Introduction
Idiopathic pulmonary fibrosis (IPF), a major
idiopathic interstitial lung disease, has an extremely poor
prognosis (1). Moreover, patients
with IPF have a higher incidence of lung cancer, more than seven
times higher than that in the general population (2). A previous prospective cohort study
revealed that 9% of patients with IPF were dead because of lung
cancer (1,3). Additionally, IPF is detected in
3.7-8% of patients with lung cancer (4-7),
and the prognosis of lung cancer with IPF is poorer than that
without IPF (4,5,8).
Therefore, treatment strategies are crucial for patients with lung
cancer and IPF. The postoperative acute exacerbation of
interstitial pneumonia (IPAE) is a life-threatening complication.
Several previous studies have shown that IPAE is associated with
high mortality rates.
Research conducted by the Japanese Association for
Chest Surgeons identified seven predictive risk factors for IPAE,
with the study reporting a 43.9% mortality rate for this condition
(9). Possible prophylactic
measures against IPAE, such as steroids, sivelestat, or
ulinastatin, have yet to be established (10). Recently, anti-fibrotic drugs such
as pirfenidone and nintedanib have been identified to relieve the
chronological worsening of pulmonary function or prevent IPAE
(11-21).
Although trials on the perioperative administration of pirfenidone
have been reported (22), no
reports exist on the perioperative safety and efficacy of
nintedanib. This study aimed to examine the perioperative safety
and efficacy of this medication in patients with acute exacerbation
of interstitial pneumonia.
Materials and methods
This study focused on patients diagnosed with both
lung cancer and IPF who underwent bilobectomy, lobectomy,
segmentectomy, and wedge resection between January 2020 and August
2023 at Juntendo University School of Medicine, Nerima Hospital.
Twelve patients with IPF and concomitant lung cancer who received
perioperative nintedanib therapy after lung cancer surgery were
retrospectively investigated. Clinical data were retrospectively
obtained from the medical charts. Oral nintedanib (300 mg/day) was
administered preoperatively, and patients were assessed for adverse
events 1-2 weeks after the initiation of treatment. The oral dose
was reduced to 200 mg/day in patients with liver dysfunction and
those who developed side effects such as liver dysfunction and
diarrhea. Nintedanib was withdrawn 5 days preoperatively and
resumed postoperatively after chest tube removal.
This study was approved by the Institutional Review
Board of our hospital (No. E23-0399). According to an International
Working Group Report, IPAE is defined as the subjective worsening
of dyspnea, new bilateral radiological opacities, and exclusion of
causes of dyspnea such as cardiac failure or fluid overload
(23). The assessment of
postoperative IPAE was conducted within a specific time frame, and
the study protocol defined the evaluation period as 30 days after
surgery according to the PEOPLE study, which demonstrated the
perioperative benefit of pirfenidone (22).
Results
Nintedanib was administered to 12 patients between
January 2020 and August 2023. Ten patients did not receive any
other medication for IPF during the perioperative period, including
steroids, N-acetyl cysteine, erythromycin, or sivelestat sodium.
Two patients received steroids, but no other agents were
administered. Eleven patients were administered oral nintedanib
(300 mg/day), and a decreased dose (200 mg/day) was administered to
one patient with a hepatic comorbidity. Patients were assessed for
adverse events 1-2 weeks after the initiation of treatment. In one
of the 11 patients who developed liver dysfunction, the oral dose
was reduced to 200 mg/day.
The patient characteristics are shown in Table I. The mean patient age was 75.1±4.6
(64-81) years, and the body mass index ranged from 20.9 to 28.4
kg/m2 (average, 25.0 kg/m2). All the patients
had a history of heavy smoking. Their past medical histories
included heart disease in one case (8.3%), lung disease except for
IPF in three cases (25%), diabetes in two patients (16.7%), stroke
in one case (8.3%), and cancer affecting other organs in three
cases (25%). None of the patients had autoimmune diseases.
Clinically, ten cases (83.3%) were associated with the usual
interstitial pneumonia pattern. In four cases, restrictive
ventilatory failure was evident (33.3%). The percentages predicting
vital capacity ranged from 82 to 123.1 (average, 101.5), the
percentages predicting the diffusing capacity of the lungs for
carbon monoxide ranged from 39 to 68.2 (average, 50.1), and the
modified sex, age, and physiology score ranged from 2 to 7
(average, 4.9). The IPF markers in blood tests, such as Krebs von
den Lungen-6 and surfactant protein-D, ranged from 349 to 1650
(average, 693.7) and 15 to 190 (average, 90.7), respectively. The
pathological diagnosis of lung cancer included stage I in four
cases (33.3%), stage II in five cases (41.7%), and stage III in
three cases (25%) based on the Union for International Cancer
Control, 8th edition (24).
However, to date, no cases of stage 0 or IV disease have been
reported. The histological types of lung cancer included
adenocarcinoma in three cases (25%), squamous cell carcinoma in
five cases (41.7%), small cell carcinoma in two cases (16.7%), and
other histological subtypes in two cases (16.7%) (Table II). Most patients underwent
lobectomy, while limited resections, including anatomical
segmentectomies in two cases and wedge resection in one case, were
performed in others. Two patients underwent bi-lobectomy. The
length of surgery ranged from 167 to 365 min (average, 257.3 min),
and blood loss ranged from 2 to 447 g (average, 164.6 g). The
details of the surgical procedures are presented in Table III.
 | Table IPatient characteristics. |
Table I
Patient characteristics.
| Characteristic | Value |
|---|
| Number of
patients | 12 |
| Age, years | 75.1±4.6 |
| Sex | |
|
Male | 10 |
|
Female | 2 |
| BMI | 25.0±2.5 |
| Smoking history, pack
yearsa | 54.7±22.3 |
| Medical history | |
|
Heart
disease | 1 |
|
Lung disease
(except IP) | 3 |
|
Diabetes | 2 |
|
Autoimmune
disease | 0 |
|
Stroke | 1 |
|
Other organ
cancer | 3 |
| ILD pattern | |
|
UIP | 10 |
|
Non-UIP | 2 |
| VC, % | 101.5±13.6 |
| DLCO, % | 50.1±8.6 |
| Modified GAP
score | 4.9±1.4 |
| KL-6 | 693.7±392.8 |
| SP-D | 90.7±60.6 |
| Table IIPathological diagnosis of lung
cancer. |
Table II
Pathological diagnosis of lung
cancer.
| Classification | N |
|---|
| pT
classificationa | |
|
T1 | 2 |
|
T2 | 9 |
|
T3 | 1 |
|
T4 | 0 |
| pN
classificationa | |
|
N0 | 8 |
|
N1 | 1 |
|
N2 | 3 |
| pM
classificationa | |
|
M0 | 12 |
|
M1 | 0 |
| Cancer
stagea | |
|
I | 4 |
|
II | 5 |
|
III | 3 |
|
IV | 0 |
| Pathology | |
|
Adenocarcinoma | 3 |
|
Squamous
cell carcinoma | 5 |
|
Small cell
carcinoma | 2 |
|
Other | 2 |
| Table IIISurgical procedure for lung
cancer. |
Table III
Surgical procedure for lung
cancer.
| Procedure | Value |
|---|
| Operation | |
|
Bi-lobectomy | 2 |
|
Lobectomy | 7 |
|
Segmentectomy | 2 |
| Wedge
resection | 1 |
| Length of
operation, min | 257.3±58.8 |
| Blood loss, g | 164.6±170.0 |
Table IV shows the
complications observed during the study period, the mortality
rates, and the nintedanib status. The dosing period of nintedanib
before surgery ranged from 14 to 43 days (average, 27.1 days). None
of the patients canceled or postponed surgery because of
nintedanib-related side effects. The most frequent postoperative
surgical complication was prolonged air leakage (three cases; 25%),
followed by surgical site infection (two cases; 16.7%). Pyothorax,
heart failure, and pleurisy were observed in one case (8.3%). Three
patients with prolonged air leakage did not receive post-operative
nintedanib. However, during the entire follow-up period, IPAE was
not identified, and the mortality rate in this study was 0%. The
detailed clinical courses and patient characteristics are
summarized in Table V.
| Table IVPerioperative complications and
mortality rates. |
Table IV
Perioperative complications and
mortality rates.
|
Characteristics | Values |
|---|
| Dosing period of
nintedanib before operation, days | 27.1±9.1 |
| Nintedanib resumed
cases after operation | 9 |
| Time to nintedanib
resumption, days | 4.2±1.7 |
| Perioperative
complications | |
|
IPAE | 0 (0) |
|
Bronchopleural
fistula | 0 (0) |
|
Pyothorax | 1 (9.1) |
|
Prolonged
air leak | 3 (27.3) |
|
Arrhythmia | 0 (0) |
|
Heart
failure | 1 (9.1) |
|
Pleurisy | 1 (9.1) |
|
Renal
complications | 0 (0) |
|
Surgical
site infection | 2 (18.2) |
| Mortality | |
|
30 days | 0 (0) |
| Table VSummary of patient characteristics
and clinical course. |
Table V
Summary of patient characteristics
and clinical course.
| No. | Age, years | Sex | Purpose of
surgery | Emphysema | IPF subtype | Medication | BI | Surgical
procedure | Initial dose of
nintedanib | Side effects | Resume dose | Perioperative
complication | 30 days
outcome |
|---|
| 1 | 81 | M | Lung cancer | + | NSIP | Anticoagulant,
antihypertensive agent, antiarrhythmic | 600 | Lobectomy | 300 | - | 300 | - | Alive |
| 2 | 77 | M | Lung cancer | - | UIP | Bronchodilator | 1100 | Bi-lobectomy | 300 | - | 300 | - | Alive |
| 3 | 75 | M | Lung cancer | + | UIP | Antihypertensive
agent, hypoglycemic agent | 960 | Segmentectomy | 300 | - | 300 | - | Alive |
| 4 | 72 | M | Lung cancer | + | NSIP | Anticoagulant,
antihypertensive agent, bronchodilator | 1000 | Lobectomy | 200 | - | 200 | - | Alive |
| 5 | 73 | M | Lung cancer | + | UIP | Antihypertensive
agent, bronchodilator | 1100 | Wedge
lobectomy | 300 | - | 300 | Surgical site
infection, heart failure | Alive |
| 6 | 80 | M | Lung cancer | - | UIP | Bronchodilator | 2400 | Lobectomy | 300 | - | - | Prolonged air
leak | Alive |
| 7 | 70 | M | Lung cancer | - | UIP | Thiamazole | 900 | Lobectomy | 300 | - | 300 | Surgical site
infection, pleurisy | Alive |
| 8 | 78 | M | Lung cancer | + | UIP | Bronchodilator | 1000 | Lobectomy | 300 | Liver failure | 200 | - | Alive |
| 9 | 77 | F | Lung cancer | + | UIP | Antihypertensive x
failure | 800 | Bi-lobectomy | 300 | - | - | Prolonged air
leak | Alive |
| 10 | 79 | M | Lung cancer | - | UIP | Prednisolone,
antihypertensive agent | 750 | Lobectomy | 300 | - | - | Prolonged air leak,
pyothorax | Alive |
| 11 | 75 | M | Lung cancer | + | UIP | Bronchodilator,
antihypertensive agent | 1500 | Segmentectomy | 300 | - | 300 | - | Alive |
| 12 | 64 | M | Lung cancer | + | UIP | Prednisolone,
antihypertensive agent, hypoglycemic agent | 1020 | Lobectomy | 300 | - | 300 | - | Alive |
Discussion
Nintedanib, an anti-fibrotic agent for IPF, inhibits
multiple growth factors, such as vascular endothelial growth factor
(VEGF)-2, platelet-derived growth factor, and fibroblast growth
factor receptors (25,26). Inhibitors and antibodies targeting
the VEGF receptor have gained recognition as effective anti-cancer
treatments, particularly for patients with advanced-stage
malignancies (27-29).
Conversely, a previous report has revealed that VEGF is associated
with the pathogenesis of IPAE and acute respiratory distress
syndrome (30). Nintedanib
suppresses the expression of VEGF receptors, which are believed to
inhibit IPAE development. Data on the efficacy of nintedanib in
patients with interstitial lung diseases, except for IPF, were
derived from two high-quality trials. In the SCENCIS trial for
systemic sclerosis-induced interstitial lung disease and INBUILD
trial for progressive fibrosing interstitial lung disease,
nintedanib delayed the onset of the initial development of IPAE and
the progression of lung function deterioration, especially forced
vital capacity (13,14). In the TOMORROW phase II trial, the
incidence of acute exacerbations was significantly lower in the
nintedanib-treated group (15).
Moreover, the INPULSIS cohort revealed the efficacy of nintedanib,
with a particular focus on its effects on the Japanese patient
population (16). Incidence of
IPAE was 4% in patients who received nintedanib, while the
incidence of IPAE was 12% in patients who received a placebo.
Several complications in this study, such as persistent pulmonary
fistulae, surgical site infections, and pyothorax, may have been
influenced by the protracted wound healing effect due to the
inhibition of multiple growth factors. However, none of the
patients in this study experienced IPAE, suggesting that nintedanib
has an inhibitory effect on IPAE, as previously reported.
However, there are no reports on the perioperative
administration of nintedanib in patients with lung cancer or
interstitial pneumonia. This is the first study on the
perioperative administration of nintedanib to prevent acute
exacerbation of interstitial pneumonia. However, studies on the
perioperative administration of pirfenidone, such as the PEOPLE
study, have been reported (22). A
phase II PEOPLE study revealed the safety and efficacy of
perioperative administration of pirfenidone, demonstrating an acute
exacerbation rate of 5.1% and a mortality rate of 2.8% at 1 month
after surgery. Furthermore, a Phase III PEOPLE study was conducted
(22). Although the breakdown of
anti-fibrotic drugs for the results is unclear, a retrospective
study of 103 patients undergoing lung transplantation and receiving
anti-fibrotic agents included 21 nintedanib recipients. This study
found that anti-fibrotic drug therapy did not increase the
incidence of post-operative complications related to the airway,
bleeding, or wounds after lung transplantation. Furthermore, the
study suggested a potential correlation between anti-fibrotic drug
therapy and favorable outcomes in lung transplant patients,
indicating a possible decrease in the incidence of primary graft
dysfunction and a potential reduction in perioperative mortality
rates (31). To the best of our
knowledge, this study is the first to investigate the perioperative
use of nintedanib to prevent IPAE in lung cancer. In this study,
IPAE occurring within 1 month after surgery was not observed.
Furthermore, after 30 days, the mortality rate was 0% in this
study. This result was most likely related to the absence of cases
of acute exacerbation of interstitial pneumonia. However, several
complications, such as persistent pulmonary fistulae, surgical site
infections, and pyothorax were observed in this study, which may
have been influenced by the protracted wound-healing effect of
nintedanib. However, establishing a causal relationship with
nintedanib administration is challenging due to the occurrence of
these common perioperative complications. Further prospective
studies are required to elucidate the causal relationship between
these complications. In addition, research should be conducted on
the time required for drug discontinuation.
The various limitations of the present study
prevented us from drawing conclusive inferences about the
effectiveness of nintedanib in preventing postoperative IPAE.
First, our investigation was confined to Japanese patients and
utilized a relatively small sample size without statistical
analysis, which potentially limits the generalizability of the
results. The second limitation is the retrospective nature of the
study. Finally, this was not a comparative study, and additional
patients and randomized controlled trials are required to determine
the statistical significance of the data.
IPF should be acknowledged as a crucial factor when
planning lung cancer diagnosis and therapy. An established strategy
for the accurate diagnosis of lung cancer using useful tools such
as liquid biopsy (32) and
reducing the occurrence of perioperative IPAE leads to more
comprehensive and effective management of both the cancer and the
underlying IPF, ultimately enhancing patient prognosis and quality
of life.
In conclusion, this is the first study on the
perioperative administration of nintedanib to prevent acute
exacerbation of interstitial pneumonia. These results encourage
further investigation into the potential of nintedanib treatment in
a larger patient cohort through prospective verification.
Acknowledgements
Not applicable.
Funding
Funding: This study was supported by JSPS KAKENHI (grant no.
23K15564).
Availability of data and materials
The data generated in the present study may be
requested from the corresponding author.
Authors' contributions
RS and TB were responsible for study concept and
design. RS was responsible for the acquisition, analysis and
interpretation of data, and obtained funding. RS, HU, SH, TB and KS
were responsible for clinical material support and analysis of
clinicopathological data. RS and TB confirm the authenticity of all
the raw data RS and TB were responsible for drafting of the
manuscript. All authors have read and approved the final
manuscript.
Ethics approval and consent to
participate
This study was approved (approval no. E23-0399) by
the Institutional Review Board of the Juntendo University Nerima
Hospital (Tokyo, Japan). The Institutional Review Board of Juntendo
University Nerima Hospital (Tokyo, Japan) exempted this
retrospective observational study from requiring written informed
consent. Instead, informed consent was obtained in the form of an
opt-out on a website. This study followed the Strengthening the
Reporting of Observational Studies in Epidemiology guidelines.
Patient consent for publication
Not applicable.
Competing interests
The authors declare that they have no competing
interests.
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