuracy with goniometry compared to vis-
ual estimation with 22% and 46% of measurements being
within 5° of their gold standard (radiography) for knee
flexion only (Edwards et al. 2004). Murphy et al. showed
equivalent accuracy of digital photography and goniom-
etry in measuring knee flexion and extension (Murphy
et al. 2013). Some studies report an advantage to either
digital photography or goniometry over visual estimation
with increasing amounts of knee flexion (Ferriero et al.
2013).
Visual estimation is the most common modality used

in most surgical practices, due to its speed, ease of use,
and lack of need for equipment (Chevillotte et al. 2009;
Murphy et al. 2013). The next most common technique,
and most commonly used technique among therapists,
is goniometry, which is believed by some to offer a more
reliable measurement (Ferriero et al. 2013; Gajdosik and
Bohannon 1987; Lavernia et al. 2008; Murphy et al.
2013; Watkins et al. 1991). Our study contests that
notion with clinically equivalent accuracy between the
three techniques. However, digital photography still
offered slightly improved precision for measuring hip
abduction and knee extension. In addition, digital
photography offers the added benefit of a permanent,
savable, and printable record of the motion allowing
comparison between observations of the same measure-
ment, different measurements separated by time, and
allows for off-site measurements over long distances
(Bennett et al. 2009; Dunlevy et al. 2005; Ferriero et al.
2013). The ability to accurately measure motion at dis-
tance could help facilitate telemedicine or internet-based
healthcare, which could alert the clinician regarding de-
clines in function that would benefit from intervention.

Often, especially in the hip, motion is included as part of
clinical outcome scores (Holm et al. 2000). The ability to
obtain digital measures of motion over a distance (by
phone or internet) offers great promise for clinical re-
search (Holm et al. 2000). Jenny et al. demonstrated high
measurement accuracy at the knee using a smartphone
digital camera measurement (Jenny et al. 2016). In this
study, we have used a digital camera and secondarily
measured the angle on a desktop computer. Although
not utilized for this study, smartphone applications allow
for identical techniques to be used without the need for
transfer of the image to a desktop computer (Ferriero
et al. 2013; Milani et al. 2014). This may make digital
photographic measurements more clinically attractive
alternative to visual estimation or goniometry (Ferriero
et al. 2013; Milani et al. 2014).
This study does have some limitations. First, the limb

position used for each measurement by each investigator
was not identical so comparison of accuracy between
measurements relies on the accuracy of the motion
capture analysis. Prior studies have shown motion cap-
ture analysis to be highly accurate for joint motion mea-
surements making it ideal for use as a gold standard
(Charlton et al. 2015; Furtado et al. 2013) and our study
utilized arrays of reflective markers that were attached
directly to the bones and secured with cement to de-
crease the possibility of loosening (Chung and Ng 2012).
Hagio et al. used CT scans combined with infrared mo-
tion capture analysis (similar to this study) and showed
excellent accuracy (within 5 degrees) for hip motion
(Hagio et al. 2004). Second, motion capsule analysis
measures the angle formed by the two bones being
measured, which may not represent the “clinical” angle
at the joint made by the soft tissue (i.e. with the knee in
full extension [or 0°], the bones may be in slight hyper-
extension relative to each other). However, this reference
remained constant for all measurements by each group
allowing comparison between groups. Additionally,
other authors have cited radiographic measurement as
the “gold standard” which suffers from the same issues
(Lavernia et al. 2008). Third, for photographic measure-
ments, we did not measure the distance or angle of the
camera in relation to the joint being measured (i.e. no
reflective markers were placed onto the camera itself, no
use of a tripod or other apparatus). However, this lack of
standardization corresponds to the method that it would
be used clinically so it allows for better generalization of
our results. Fourth, the skin was not marked to identify
the optimal points of reference. Instead, each investiga-
tor made their own judgment regarding the boney land-
marks, in order to be more representative of the clinical
utility, which is limited by the amount of body fat,
muscle, and clothing obscuring landmarks (Naylor et al.
2011). Again, this will allow better generalization to

Table 4 Precision by technique for knee range of motion
(proportions of measurement errors within 10° or 5° of motion
capture analysis)

Visual Goniometer Photo

Knee Flexion (<10°) 92% 94% 90%

Knee Extension (<5°) 49% 50% 74%

Precision of measurements or the proportion of measurement errors that were
within 10° (for elbow flexion) or 5° (for elbow extension), defined as the
minimally clinically significant difference by the authors, of the reference
standard (motion capture analysis) for both knee motions

Russo et al. Journal of Experimental Orthopaedics  (2017) 4:29 Page 6 of 8



clinical practice. Fifth, our investigators included three
fellowship-trained orthopaedic surgeons and three
physical therapists with varied levels of experience. This
may have had an effect on the measurement accuracy
and reliability. Sixth, the clinical applicability of meas-
urement errors are not static across a range of motion.
An error of 5–10° at 100° knee flexion is less clinically
significant than that same error at full extension
(Ferriero et al. 2013). The definition of clinically signifi-
cant changes in motion (such as minimal clinically im-
portant difference [MCID]; minimal detectable change
[MDC]) or minimal acceptable motion (such as patient
acceptable symptom state [PASS]) for joint range of
motion is not well established within the literature.
Some suggest 6° be used for the lower extremity, while
others define clinical significance by a change greater
than 10% of the motion arc (Blonna et al. 2012; Boone
et al. 1978; Mehrholz et al. 2005; Roach et al. 2013;
Wheatley-Smith et al. 2013). However, for certain joints,
10% seems excessive (i.e. 14° for knee extension)
(Mehrholz et al. 2005; Roach et al. 2013; Wheatley-
Smith et al. 2013). The authors chose 10° as the MCID,
or clinically significant difference, for all measurements
with the exception of knee extension.

Conclusions
There was no clinically significant difference in measure-
ment accuracy between the three techniques for hip and
knee motion. Digital photography only showed higher
precision for two joint motions (hip abduction and knee
extension). Overall digital photography shows equivalent
accuracy and near-equivalent precision to visual estima-
tion and goniometry.

Acknowledgements
Luis F. Pulido, M.D., Robert A. Jack, M.D., Derek T. Bernstein, M.D., Brad Hollas,
DPT, Corbin Hedt, DPT, and Kyle Belski, DPT, for assisting with measurements.
Lucas Bizzaro, Amarani Rucoba, Mladen Milovancevic, Sangwoo Kim, Michael
Hogan, and Jonathan Gold for assisting with cadaver setup and motion
analysis setup/analysis.

Funding
No outside sources of funding were utilized. All funding was internally from
the Department of Orthopedics & Sports Medicine at Houston Methodist
Hospital.

Authors’ contributions
All authors read and approved the final manuscript.

Competing interests
The authors declare that they have no competing interests with the subject
of this paper. For full disclosure, all authors have listed their disclosures
below:
RRR, MBB, SKI, BJG, SH, JA, CL: None.
PCN: Research support [CeramTech; DJ Orthopaedics; Microport; Smith &
Nephew; Zimmer]; Board or committee member [International Society for
Technology in Arthroplasty; Knee Society]; Stock or stock options [Joint View,
LLC]; Editorial or governing board [Journal of Arthroplasty; Journal of Hip
Preservation Surgery]; Publishing royalties, financial or material support
[Springer]; IP Royalties [Stryker; Zimmer]; Paid consultant [Zimmer]; Other
financial or material support [Musculoskeletal Transplant Foundation].

JDH: Board or committee member [AAOS; American Orthopaedic Society for
Sports Medicine; Arthroscopy Association of North America]; Paid consultant
[Applied Biologics; NIA Magellan; Smith & Nephew]; Editorial or governing
board [Arthroscopy; Frontiers in Surgery]; Research support [DePuy, A Johnson
& Johnson Company]; Paid presenter or speaker [Ossur; Smith & Nephew];
Publishing royalties, financial or material support [SLACK Incorporated].
PCM: Editorial or governing board [Journal of Knee Surgery;
Orthobullets.com].

Publisher’s Note
Springer Nature remains neutral with regard to jurisdictional claims in
published maps and institutional affiliations.

Author details
1Department of Orthopedics & Sports Medicine, Houston Methodist Hospital,
6445 Main Street, Outpatient Center, Suite 2500, Houston, TX 77030, USA.
2Institute for Orthopaedic Research & Education (IORE), Houston, TX, USA.

Received: 16 May 2017 Accepted: 4 September 2017

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Russo et al. Journal of Experimental Orthopaedics  (2017) 4:29 Page 8 of 8


	Abstract
	Background
	Methods
	Results
	Conclusions

	Background
	Methods
	Cadaver & Motion Analysis Setup
	Measurement technique
	Statistical analysis

	Results
	Hip range of motion (flexion, abduction, internal rotation, external rotation)
	Knee ROM (flexion, extension)

	Discussion
	Conclusions
	Funding
	Authors’ contributions
	Competing interests
	Publisher’s Note
	Author details
	References