Panacea Journal of Medical Sciences 2021;11(3):573–578

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Panacea Journal of Medical Sciences

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Original Research Article

Clinical profile of patients with interstitial lung disease in connective tissue
disorders – An original study

Abhishek Nuchin1, Girija Nair1, Balaji Tuppekar1, Shahid Patel1,*, Abhay Uppe1

1Dept. of Pulmonary Medicine, D. Y. Patil Medical College, Navi Mumbai, Maharashtra, India
 

 

A R T I C L E I N F O

Article history:
Received 17-03-2021
Accepted 13-04-2021
Available online 24-11-2021

Keywords:
Interstitial Lung Diseases (ILD’s).
Declaration of Helsinki (DoH)

A B S T R A C T

Background and Objectives: Interstitial Lung Diseases (ILD’s) are a heterogeneous collection of more
than one distinct lung disorder which is grouped together owing to their clinical, radiographic, and
pathologic features they share in common. Connective tissue disease may be an underlying cause of
Interstitial Lung Disease, and often patients may not present with a pre-existing diagnosis. The aim of
this study is to study the clinical profile of these patients including physiologic testing and have a better
understanding of CTD-ILD in the Indian scenario.
Material and Methods: This was a prospective, observational study conducted at D.Y.Patil Hospital
and Medical Research Center, Navi Mumbai, India, between a two year period from December 2017-
December 2019. A total of 50 patients of age 18 and above with clinical diagnosis of connective tissue
disease and interstitial lung disease were included in the study. Clinical profile of the study participants was
studied based on presenting symptomatology and history, chest x-ray and HRCT findings, microbiological
aspirates in sputum, pulmonary function testing, 6MWT and 2D-Echo findings. The convenient sampling
method was used for data collection and distribution of responses was examined using frequencies and
percentages. Further analysis was done using appropriate statistical tests (Chi-square test, t-test) were used
to compare responses between various subgroups.
Results: Majority of the study subjects were females (56%) as compared to males (44%). Mean age
of the study participants was 58.08 ± 11.92 years, ranging from 27 years to 81 yrs. Majority were of
the age group 61-70 years(21%), followed by 51-60 years(16%) respectively. All the participants (100%)
presented with dyspnea, more than half of them 28(56%) had cough and over a quarter of them had joint
pain 15(30%).17(34%) symptomatic patients of CTD were also diagnosed as ILD. 33(66%) of patients
with ILD had underlying CTD.
66% patients of ILD had underlying Connective Tissue Disease. UIP pattern was the predominant in 88%
of RA-ILD and NSIP pattern was predominant in other CTD-ILD. Restrictive abnormality on PFT with
reduced DLCO was observed in all patients with raised pulmonary artery pressure in 70% patients.
During the 6-minute walk test, 64% of patients walked <350 meters and significantly reduced SpO2 levels
were observed after exercise P<0.05.
Conclusion: Our study showed a high frequency of lung involvement in the form of respiratory symptoms,
radiological patterns, echocardiography, and changes in pulmonary function and exercise testing in patients
with ILD diagnosed to have underlying CTD. Since lung involvement in CTD is associated with significant
morbidity and mortality, a high index of suspicion in ILD patients with underlying connective tissue disease
will help in early diagnosis and treatment of CTD-ILD which is associated with a better prognosis compared
to other ILD’s. Further studies with a larger sample size and regular patient follow up are required for a
better understanding of CTD-ILD in the Indian scenario.

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https://doi.org/10.18231/j.pjms.2021.113
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574 Nuchin et al. / Panacea Journal of Medical Sciences 2021;11(3):573–578

1. Introduction

ILD refers to a heterogeneous collection of lung disorders
that tend to be grouped together since they share clinical,
radiographic, and pathologic features. These disorders
are sometimes called diffuse parenchymal lung disease
(DPLD). Treatments may vary considerably depending on
the diagnosis hence a structured approach.

Patients usually present with symptoms cough and
dyspnoea on exertion. A detailed history regarding presence
of respiratory symptoms with another underlying disease
is important. eg. vasculitides, sarcoidosis, amyloidosis,
glycogen storage disorders, GERD may all present with
persistent cough. History of smoking, environmental
exposure and familial disease must be documented.

A careful physical examination usually reveals Velcro
crepitation’s or crackles. Systemic features of underlying
disease may also be present. A review of laboratory
data, physiologic studies, radiography, bronchoalveolar
lavage and in some cases pathologic tissue obtained from
lung biopsy is essential. Multidisciplinary approach is an
important part of this process and can have a significant
impact on diagnostic and management decisions. 1

Distinguishing those patients who have a known cause
for their ILD (e.g., connective tissue disease, occupational
or environmental exposure, or drug toxicity) from those
who do not (e.g., IPF, sarcoidosis) is an important step.
Connective tissue disease may be an underlying cause
of interstitial lung disease, and patients may sometime
present with a pre-existing diagnosis. However, most will
not and it is important to bring to clinical attention any
associated or underlying autoimmune disease as soon as
the onset of ILD is diagnosed by the pulmonologist. In
some cases, nonspecific symptoms such as night sweats,
fever, fatigue, or weight loss may suggest an underlying
inflammatory condition. In others, a detailed history and
clinical examination of systems aid in the diagnosis of an
underlying connective tissue disorder.

For example, careful questioning regarding skin related
symptoms may lead to the diagnosis of dermatomyositis
as demonstrated by Gottron’s papules, a heliotrope rash or
“mechanic’s hands,” all of which may go unnoticed. Patients
with underlying systemic sclerosis (scleroderma) may give
a history of skin tightness and telangiectasias, raynaud’s
phenomenon, or digital pitting and skin thickening. Papular
eruptions, lupus pernio, and erythema nodosum may be seen
in sarcoidosis. 2 Patients with systemic lupus erythematosus
(SLE) may present with malar rash, photosensitivity skin
reactions, or hair loss.

A detailed review of systems may uncover sequelae of
longstanding ILD. In patients with advanced fibrotic lung
disease and hypoxemia symptoms like increasing oedema,
syncopal events or exertional chest discomfort may indicate

* Corresponding author.
E-mail address: patel_shahid@hotmail.com (S. Patel).

core pulmonale and pulmonary hypertension.
The lung is a frequent target of autoimmune-mediated

injury in patients with connective tissue disorders due
to abundance of connective tissue and blood supply. All
compartments of the lung can be potentially affected
including airways, lung parenchyma, vasculature and
pleura. They can be affected in various combinations and
degrees based on the underlying connective tissue disorder
and are a significant cause of morbidity and mortality. 3

There are very few Indian studies assessing the clinical
profile of patients with connective tissue disorders in ILD
based on physiologic testing. This study aims to assess the
clinical profile of patients with connective tissue disorder
related ILD based on spirometry, lung volumes, 6MWT,
sputum culture and diffusing capacity and help understand
the disease better in the Indian scenario.

2. Materials and Methods

This study documents were reviewed and approved by the
Institutional Ethics Committee (IEC) of D.Y.Patil Hospital
(Navi Mumbai, Maharashtra, India), and was conducted in
adherence to good clinical practice (GCP) guidelines and
Declaration of Helsinki (DoH).

This was a prospective, observational study conducted
between a two-year period from December 2017- December
2019. A total of 50 patients of age 18 and above with clinical
diagnosis of connective tissue disease and interstitial lung
disease were included in the study from the in-patient as
well as outpatient setting. Patients below the age of 18years
with only connective tissue disease or only interstitial lung
disease were excluded from the study.

After taking written informed consent from each patient,
they were provided with a patient information sheet which
included personal data, presenting symptoms and past
history, HRCT Thorax, PFT, Sputum culture and 2-D Echo
findings and performance on 6-minute walk test.

The convenient sampling method was used for data
collection and distribution of responses was examined using
frequencies and percentages. Further analysis was done
using appropriate statistical tests (Chi-square test, t-test)
were used to compare responses between various subgroups.

3. Results

Majority of the study subjects were females (56%)
as compared to males (44%). Mean age of the study
participants was 58.08 ± 11.92 years, ranging from 27
years to 81 yrs. All the participants (100%) presented with
breathlessness, more than half of them 28 (56%) had cough
and over a quarter of them had joint pain 15 (30%), only
17 (34%) patients had initial involvement of others systems
that is 15 (30%) Patients had joint pain and 2 patients (4%)
presented with skin tightness. (Table 1)



Nuchin et al. / Panacea Journal of Medical Sciences 2021;11(3):573–578 575

Majority were of the age group 61-70 years, followed
by 51-60 years respectively. Nearly half of the study
participants 21 (42%) had history of hypertension, 13 (26%)
had diabetes mellitus. 44 (88%) participants did not have
smoking history. 6 (50%) participants who were smokers
had 1 pack per year history of smoking.

Majority of the study participants were house wives
22(44%), followed by teachers 8(16%), clerks 7(14%).
Number of patients with CTD presenting with symptoms
and diagnosed as ILD were 17(34%) and number of patients
of ILD diagnosed as CTD (connective tissue disease) were
33(66%) (Table 2). In case of chest x-ray findings, reticular
opacities which are predominantly observed seen in lower
zones in 47/50 cases (94%). More than two- thirds of the
participants showed bilateral lower zone reticular opacities
43(86%) (Table 3).

Among the participants, 17 had RA. Among those
patients 15 had UIP pattern and 2 had NSIP pattern on
HRCT. Out of 9 patients of systemic sclerosis 4 had UIP
pattern and 5 had NSIP pattern. NSIP was predominant
in the remainder of CT-ILD participants (Tables 4 and 5).
Among the study participants; only 3(6%) patients reported
a sputum culture growth. Pseudomonas was cultured in
the sputum of patients with polymyositis ILD and two
patients with scleroderma ILD had sputum culture positive
for staphylococcus.

All the participants showed the restriction pattern on
FVC and reduced DLCO. Among the study participants
27 (54%) had mild restriction, 18 (36%) had moderate
restriction and 5 patients had severe restriction. All
study subjects (100%) had reduced DLCO with a
mean of 54.22ml/min/mmHg. The lowest value was 18
ml/min/mmHg in a patient with systemic sclerosis with ILD
and highest value of 78ml/min/mmHg in a patient with RA-
ILD. 23 (46%) patients had moderately reduced DLCO,
20(40%) patients had mildly reduced DLCO and severely
reduced in 7(14%) of patients. However, nearly 43(86%) of
the participants showed normal FEV1/FVC ratio. (Tables 6,
7 and 8).

35 (70%) participants showed increased pulmonary
artery pressure. Mean pressure of 33.76 with a maximum
PASP of 65 and minimum PASP of 18. Among the
participants who had pulmonary hypertension (70%), 50%
had mild, 14% had moderate and 6% had severe pulmonary
hypertension (Table 9 ). Only 4 (8%) of the participants
had mild dilation of the RA/ RV and rest did not show
any such findings. Nearly 49 (98%) of the participants had
a normal LV Ejection Fraction (LVEF) on 2D echo. The
RA/ RV dilation was observed more among the moderate
and severely FVC categories when compared to others, this
trend was found to be statistically significant (P<0.05). The
involvement of RA/ RV dilatation was significantly more
among the participants who had severely reduced FEV1 (30-
50% of predicted) in restrictive lung disease when compared

to another group of mildly reduced FEV1 (50-79% of
predicted).

In case of 6-minute walk test; there was a significant
difference in pulse rate and SpO2 levels observed
between pretest and posttest measurements. Majority of the
participants 19 (38%) walked 250- 349 meters on 6 min
walk test, followed by 13 (26%) who could only walk 150-
249 meters. (Tables 10 and 11)

Table 1: Distribution of subjects based on frequency of symptoms
encountered

Symptoms Number (n=50) Percent
Breathlessness 50 100
Cough 28 56
Joint pain 15 30
fever 5 10
Tightness of skin 2 4

Table 2: Diagnosis of CT-ILD
Diagnosis of CT ILD Total Percentage
CTD diagnosed to have ILD 17 34%
ILD diagnosed to have CTD 33 66%
Total 50 100%

Table 3: Chest X-Ray Findings
Chest X-Ray Findings Number Percent
Bilateral lower zone reticular
opacities

43 86

Bilateral lower zone opacities with
bronchiectasis

2 4

Bilateral lower zone nodular
opacities

2 4

Upper zone opacities 3 6
Total 50 100

Table 4: HRCT findings
HRCT findings Number Percent
Non-specific interstitial pneumonia 23 46
Usual interstitial pneumonia 27 54
Total 50 100

4. Discussion

As discussed earlier connective tissue diseases encompass
a wide range of heterogeneous disorders where lung
involvement causes significant morbidity and mortality.
Even though the pathogenesis of connective-tissue diseases
is unknown, the role of autoimmunity in ILD associated
with connective-tissue disorders is well established. 4

Paolo Spagnolo, Jean-François Cordier, Vincent Cottin 5

concluded that RA affects approximately 1% of the



576 Nuchin et al. / Panacea Journal of Medical Sciences 2021;11(3):573–578

Table 5: HRCT findings with UIP and NSIP
CT –ILD UIP NSIP
RA 15 2
Systemic sclerosis 4 5
Scleroderma 3 4
Sarcoidosis 1 3
SLE 1 2
Polymyositis /DM 1 4
MCTD 2 3
Total 27 23

Table 6: FVC and DLCO
Characteristics Number Percent
FVC < 80% (Restriction pattern) 50 100
DLCO < 80 reduced 50 100

Table 7: FVC
FVC (Restriction) Total Percentage
Mild 27 54%
Moderate 18 36%
Severe 5 10%
Total 50 100%

Table 8: DLCO grading
DLCO grading Number Percentage
Mild (79-60%) 20 40
Moderate (59-40%) 23 46
Severe (<40%) 7 14
Total 50 100

Table 9: PASP grading
PASP grading Number Percentage
Mild (26-40) 25 50
Moderate (40-55) 7 14
Severe (>55) 3 6
Total 35 70

population worldwide, and women are twice as likely as
men to be affected, with the peak incidence being observed
between the fourth and sixth decade. Majority in our study
were females (56%) as compared to males (44%). Mean age
of the study participants was 58.08 ± 11.92 years, ranging
from 27 years to 81 yrs. Majority were of the age group
61-70 years (21 patients-42%), followed by 51-60 years (16
patients-32%).

As described by Yang, 6 symptoms considered for
diagnosis of ILD-CTDs were dry cough, wheezing, and
chest tightness and velcro-like rales that can be heard at the
lung bases bilaterally, and clubbing.

Patients may also present with joint pain, dry eyes/mouth
dry, Raynaud phenomenon, central muscle weakness,
joint swelling deformation, long-term healing of oral
ulcers, morning stiffness, repeated unexplained fever, skin Ta

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Nuchin et al. / Panacea Journal of Medical Sciences 2021;11(3):573–578 577

Table 11: Distance walked
Distance walked 6-mwt Number Percent
> 350mts 18 36
250- 349mts 19 38
150- 249mts 13 26
Total 50 100

thickening cracking, esophageal reflux.
E. Bodolay, Z. Szekanecz 7 studied ILD with MCTD

also described 80% of the study group to have complaints
of breathlessness the predominant symptom. ILD is a
diffuse parenchymal lung disease, which may be secondary
to a variety of occupational or environmental exposures
including smoking, and can complicate multiple rheumatic
or connective tissue diseases (CTDs) as described by
Castelino et al. 8 Majority of the participants in our study
were exposed to chulha (biofuel) 18(36%), followed by
11(22%) who gave history of smoking (beedi/cigarette).

In this study rheumatoid arthritis has higher frequency
which comprises 34%, 18% had systemic sclerosis, 14%
had scleroderma, polymyositis and MCTD constituted
10% each and sarcoidosis and SLE constituted 8% and
6% respectively. Castelino et al. 8 observed frequency of
connective tissue disorder associated with ILD was 45%
in case of systemic sclerosis and 20-30% with rheumatoid
arthritis. In this study rheumatoid arthritis has higher
frequency of 34%, followed by 18% in systemic sclerosis,
14% in scleroderma, polymyositis and MCTD constituted
10% each and sarcoidosis and SLE constituted 8% and 6%
respectively.

E. Bodolay, Z. Szekanecz 103 describes 96 ILD-CTD
patients with chest X-rays showing abnormalities consisting
of small irregular opacities predominantly in the bases and
middle regions in 87/96 cases (90.6%). In this study 96 out
of 144 MCTD patients (66.6%) had active ILD, 75 of this
group (78.1%) showed ground glass opacity, 21 patients
(21.8%) ground glass opacity with mild fibrosis with HRCT.

E.J Kim et al in their study showed a definite usual
interstitial pneumonia pattern in 20 (24%), likely NSIP in
19 (23%) and indeterminate in 43 (52%) out of 82 patients
with RA- ILD. 9 In a study of 63 patients with rheumatoid
lung disease conducted by David A. Lynch, MB, 26 had a
CT pattern suggestive of UIP, 19 had a pattern of NSIP. 10

Bouros D, Wells AU, Nicholson AG, et al. 11 reported the
most frequent histopathologic pattern in systemic sclerosis
was NSIP, observed in 62 of 80 patients (77.5%); NSIP was
subcategorized as cellular NSIP (15/62, 24%) and fibrotic
NSIP (47/62, 76%). Patients with UIP (n = 6) and those with
end-stage lung (n = 6) were grouped together, making up 12
of 80 patients (15%).

In our study participants, opacities were predominantly
observed in lower zones in (94%), reticular opacities in
86%, nodular opacities in 4% of patients and reticular
opacities with bronchiectasis in 4%. 27 (54%) had Usual

Interstitial Pneumonia (UIP) and the rest 23 (46%) had non-
specific interstitial pneumonia (NSIP). Among 17 patients
of RA, 15 had UIP pattern and 2 had NSIP pattern; of the 9
patients of systemic sclerosis 4 had UIP pattern and 5 had
NSIP pattern. In the remainder of the CT-ILD participants
NSIP pattern was predominant.

Among our study participants whose sputum was tested
for culture characteristics, only 3 (6%) showed growth and
rest 47(94%) did not show any on culture. Among 3 patients
who showed growth in sputum 2 of them had bronchiectatic
changes in which 1 patient grew Pseudomonas and another
grew Staph Aureus.

Pulmonary function testing of all participants showed a
restrictive pattern on FVC and reduced DLCO. 7 (14%)
of participants had obstruction on PFT with restriction.
Minimum FVC was 42% of predicted and maximum
FVC of 78% of predicted. Among our study participants
27 (54%) had mild restriction, 18 (36%) had moderate
restriction and 5 patients had severe restriction. All study
subjects (100%) had reduced DLCO with a mean of
54.22ml/min/mmHg.

In our study, echocardiography of 35 (70%) participants
showed increased pulmonary artery pressure with the rest
having normal pressures. Mean pressure of 33.76 with
max PASP of 65 and minimum PASP of 18. Among
the participants who had pulmonary hypertension (70% of
patients) 50% had mild, 14% had moderate and 6% had
severe pulmonary hypertension. Among the 35 patients 4
patients had dilated right atrium and right ventricle. Bouros
D, Wells AU, Nicholson AG, et al. 11 in their study of
systemic sclerosis reported that pulmonary hypertension
was evident on echocardiography in 12 of 56 participants
(21%); in 44 patients, echocardiographic findings were
normal; and in the remaining 18 patients, there was no
evidence of pulmonary hypertension.

Chang et al. 12 studied 619 patients of scleroderma
with ILD and observed mild to moderate pulmonary
hypertension in 154 patients (24.9%), and severe pulmonary
hypertension in 77 patients (12.4%). Of the 36.3% with an
elevated RVSP measurement, the mean RVSP was 53.3 ±
16.4 mm Hg.

RA/RV dilatation was significantly present among our
participants who had severely reduced FEV1 (30-50% of
predicted) when compared to another group of mildly
reduced FEV1 (50-79% of predicted). The RA/ RV dilation
was observed more among the moderate and severely FVC
categories when compared to others, this trend was found to
be statistically significant.

The six-minute walk test (6MWT) provides powerful
prognostic information and has recently been applied
to ILD. As compared to resting lung function tests,
desaturation to 88% in a baseline 6MWT, either during 13

or at the end of the test, 14 has emerged as a much more
powerful predictor of mortality. In a study of patients with



578 Nuchin et al. / Panacea Journal of Medical Sciences 2021;11(3):573–578

IPF, desaturation to 88% or below was associated with a
median survival of 3.21 years compared with a median
survival of 6.63 years in those who did not desaturate. 1,5,6

In the present study There was a significant difference
observed between pre-test and post-test measurements
regarding pulse and Spo2 levels. With mean pulse rate of
96 in pre-test increased to 121 per minute and spo2 level of
94% in pre-test decreased to 88% in post-test.

Among our study subjects 18 (36%) patients were able to
walk more than 350 meters, 19 patients were able to cover
distance between 250-350 meters and 13 patients covered
distance ranging from 150-250 meters.

5. Conclusion

Our study highlights the clinical profile and lung
involvement in the form of respiratory symptoms,
radiological changes, echocardiography findings, and
changes in pulmonary function and exercise testing in
CTD-ILD patients. Since lung involvement in CTD is
associated with significant morbidity and mortality, a high
index of suspicion and the ability to identify the various
clinical features and effects on physiological testing in ILD
patients with underlying CTD can help in early diagnosis
and treatment. One of the drawbacks of this study was the
lack of lung biopsy for histopathological confirmation of
ILD. Further studies with a larger sample size and regular
patient follow up are required for a better understanding of
CTD-ILD in the Indian scenario.

6. Sources of Funding

No financial support was received for the work within this
manuscript.

7. Conflicts of Interest

No conflicts of interest.

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Author biography

Abhishek Nuchin, Resident

Girija Nair, Professor and HOD

Balaji Tuppekar, Assistant Professor

Shahid Patel, Associate Professor

Abhay Uppe, Professor and HOU

Cite this article: Nuchin A, Nair G, Tuppekar B, Patel S, Uppe A.
Clinical profile of patients with interstitial lung disease in connective
tissue disorders – An original study. Panacea J Med Sci
2021;11(3):573-578.

http://dx.doi.org/10.1055/s-0030-1262212
http://dx.doi.org/10.1378/chest.15-1145
http://dx.doi.org/10.1093/rheumatology/keh575
http://dx.doi.org/10.1186/ar3097
http://dx.doi.org/10.1097/RTI.0b013e3181c1acec
http://dx.doi.org/10.1164/rccm.2106012
http://dx.doi.org/10.1164/rccm.200604-488OC
http://dx.doi.org/10.1164/rccm.200302-219OC