9Drug TargeT InsIghTs 2016:10

A Case of Organizing Pneumonia (OP) Associated 
with Pembrolizumab

Paraskevi Fragkou1, Maria souli1, Maria Theochari2, Christina Kontopoulou3, stelios Loukides4 
and anna Koumarianou2
1Fourth Department of Internal Medicine, Infectious Diseases Unit, Attikon University Hospital, National and Kapodistrian University of 
Athens, Athens, Greece. 2Fourth Department of Internal Medicine, Hematology-Oncology Unit, Attikon University Hospital, National and 
Kapodistrian University of Athens, Athens, Greece. 32nd Radiology Department, Attikon University Hospital, National and Kapodistrian 
University of Athens, Athens, Greece. 42nd Respiratory Medicine Department, Attikon University Hospital, National and Kapodistrian 
University of Athens, Athens, Greece.

A BSTR ACT: Until recently, chemotherapy for metastatic melanoma had disappointing results. The identification of immune checkpoints such as CTLA-4 
and PD-1/PD-L1 has led to the development of an array of monoclonal antibodies (Mabs). These immunologic approaches against tumoral cells come with 
a novel kind of side effects that the clinician needs to be familiarized with. Herein, we report for the first time a case of organizing pneumonia, based on 
imaging and cytological analyses of bronchoalveolar lavage, possibly associated with the use of pembrolizumab, an anti-PD-1 Mab recently approved for 
the treatment of metastatic melanoma.

K E Y WOR DS: OP, organizing pneumonia, pembrolizumab, melanoma, side effect

CITATION: Fragkou et al. a Case of Organizing Pneumonia (OP) associated with 
Pembrolizumab. Drug Target Insights 2016:10 9–12 doi:10.4137/DTI.s31565.

TYPE: Case report

RECEIVED: February 5, 2016. RESUBMITTED: april 14, 2016. ACCEPTED FOR 
PUBLICATION: april 18, 2016.

ACADEMIC EDITOR: anuj Chauhan, editor in Chief

PEER REVIEW: Three peer reviewers contributed to the peer review report. reviewers’ 
reports totaled 454 words, excluding any confidential comments to the academic editor.

FUNDING: authors disclose no external funding sources.

COMPETING INTERESTS: Authors disclose no potential conflicts of interest.

COPYRIGHT: © the authors, publisher and licensee Libertas academica Limited. 
This is an open-access article distributed under the terms of the Creative Commons 
CC-BY-nC 3.0 License.

CORRESPONDENCE: akoumari@yahoo.com 

Paper subject to independent expert single-blind peer review. all editorial decisions 
made by independent academic editor. upon submission manuscript was subject to 
anti-plagiarism scanning. Prior to publication all authors have given signed confirmation 
of agreement to article publication and compliance with all applicable ethical and legal 
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requirements of third parties. This journal is a member of the Committee on Publication 
ethics (COPe).

Provenance: the authors were invited to submit this paper.

Published by Libertas academica. Learn more about this journal.

Introduction
New monoclonal antibodies (Mabs) targeting the immune 
checkpoint blockade have revolutionized the treatment of 
advanced melanoma patients. Although these novel Mab 
therapies can induce remarkable antitumor-specific immune 
responses, they have distinct side effects as compared with che-
motherapy, including nonspecific immunological activation.1 
To our knowledge, we report the first case of organizing pneu-
monia (OP) in a melanoma patient under immunotherapy 
with pembrolizumab, a PD-1 targeting Mab. The patient’s 
next of kin has given consent for publication of this report.

Case Presentation
A 64-year-old woman presented to our emergency depart-
ment with a 10-day history of progressive dyspnea and dry 
cough nonresolving after a 9-day course of oral antibiotics 
(levofloxacin 750  mg daily). She had been diagnosed with a 
c-kit/BRAF wild-type, stage IV mucosal melanoma of the 
nasal cavity with involvement of cervical and mediastinal 
lymph nodes and metastases to the liver, brain, and bones 
nine months earlier. Initial treatment included two cycles 
of dacarbazine 1000  mg/m2 and zoledronic acid 4  mg every 
three weeks. One month later, the patient experienced disease 
progression and was treated with four cycles of ipilimumab 
immunotherapy 3 mg/kg and zoledronic acid 4 mg q3 weeks 

intravenously (iv). Three months later, the disease advanced 
further, and a second-line immunotherapeutic agent with 
pembrolizumab was initiated. Thirteen days prior to her 
admission, she had received her fourth cycle of immunother-
apy with pembrolizumab. Her pretherapeutic thoracic CT 
scan was normal.

On examination, she was pale and tachypneic. The chest 
auscultation revealed diffuse bilateral coarse crackles and areas 
of bronchial breathing mainly in the right middle lobe. She 
was afebrile, but her oxygen saturation on room air was 75%.

Her blood tests were normal except an erythrocyte 
sedimentation rate of 200  mm/hour, a white blood count of 
10,970  cells/μL (differential: 83.6% neutrophils, 9.7% lym-
phocytes, and 6.7% monocytes), and a C-reactive protein of 
173  mg/L (normal value: 0–6  mg/L). A chest radiography 
demonstrated patchy alveolar infiltrates mainly on the right 
upper, the right middle, and the left upper lobe.

An initial diagnosis of a lower respiratory tract infec-
tion was made, and antibiotics were commenced, including 
ceftriaxone 2  g/day iv and azithromycin 500  mg/day orally. 
After three days of treatment, there was no improvement of 
signs or symptoms. Subsequently, the patient underwent a 
high-resolution computed tomography (HRCT) of the chest 
and fiberoptic bronchoscopy with bronchoalveolar lavage 
(BAL). Samples were submitted for staining and culture for 

Journal name: Drug Target Insights

Journal type: Case Report

Year: 2016

Volume: 10

Running head verso: Fragkou et al

Running head recto: OP in pembrolizumab

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Fragkou et al

10 Drug TargeT InsIghTs 2016:10

bacteria, fungi, mycobacteria, and nocardia, special staining 
for Pneumocystis jirovecii, cytology, immunophenotyping, and 
molecular testing for viral infection. The HRCT demonstrated 
patchy consolidation with a predominantly subpleural and 
peribronchial distribution, small ill-defined peribronchiolar 
nodules, tree-in-bud sign, and reverse halo sign, involving all 
lobes mainly the lower ones (Fig. 1). There was no lymph nodal 
enlargement or pleural effusion. Cytology, microbiology, and 
molecular testing were negative for malignant or infectious 
diseases. The immunophenotyping of the BAL lymphocytes 
by flow cytometry revealed macrophage and monocyte pre-
dominance (60.7%) with a lymphocyte count of 28.7% and a 
CD4+/CD8+ index of 0.4. Based on the imaging and clini-
cal and BAL findings that were consistent with OP, therapy 
with corticosteroids (prednisolone 50 mg/day iv) was initiated 
that resulted into rapid clinical and radiographic improvement 
of the patient. Her C-reactive protein declined to 20  mg/L 
within two days of steroid treatment. The treating physician 
assessed that OP represented a grade 3 adverse event,2 most 
probably related to treatment with pembrolizumab, which was 
discontinued. Three months later, the patient died of advanced 
metastatic disease in the brain.

Discussion
Advanced melanoma has been a challenge in oncology as the 
five-year survival rates were immensely low with standard 
chemotherapy.3 Newer Mab therapies targeting the immune 
checkpoint, ipilimumab (Yervoy; Bristol-Myers Squibb), 
nivolumab (Opdivo; Bristol-Myers Squibb), and pembroli-
zumab (Keytruda; Merck Sharp & Dohme Corp) were shown 
to prolong progression free and overall survival compared 
with chemotherapy.4

Pembrolizumab is a humanized IgG4 Mab raised against 
the programmed cell death protein 1 (PD-1) immune check-
point, recently approved by the US Food and Drug Adminis-
tration and the European Medicines Agency for the treatment 
of advanced melanoma, as a result of a randomized controlled 
phase III trial showing improved overall survival.5

PD-1 is a cell surface receptor that belongs to the immu-
noglobulin superfamily and is normally expressed on B-cells,6 

T-cells,7 and macrophages.8 PD-1 and its ligands, namely, 
programmed cell death ligand 1 (PD-L1) and 2 (PD-L2), 
have been found to be abnormally expressed by tumor cells.9 
These molecules play an important role in inhibiting antitu-
mor immune responses and are responsible for the immune 
evasion of cancer cells by the cytotoxic effector immune cells. 
Mab therapies against the PD-1 can reverse immune tolerance 
and achieve high tumor response rates and improvement of 
survival.10

The therapeutic effects of Mabs are not fully understood, 
but they are mediated through direct signaling, complement-
dependent cellular cytotoxicity, and antibody-dependent cel-
lular cytotoxicity.11

Pemprolizumab (previously known as MK-3475 or lam-
brolizumab) is a humanized monoclonal IgG4–kappa isotype 
antibody. Its variable region sequences were derived from a 
very high-affinity mouse antihuman PD-1 antibody (dissocia-
tion constant, 28  pM) that was grafted into a human IgG4 
immunoglobulin with a stabilizing S228P Fc alteration that 
does not engage Fc receptors or activate complement, thus 
avoiding cytotoxic effects of the antibody when it binds to the 
PD-1 receptor of T-cells that are intended to activate against 
tumor cells.12 It is reasonable to assume that the mechanism 
of action and the resulting side effects of pembrolizumab 
are mediated through PD-1 direct signaling on T-cells or 
macrophages.

Cryptogenic organizing pneumonia (COP), the idio-
pathic form of OP (formerly called bronchiolitis obliterans 
OP), is a type of diffuse interstitial lung disease that affects 
the distal bronchioles, respiratory bronchioles, alveolar ducts, 
and alveolar walls. The primary area of injury is within the 
alveolar wall. Since many cases of COP are secondary, it is 
more proper to use the term OP associated with the name of 
the secondary cause.13

Histopathologic study through lung biopsy via video-
assisted thoracoscopic surgery or open thoracotomy is the 
optimal method for establishing the diagnosis of COP, in 
order to have enough tissue for the pathologist to exclude 
other processes. Because of the low oxygen saturation level, 
we selected to combine the cytological profile of BAL with 

Figure 1. Patient’s computed tomography of chest indicating (A) baseline CT scan before pembrolizumab therapy, (B) reverse halo sign (dotted arrow) 
and consolidation with air bronchogram (straight arrow) features of OP following therapy of pembrolizumab, and (C) follow-up CT scan indicating complete 
resolution of the organized pneumonia, one month after the steroid therapy. Metastatic lesion in the right middle lobe.

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OP in pembrolizumab 

11Drug TargeT InsIghTs 2016:10

characteristic clinical and imaging features. A previous study 
has already described in detail the cytological and immu-
nocytological profile of BAL in COP, which include foamy 
macrophages, mast cells, plasma cells, a decreased CD4/CD8 
T-cell ratio, an increase in activated T-lymphocytes based on 
HLA-DR or interleukin-2 receptor expression and a lympho-
cyte increase of 20%–40% also documented in our patient 
with bronchiolitis obliterans.

The most commonly occurring clinical findings in COP 
are similar to our patient’s symptoms, including nonproductive 
persistent cough, dyspnea, and malaise without fever.14 Since 
the most common manifestations are nonspecific, diagnosis is 
often delayed (6–13 weeks), and similar to our patient, a lack 
of response to empiric antibiotics for community-acquired 
pneumonia may be the initial clue to the presence of a non-
infectious, inflammatory pneumonia.15 Similar to that in our 
patient, HRCT has findings that are characteristic for COP 
and include peripheral bilateral patchy opacities, more fre-
quently in the periphery and in the lower lung zone, air bron-
chogram, and reverse halo sign.16 Once the diagnosis of COP 
is made, rapid clinical and imaging improvement is obtained 
with corticosteroid treatment, but relapses are common after 
stopping treatment, indicating an established immune reac-
tion requiring long-term therapy.15

When COP is suspected in cancer patients, differential 
diagnoses that need to be considered include disease progres-
sion, cardiogenic edema, radiation pneumonitis, allergies, 
pulmonary hemorrhage, and infections that cause diffuse inter-
stitial infiltrates in the lungs such as gram-negative or gram-
positive bacteria, fungi (Aspergillus, Candida, and P. jirovecii), 
parasites (Toxoplasma gondii), or viruses (herpes simplex, vari-
cella zoster, and cytomegalovirus).17

On the other hand, pneumonitis in cancer patients may 
hold a heterogeneous pathological background based on vari-
ous antineoplastic agents including chemotherapy, such as 
taxanes, targeted therapy, such as everolimus, and Mabs, such 
as rituximab, a chimeric IgG1.17

In retrospective analysis of patients with non-Hodgkin 
lymphoma treated with rituximab, 8 of 23 patients, diagnosed 
with COP and treated with corticosteroids, died, indicat-
ing that COP although rare may become a fatal pulmonary 
toxicity and the oncologists or internists must maintain a high 
index of suspicion to recognize this complication early.

Little is known regarding the clinicopathologic features 
of pneumonitis related to the novel immune checkpoint inhib-
itors. A recent study indicated the development of pneumo-
nitis in three patients treated with nivolumab, an anti-PD-1 
Mab, 7–24.3 months after treatment initiation.18 Two patients 
were radiographically found with acute interstitial pneumo-
nia/acute respiratory distress syndrome, and one patient was 
with nonspecific interstitial pneumonia. Two of these patients 
required admission in the intensive care unit, and one suc-
cumbed four weeks after diagnosis of pneumonitis. Com-
puted tomography findings differed from COP, and BAL or 

transbronchial biopsy was not performed in these patients. 
Another report involving a patient treated with nivolumab 
described an OP diagnosed both radiographically and patho-
logically.19 Similar to our case, CT of the chest showed the 
typical reversed halo sign and had a favorable response to cor-
ticosteroid therapy.

With novel immunotherapies, the incidence of auto-
immune phenomena is rising; therefore, it is important to 
recognize an OP early in any patient receiving anti-PD-1 
and presenting with symptoms of new cough or shortness 
of breath. The diagnosis needs to be supported by imaging 
and cytological investigations. Although the exact causative 
mechanism of OP by anti-PD-1 Mab therapy cannot be 
established as yet, a T-cell or macrophage-driven effect is the 
most plausible explanation, and further studies are warranted 
to define the pathogenic mechanism underlying this possibly 
lethal side effect.

Acknowledgment
The authors are obliged to Professor Dimitrios Boumpas for 
critical revision of the manuscript.

Author Contributions
Conceived and designed the experiments: AK. Analyzed the 
data: MS. Wrote the first draft of the manuscript: PF. Con-
tributed to the writing of the manuscript: PF, MS, MT, CK, 
SL, AK. Agree with manuscript results and conclusions: PF, 
MS, MT, CK, SL, AK. Jointly developed the structure and 
arguments for the paper: PF, MS, MT, CK, SL, AK. Made 
critical revisions and approved final version: PF, MS, MT, 
CK, SL, AK. All authors reviewed and approved of the final 
manuscript.

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