Chivers D et al. SA Orthop J 2019;18(3)
DOI 10.17159/2309-8309/2019/v18n3a5

South African Orthopaedic Journal 
http://journal.saoa.org.za

TRAUMASHOULDER AND ELBOW

Citation: Chivers D, Lambrechts A, Vrettos B, Dachs R, Roche S. Unrepaired rotator cuff tears following acromioplasty. SA Orthop J 2019;18(3):47-52. 
http://dx.doi.org/10.17159/2309-8309/2019/v18n3a5 

Editor: Prof LC Marais, University of KwaZulu-Natal, Durban, South Africa 

Received: September 2018  Accepted: May 2019  Published: August 2019

Copyright: © 2019 Chivers D, et al. This is an open-access article distributed under the terms of the Creative Commons Attribution Licence, which 
permits unrestricted use, distribution and reproduction in any medium, provided the original author and source are credited.

Funding: No financial remuneration was received by any of the authors for this study.

Conflict of interest: The authors declare that there is no conflict of interest regarding the publication of this paper.

Abstract

Background: The natural history of rotator cuff tears suggests that not all tears progress and small isolated rotator cuff tears might 
heal. To date there have been no long-term studies assessing the MRI changes of unrepaired full thickness supraspinatus tears after 
acromioplasty.

Methods: A database of patients from a single surgeon that have had acromioplasty without rotator cuff repair in the last five to 15 
years was reviewed. The number of shoulders examined in this study was 17. Patients all completed an Oxford score, Constant score 
and had an MRI to assess fatty infiltration and atrophy.

Results: Mean follow-up time 7.2 years (range, 5–13 years). The patients were divided into three groups depending on the size of 
the tear at time of surgery: C1 tears (<1 cm) n=5, C2 tears (1–1.9 cm) n=8, C3 tears (2–3 cm) n=4. In the C2 group, MRI evaluation 
showed there were two patients that had tears that had regressed in size (CI 1.4–36, 4). In the C3 group, MRI evaluation revealed that 
all (100%) of the rotator cuff tears had significant fatty infiltration and atrophy. There was no statistical difference between groups when 
assessing Oxford scores (p=0.75) and Constant scores (p=0.69). There was significant association between increase in tear size and 
fatty infiltration (p=0.028). A possible association was noted between increase in tear size and atrophy (p=0.054).

Conclusion: Patients had good long-term clinical outcomes irrespective of tear size. It showed that not all tears progressed to significant 
fatty change and atrophy. 

Level of evidence: Level 3

Key words: unrepaired, full thickness supraspinatus tear, acromioplasty

Unrepaired rotator cuff tears following acromioplasty
Chivers D1 , Lambrechts A2, Vrettos B3, Dachs R4 , Roche S5    
1 MBChB, MMed(UCT), FCS(SA)Orth; Orthopaedic consultant, Port Shepstone Hospital; Department Orthopaedic Surgery, University of Cape Town, 

Cape Town, South Africa
² MBChB, MMed(Orth); Orthopaedic surgeon, Constantiaberg Hospital, Cape Town;  University of Cape Town, Cape Town, South Africa 
³ MBChB, FCS(SA)Orth, FRCS; Honorary professor, Shoulder and Elbow unit, Groote Schuur Hospital, University of Cape Town, Cape Town, South Africa
4 MBChB, FCS(SA) Orth; Consultant, Shoulder and Elbow unit, Groote Schuur Hospital, University of Cape Town, Cape Town, South Africa 
5 MBChB, FCS(SA) Orth; Professor, Head of Shoulder and Elbow unit, Groote Schuur Hospital, University of Cape Town, Cape Town, South Africa

Corresponding author: Dr D Chivers, PO Box 306, Shelly Beach 4265, KwaZulu-Natal; email: davechivers78@gmail.com; cell: 082 903 7691

https://orcid.org/0000-0001-7896-9688
https://orcid.org/0000-0002-4394-6627


Page 48 Chivers D et al. SA Orthop J 2019;18(3)

Introduction

Impingement syndrome and its association with rotator cuff tears 
is well documented. The clinical outcome after acromioplasty has 
been well researched and the literature reports good long-term 
results. Debate, however, continues regarding the optimal and 
most cost-effective treatment of the older patient group with an 
associated rotator cuff tear, with studies reporting good functional 
outcomes without rotator cuff repair.1

Recent studies have assessed the structural changes of 
unrepaired rotator cuff tears; however, there has been little research 
into the long-term clinical outcomes and MRI changes in isolated 
full thickness tears of supraspinatus after acromioplasty.

The aim of this study was to evaluate the long-term clinical 
and structural outcomes of a cohort of patients with isolated full 
thickness tears of supraspinatus who underwent an acromioplasty 
without rotator cuff repair.

Methods and material

The cohort consisted of patients from a single surgeon database 
who had been operated on for symptomatic impingement syndrome 
without repair of a full thickness supraspinatus tear diagnosed at 
arthroscopy. Tears were categorised as C1 (less than 1 cm), C2 
(between 1 and 1.9 cm), and C3 (between 2 and 3 cm) according 
to the Snyder classification.2

All C1 and C2 rotator cuff tears at arthroscopy were noted to be 
within the rotator cable as postulated by Burkhart et al.3

All patients had failed conservative treatment, and on examination 
had full active abduction, forward elevation and external rotation, 
minimal weakness of supraspinatus and full strength of infraspinatus 
and subscapularis. 

Exclusion criteria were follow-up of less than five years, 
rheumatoid arthritis, diabetes, long-term corticosteroid use, and 
previous surgery to the shoulder.

Of the 64 patients contacted telephonically, 16 agreed to 
participate. The other 48 patients were either not contactable, were 
too ill, had relocated or had passed away.

We had 16 patients that met these criteria; of these 16 patients, 
there was one patient that had bilateral pathology, so the number 
of shoulders investigated was 17 (n=17).

Imaging

Patients did not receive an MRI on presentation to the primary 
surgeon as it was not clinically indicated at the time, but were 
assessed clinically and had X-ray confirmation of type 3 acromial 
morphology as described by Bigliani et al.2

On follow-up, all study participants had an MRI of both shoulders. 
The MRI images were assessed by an experienced musculoskeletal 
radiologist and a fellowship-trained shoulder surgeon who had no 
information regarding the patients’ clinical outcome.

Continuity or rupture was assessed on T2-weighted coronal 
imaging sequence. A tear was diagnosed if there was no continuity 
in the muscle fibres of the rotator cuff. 

The quality and quantity of the rotator cuff was assessed on 
parasagital T1-weighted turbospin echo images taken parallel to 
the glenohumeral joint.

Fatty infiltration was assessed as described by Goutallier et al.,5 
modified by Fuchs et al.6 for MRI.

Supraspinatus atrophy was determined using the tangent sign as 
described by Zanetti et al.7 

Clinical assessment

Clinical assessment was done according to a standardised 
technique using a handheld goniometer and dynamometer.

The Constant score 8 was recorded where a maximum of 100 
points could be obtained. Shoulder range of movement was 
measured using a handheld goniometer as described by Constant 
and Murley.8 Abduction strength was measured using a handheld 
dynamometer applied to the wrist. The arm was abducted in the 
scapular plane, elbow extended, and forearm pronated. Three 
readings were taken and the average of the three readings was 
recorded.

An Oxford score9 was completed by all patients examined, where 
a maximum score of 48 could be obtained.

Statistical methods

The data was analysed using Stata 13.0 (Statacorp LP, 4905 
Lakeway Drive, College Station, TX77845, USA). Categorical data 
between the groups was analysed using the chi-squared test or 
Fisher’s exact test as appropriate. Normality of continuous data 
was assessed using the Shapiro Wilk test. Normally distributed 
data was summarised using means and standard deviations, and 
compared using the Student’s t-test. Skewed data was summarised 
using medians and ranges, and groups compared using the Mann-
Whitney test. Statistical significance was set at p<0.05 and all tests 
were two-sided.

Results

There were 17 shoulders in 16 patients (nine females). Mean follow-
up was 7.2 years (range, 5–13 years). The mean age at surgery was 
65.8 years (range, 50–82 years) and the mean age at most recent 
follow-up was 73 years (range, 60–89 years).

The patients were divided into three groups depending on the 
size of the tear at time of arthroscopy. In this study, we had five C1 
tears, eight C2 tears and four C3 tears (Table I).

C1 tears (n=5)

The average age at surgery was 60.4 years (range, 49–75 years).
The average age of patients with C1 tears at most recent follow-up 
was 67.4 years (range, 60–82 years).

The median Constant score was 86 (range 83–96) and median 
Oxford score was 47 (range 46–48). 

Only one patient in the C1 tear group had significant fatty 
infiltration (grade IV) and a positive tangent sign indicating 
significant muscle atrophy.

C2 tears (n=8)

The average age at surgery was 65.3 years (range, 58–81 years).
The average age of patients with C2 tears at most recent follow-up 
was 76.7 years (range, 69–81 years). The mean Constant score was 
72.3 (range 62–98) and mean Oxford score was 45 (range 42–48).

Only one patient in this group had significant fatty infiltration 
(grade IV).

On MRI two tears in the group had regressed in size and were 
reported as partial thickness tears.

Table I: Comparison of tear size and age at surgery/follow-up

C1 tears C2 tears C3 tears

Age at surgery
(range years)

60.4 years 
(49–75)

65 years 
(58–71)

69 years 
(59–73)

Age at follow-up
(range years)

67.4 years 
(60–82)

76.7years 
(69–81)

76.2 years 
(72–83)



Page 49Chivers D et al. SA Orthop J 2019;18(3)

C3 tears (n=4)

The average age at surgery was 69 years (range, 59–73 years) The 
average age of patients with C3 tears at most recent follow-up was 
76.2 years (range, 72–83 years). The mean Constant score was 
72.3 (range 65–98). The mean Oxford score was 45 (range, 42–48).

On MRI all four patients had stage 4 fatty infiltration and a positive 
tangent sign.

Comparison of clinical parameters 

There was no significant difference between the three groups 
when comparing abduction strength: Oneway ANOVA p=0.31); 
internal rotation (Kruskall-Wallis chi-squared p=0.8); and external 
rotation Kruskall-Wallis chi-squared p=0.7). There was, however, a 
statistical difference in range of motion when comparing forward 
flexion (Oneway ANOVA p=0.04); and lateral elevation (Oneway 
ANOVA p=0.04) between the three categories of tears  (Table II).

There was no significant difference in Oxford (Kruskall-Wallis chi-
squared  p=0.75) and Constant scores (Kruskall-Wallis chi-squared  
p=0.69) when comparing the three groups (Table III).

Comparison of MRI findings

When assessing the fatty infiltration, atrophy and tear size, the C3 
tears did have a statistically higher chance of having fatty infiltration 
(Pearson chi-squared p=0.028). The C3 tears also had significant 
atrophy (Pearson chi-squared p=0.032), as indicated by the tangent 
sign (Tables IV and V).

In the C2 group, two of the full thickness tears were now reported 
as being partial thickness tears and smaller in dimension than 
reported on initial surgical assessment. This equates to 12% of the 
total number of shoulders assessed (CI: 1.4–36.4). 

The association between increasing age and atrophy Wilcoxon 
rank-sum (p=0.05) was also noted to be significant, as well as age 
and fatty infiltration Wilcoxon rank-sum (p=0.008). 

The comparison between fatty infiltration stages and abduction 
strength revealed that stage 0 (n=2) had mean strength of 9.4 kg 
(4.8 kg–14.0 kg); stage 1 (n=6) abduction strength mean 16.0 kg 
(range 6.6 kg – 22.kg); stage 2 (n=4) mean abduction strength  
10.4 kg (range 5.3 kg – 15.3 kg); stage 3 (n=1) abduction strength 
3.5 kg; and the stage 4 (n=4) abduction strength was 4.2 kg (range 
1.4 kg – 8.4 kg). There was a statistically significant association 
between muscle atrophy and abduction strength, Spearman’s 
p=0.009 (Table VI).

Table II: Table showing the clinical parameters for the three categories of tear (based on tear size at surgery) (n=17)

C1 tears C2 tears C3 tears p-value

Mean abduction in kg (SD) 11.1 (7.5) 11.9 (7.1) 6.4 (3.3) *p=0.4

Mean forward flexion 
Degrees (SD)

168.2 (7.5) 170 (7.8) 157.2 (7.2) *p=0.04

Mean lateral elevation 
Degrees (SD)

171 (4.3) 170.8 (5.2) 162.8 (5.9) *p=0.04

Median external rotation average (range) 
*** see key

  4 (2–5) 5 (5–5) 4.5 (3–5) **p=0.7

Median internal rotation
Average (range)
* see key

5 (5–6) 5 (5–6) 5 (5–6) **p=0.8

*Means were compared between the three categories using ANOVA
**Medians were compared between the three categories using the Mann-Whitney U test
***External rotation: 1) hand behind head, elbow forward; 2) hand behind head, elbow back; 3) hand to top of head, elbow forward; 4) hand to top of head, elbow back;  
     5) full elevation
*** Internal rotation: 1) lateral thigh; 2) buttock; 3) lumbosacral junction; 4) waist; 5) T12 vertebra; 6) interscapular T7

Table III: Comparison of median Oxford and median Constant scores by tear size (n=17)

C1 C2 C3 p-value

Median Oxford score (range) 47 (25–48) 45 (37–48) 45 (42–48) p=0.75

Median Constant score (range) 86 (52–96) 72.3 (78–98) 72.3 (65–86) p=0.69

Medians were compared between the three groups using Kruskall-Wallis chi-squared test.

Table IV:  Comparison of tear size and proportion of muscle with fatty 
infiltration at follow-up, n=17

  Stage 0 
(%)

Stage 1 
(%)

Stage 2 
(%)

Stage 3 
(%)

Stage 4 
(%)

C1 tears 40.0 20.0 20.0 20.0 0.0

C2 tears 0.0 62.0 25.0 0.0 12.5

C3 tears 0.0 0.0 0.0 0.0 100.0

(Fisher’s exact test, p=0.028)

Table V: Comparison of tear size and proportion atrophy

Tangent sign negative 
(%) 

Tangent sign positive 
(%)

C1 tear 80.0 20.0

C2 tear 75.0 25.0

C3 tear 0.0 100.0

(Fisher’s exact test, p=0.032)

Table VI: Comparison of fatty infiltration and abduction strength

Fatty infiltration stage  
(Goutallier5)                 

Stage 0 
(n=2)

Stage 1
(n=6)

Stage 2
(n=4)

Stage 3
(n=1)

Stage 4
(n=4)

Mean abduction 
strength kg 
(range kg)

9.4 kg
(4.8–14.0)

16.0 kg
(6.6–22)

10.4 kg
(5.3–15.3)

3.5 kg 4.2 kg
(1.4–8.4)

Spearman’s rho, p=0.009



Page 50 Chivers D et al. SA Orthop J 2019;18(3)

Discussion

The reason for progression of isolated tears of the rotator cuff in 
impingement syndrome is multifactorial. Understanding the natural 
history of rotator cuff tears is important when evaluating whether 
acromioplasty has any effect on rotator cuff tear progression.

The article by Melis et al.10 that looked at the natural history of 
fatty infiltration and atrophy in tears of the supraspinatus muscle, 
suggests that tears progressed to stage 2 fatty infiltration by four 
years and severe fatty infiltration (stage 3/4) by six years. Traumatic 
tears progressed faster, and fatty infiltration of at least stage 2 was 
present at three years. Muscle atrophy was noted in all tear types 
to occur at an average of 4.5 years post-symptomatic onset. We did 
not see this progression in atrophy and fatty infiltration in the small 
isolated tears of the rotator cuff in our study. 

This assumption that all tears progress is now being disputed. 
Fucentese et al. and Maman et al.11,12 have both shown that small 
tears may get smaller and may even heal if they are isolated tears. 
The progression of isolated rotator cuff tears in the context of 
impingement syndrome following acromioplasty and subacromial 
decompression has not yet been quantified. In this study we 
confirmed that small tears may appear to heal on MRI, and our 
figure of 12% is in keeping with the literature of 8–9%11,12 healing 
rates in patients without impingement syndrome.

The aetiology of rotator cuff tears in impingement syndrome can 
be attributed to extrinsic, intrinsic and genetic factors. 

Acromial morphology as an extrinsic cause for rotator cuff tears 
and their progression is well described. A recent article13 looking 
at relationship of radiographic acromial characteristics and rotator 
cuff diseases showed that the presence of an acromial spur 
is highly associated with a rotator cuff tears in the symptomatic 
and asymptomatic patient. In Bigliani’s4 description of acromial 
morphology, a type 3 acromion has a higher incidence of rotator 
cuff tears. However, in the Maman et al.12 review there was no 
statistical correlation between acromial spur and rotator cuff tears. 
The presence of an acromial spur or abnormal acromial morphology 
does not always correlate with clinical impingement symptoms. 
Therefore, there has been suggestion that intrinsic causes may be 
responsible for symptomatic impingement syndrome and rotator 
cuff degeneration. 

The intrinsic theories of cuff degeneration and tears suggest 
that there is a zone of hypovascularity and relative hypoxia that 
may lead to apoptosis and rotator cuff damage.14-16 This abnormal 
cuff is now dysfunctional which results in an uncentred high riding 
humeral head which causes the acromial morphological changes.

Articular-sided tears are also more common than bursal-sided 
tears, which may suggest intrinsic pathology. Ogata and Uhthoff17 
showed that cuff degeneration and tears progress with age but 
acromial degeneration did not. Hyvönen et al.18 reported that open 
acromioplasty did not prevent tear progression in impingement 
syndrome as they found that tears may appear after acromioplasty 
in the shoulder where no tear was present at time of surgery.

There have also been studies looking at surgical versus non-
surgical or structured exercise regimens for the treatment of 
impingement syndrome, which have shown that long-term 
outcomes are similar when comparing acromioplasty versus non-
surgical interventions.19-21

A randomised controlled study performed by Kukkonen et 
al.1 demonstrated that operative treatment is no better than 
conservative treatment in the management of supraspinatus tears 
in impingement syndrome. Follow-up was one year in this study. 
Kukkonen suggests that conservative treatment be the primary 
method of treatment.1

These findings may support the theories that cuff degeneration is 
due to intrinsic mechanisms, and surgery may not alter the natural 
history of rotator cuff pathology in impingement syndrome.

There has been evidence to suggest that rotator cuff pathologies 
and symptoms may be genetic and there is a subset of patients 
that have increased genetic susceptibility in developing tears and 
subsequent tear progression. Harvie et al.22 has shown that siblings 
have a 2.42 relative risk of developing full thickness rotator cuff 
tears and a 4.65 relative risk of the tears being symptomatic. 

The variability noted in the healing response of the rotator cuff 
in a cross-section of patients is now being attributed to alterations 
in genetic expression. Genetic expression which controls cellular, 
vascular and extracellular matrix formation is controlled by biological 
and local mechanical factors at the tendon edge. It is postulated 
that surgical repair alters the biological environment at the tendon 
edge and therefore modulates gene expression.23 Repair of the 
rotator cuff in sheep and rabbits however, has not shown to reverse 
fatty infiltration, but early repair may result in partial recovery 
according to Kang and Gupta,15 and therefore early repair in the 
traumatic full thickness tears and early presenting degenerative 
tears is still of value. Established stage 3 and 4 fatty infiltration and 
atrophy; however, was not reversible with surgical repair.10,11,24 The 
genetic expression of protein degradation genes which results in 
proteolysis and muscle degeneration is up-regulated in massive 
rotator cuff tears.25 This may explain the association with larger 
rotator cuff tears and significant fatty infiltration and atrophy. 

The pathophysiology of fatty degeneration is related to unloading 
of the muscle due to its loss of insertion into bone; this result in 
changes in physiological structure and function of the muscle and 
ultimately atrophy.24,26 This unloading of the muscle may ultimately 
be the reason that the larger tears progressed with respect to fatty 
changes and atrophy. In smaller tears there is less unloading of the 
muscle and therefore less propensity to atrophy and degeneration.

The rotator crescent and rotator cable theory by Burkhart et al.3 

describes two distinct areas of the rotator cuff with different load 
characteristics. The rotator cable which is relatively thicker supports 
more load and shields the crescent area. Burkhart hypothesised 
that as people age there is progressive thinning of this relatively 
avascular crescent zone. This hypothesis has been recently 
supported by Kim et al.27 who have shown that most degenerative 
tears occur in a more posterior location near the junction of the 
infraspinatus and supraspinatus and not anteriorly as initially 
thought. The biomechanical relevance of this tear position is that 
the cable is still intact, which has been shown in biomechanical 
studies by Meisha et al.28 to be the primary load-bearing structure 
in the supraspinatus. Therefore, tear position and not only tear size 
are important to consider when assessing the clinical effects of 
rotator cuff tears. In this study it was noted at arthroscopy that all 
the C1 and C2 tears were within this cable, hence the good clinical 
parameters achieved by the study participants.

The fibrogenic and adipogenic progenitor cells in muscle that are 
responsible for fatty change are normally inactive in healthy muscle. 
The activation and differentiation of these cells has been found to 
be initiated by ageing, oxidative stress and muscle degeneration. 
This fibroproliferative response in the older patient negatively 
affects the rotator cuff muscle’s ability to regenenerate.24,26 The 
age of the patient is therefore important in assessing the healing 
capability of a rotator cuff tear and is of relevance in this study as 
we had an elderly patient cohort.

In this study it was noted that isolated small full thickness tears 
had the best outcomes when assessing the clinical parameters 
of Constant and Oxford scores. The small tears also had better 
structural outcomes, whereas the larger tears did considerably 



Page 51Chivers D et al. SA Orthop J 2019;18(3)

worse structurally but not clinically. Norlin and Adolfsson25 
concluded that small full thickness tears do well post acromioplasty 
at 10 to 13 years post-surgery, which correlates with our findings. 

 Ozaki et al.30 showed that 38% of cadavers over 60 years had 
cuff tears; this figure rose to 80% in cadavers over 90 years of 
age, where most of these tears are asymptomatic. The prevalence 
of asymptomatic full thickness tears in the population aged  
40–60 years is 4% and patients over 60 years is 24%, according 
to an MRI study by Sher et al.31 From this data it can be noted that 
rotator cuff tears are relatively common and that not all patients 
with cuff tears present with a loss in function or pain, which might 
explain the good clinical outcomes we found in this age group of 
patients.

Weaknesses of this study include poor patient follow-up, and low 
numbers available for this study which was due to the fact that 11 
patients had died, seven were too ill, eight patients refused, five 
had moved and 15 were not contactable. The patients were also 
pre-selected as having good functional capacity prior to surgery 
which was one of the reasons not to repair the rotator cuff. No pre-
operative MRI was done to evaluate progression of fatty infiltration 
and atrophy with current MRI findings at follow-up.

Conclusions

Currently this is the only long-term MRI study of patients with full 
thickness supraspinatus tears that were not repaired at the time of 
acromioplasty.

This small cohort of patients had good long-term clinical 
outcomes irrespective of tear size. It also showed that not all 
tears progressed to significant fatty change and atrophy in the 
long term. Full thickness tears may progress or heal despite 
surgical intervention. The process of muscle regeneration or 
degeneration in muscles with tears seems to be more influenced 
by local biological factors, genetic expression and tear location, 
and therefore acromioplasty in isolation does not influence rotator 
cuff tear healing. The recommendation that can be made from this 
study is that small tears within the cable do not need to be fixed 
and in this elderly population this would facilitate less rehabilitation 
and earlier mobilisation. Larger C3 tears, upon discussion with the 
patient, can be treated without repair and with shorter rehabilitation 
time if patients are willing to accept some functional loss.

Ethics statement 
This study received approval by the Human Research Ethics Committee, University of 
Cape Town: ref number 183/2013. 

Declarations 
The authors declare authorship of this article and that they have followed sound 
scientific research practice. This research is original and does not transgress 
plagiarism policies.

Author contributions 
DC was the primary author and researcher. AL was the primary surgeon in all the cases 
mentioned and provided the patient data base. BV reviewed the written submission. 
RD contributed in data collection and research. SR provided the original idea and 
assisted in writing the article.

ORCID
D Chivers  http://orcid.org/0000-0001-7896-9688
R Dachs  http://orcid.org/0000-0002-4394-6627

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