Clinical Trial Details
— Status: Recruiting
Administrative data
| NCT number |
NCT04996173 |
| Other study ID # |
211177 |
| Secondary ID |
|
| Status |
Recruiting |
| Phase |
N/A
|
| First received |
|
| Last updated |
|
| Start date |
October 25, 2021 |
| Est. completion date |
April 2026 |
Study information
| Verified date |
April 2024 |
| Source |
Vanderbilt University Medical Center |
| Contact |
Ankush Ratwani, MD |
| Phone |
615-322-3412 |
| Email |
ankush.ratwani[@]vumc.org |
| Is FDA regulated |
No |
| Health authority |
|
| Study type |
Interventional
|
Clinical Trial Summary
Benign central airway stenosis (BCAS) is an important cause of both pulmonary morbidity and
mortality. Notable causes include post-intubation stenosis, collagen vascular diseases,
airway trauma, infectious and idiopathic subglottic stenosis (iSGS). Surgery is the preferred
definite option; however, the first therapeutic attempt is usually endoscopic to temporarily
restore airway patency and symptomatic improvement.
Several endoscopic modalities exist for treatment. Most commonly, thermal or laser therapy to
make radial incisions into the stenotic lesion, followed by balloon dilation to increase the
area of patency. Clinicians may also inject steroids or antineoplastic agents such as
mitomycin C. All of these methods have benefits and associated risks. Symptomatic stenosis
frequently reoccurs with these methods. For example, the investigators have been doing 3-4
ballon dilations procedures a week at our institution.
Spray cryotherapy (SCT) is a novel FDA-cleared technique that allows for liquid nitrogen to
be delivered through the working channel of a bronchoscope. Few retrospective studies exist
without more robust clinical trial data to reduce the risk of bias and support its widespread
use. The investigators postulate that SCT and standard of care techniques will improve airway
patency volume at six months than the standard of care techniques alone. Some of the proposed
advantages include improved wound healing which may translate to less scar tissue and thus
improvements in airway patency for a longer duration of time.
Description:
Airway obstruction is classified into two broad categories based on the underlying etiology:
malignant and non-malignant processes. Benign central airway obstruction (BCAO), as the name
suggests, is narrowing the tracheal lumen from causes unrelated to underlying endoluminal or
extrathoracic cancers. One common mechanism is mechanical stress on the tracheal walls with
post-intubated tracheal stenosis (PITS), post-tracheostomy tracheal stenosis (PTTS), and
stenosis related to airway stents. Inflammatory disorders such as sarcoidosis, granulomatosis
with polyangiitis (GPA), relapsing polychondritis (RPC), amyloidosis are frequently observed.
Chronic atypical infections such as Tuberculosis have been implicated, especially in the
developing world. Rarely an idiopathic form can develop in women's fifth decade of life,
known as idiopathic laryngotracheal stenosis (ILTS).
First-line treatment for BCAO is dependent mainly on the complexity of stenosis. Tracheal
sleeve resection with end-to-end anastomosis is recommended for patients with complex lesions
and often is the only definitive treatment available for most patients. Bronchoscopic
management has been recommended for simple lesions or patients that are not robust surgical
candidates. However, the advances in both flexible and rigid bronchoscopic techniques have
led to the treatment of more complex lesions. A multidisciplinary and multimodal approach is
often necessary to achieve long-lasting airway lumen patency. Current bronchoscopic
modalities include balloon dilation, argon plasma coagulation (APC), diode laser or monopolar
cautery, stent placement, endoluminal steroids, antineoplastic agents, and Montgomery t-tube
placement. Patients will likely need repeat procedures, which can be on the order of several
weeks to years.
It is postulated that heat-based modalities may lead to thermal fixation of tissue with
reparative healing and fibrotic scarring that may translate to the reoccurrence of fibrotic
injury. In addition, using these modalities on patients with high intraoperative oxygen
concentrations can lead to airway fires. Spray cryotherapy (SCT) utilizes liquid nitrogen in
a metered fashion to flash freeze tissue with subsequent tissue necrosis that has many
advantages that heat-based modalities can not offer. The truFreeze System (CSA Medical, Inc.,
Baltimore, MD, USA) utilizes liquid nitrogen through a 7-french catheter through the working
channel of an endoscope. SCT works by rapidly releasing liquid state nitrogen stored at
temperatures less than -196C in a circumferential dose area, leading to rapid hypothermic
cell death on tissue. As a result, stenotic tissue undergoes intracellular ice crystal
formation with eventual rupture and cell death. Unlike slow delivery of liquid nitrogen or
contact probe freezing, this rapid expansion allows the extracellular matrix to be largely
intact, thus facilitating wound healing without exuberant airway scar. Other potential
benefits include using SCT with high oxygen concentrations, improved bleeding, use on
materials that may be combustible such as airway stents, and studies showing improved balloon
dilation with less chance of airway laceration.
The investigators hypothesize that the addition of SCT to standard endoscopic treatment
modalities of BCAO will decrease stenosis recurrence at six months. The investigators plan to
measure our primary outcome measure utilizing a novel noninvasive 3D volumetric tracheal
reconstruction by CT scan. Secondary outcomes will include changes in symptoms based on a
validated questionnaire, physiologic parameters of breathing, and changes in tracheal cell
profile with SCT using single-cell RNA sequencing.
Randomization will occur in a 1:1 fashion, with the patients and outcome adjudicators blinded
to the underlying intervention. Patients will have a thin cut CT scan within six weeks of the
incident procedure, with pulmonary function testing and questionnaire administration within
two weeks. The procedure will be done either with an interventional pulmonologist or
otolaryngology, depending on the initial referral. General anesthesia is provided with either
an endotracheal tube, laryngeal mask airway, rigid bronchoscope, or dedo laryngoscope,
depending on the operator's preference and lesion location. The standard of care group will
undergo radial cut incisions into the circumferential lesion followed by balloon dilation.
The intervention group will undergo two cycles up to 10 second spray time of SCT, followed by
radial cuts and balloon dilation. A final spray will be performed after with a standard
freeze-thaw cycle. Five patients with idiopathic subglottic stenosis will undergo cryobiopsy.
These samples will be compared with controls for changes in cellular profile.
Patients will undergo a thin cut CT scan within 6 weeks after the procedure with repeat
physiological parameters and a questionnaire. This CT will act as the personal best to
compare to the final CT scan. Finally, at six months, the investigators will repeat these
measures with a final CT scan. Throughout the follow-up period, patients will be given access
to a mobile application program that will help patients self-monitor peak expiratory flows.
If patients undergo a repeat procedure before the 6-month CT, they will be analyzed in an
early reintervention subgroup.
