NanoSpectrometer Biomarker Discovery and Confirmation Study
| Status: | Recruiting |
|---|---|
| Conditions: | Lung Cancer, Cancer |
| Therapuetic Areas: | Oncology |
| Healthy: | No |
| Age Range: | 18 - Any |
| Updated: | 1/18/2019 |
| Start Date: | September 5, 2017 |
| End Date: | May 31, 2020 |
| Contact: | Lonny Yarmus, DO |
| Email: | lyarmus@jhmi.edu |
| Phone: | 4105025224 |
This study will evaluate exhaled volatile organic compounds (VOC's) in the breath of
participants with stage 1 lung cancer, their house-mates, and matched controls. The goal of
the study is to identify VOC fingerprints that are only detectable in those with stage 1 lung
cancer.
participants with stage 1 lung cancer, their house-mates, and matched controls. The goal of
the study is to identify VOC fingerprints that are only detectable in those with stage 1 lung
cancer.
Lung cancer is by far the leading cause of cancer death in the United States. More people die
annually of lung cancer than of colon, breast, and prostate cancers combined. Worldwide it is
already the leading cause of cancer death among males, and with smoking rates substantially
higher in developing countries relative to the United States the worldwide burden of lung
cancer is projected to increase considerably in the future.
For lung cancer, as for many cancers, early diagnosis allowing for full resection offers the
greatest chance for long-term survival, but unfortunately these individuals currently
constitute only a minority of the lung-cancer population. Screening technologies that allow
for the earliest detection of lung cancer would therefore have tremendous potential to
substantially improve outcomes. Recently, and for the first time, a screening test for lung
cancer of high risk individuals has been recommended by the US Preventive Services Task
Force, as well as others, for the reduction of lung cancer mortality. This recommendation was
based primarily on the results of the National Lung Screening Trial (NLST) that randomized
over 53,000 individuals considered at high risk for lung cancer to 3 annual screenings with
either low-dose CT (LDCT) or a chest x-ray and then followed for a median of 6.5 years. In
this study LDCT scanning was associated with a statistically significant 20% relative
decrease in lung cancer mortality, and a smaller, but still significant 6.7% decrease in
overall mortality. Despite these encouraging results of LDCT, as a screening tool it has
substantial limitations. Beyond the costs, inconvenience and radiation exposure associated
with LDCT, its performance characteristics are far from optimal. For example, nearly a
quarter of the LDCT population had a positive screening test, with the vast majority - 96.4%
- proving to be false-positive. With a positive predictive value of <4% LDCT screening will
lead to a great number of unnecessary diagnostic procedures as well as substantial anxiety in
the screened population and their family.
Breath analytics is a new and very promising tool for diagnosing lung cancer, as well as
multiple other conditions. Previous studies identified that dog's heightened olfactory senses
were able to detect cancer in an individual's breath with an accuracy of nearly 100%. Since
then attempts have been made to mimic canine capabilities with "electronic noses" to detect
and quantitate the nearly 3000 compounds, many in the parts per billion or even parts per
trillion ranges, in exhaled breath. Early studies of these technologies support great
potential as a diagnostic and screening tool. As a screening tool it could be ideal as it is
noninvasive, painless and free of any undesirable side effects. In addition, new advances in
nanotechnology have allowed these extremely sensitive detection technologies to be
miniaturized to the point that they can be linked to a smartphone, providing future
possibilities to almost continuously surveil individuals for the development of lung cancer
and other life-threatening conditions. This study is concerned with comparing the
concentrations of volatile organic compounds (VOCs) in the breath of lung cancer patients
(cases) and lung-cancer-free individuals (controls).
annually of lung cancer than of colon, breast, and prostate cancers combined. Worldwide it is
already the leading cause of cancer death among males, and with smoking rates substantially
higher in developing countries relative to the United States the worldwide burden of lung
cancer is projected to increase considerably in the future.
For lung cancer, as for many cancers, early diagnosis allowing for full resection offers the
greatest chance for long-term survival, but unfortunately these individuals currently
constitute only a minority of the lung-cancer population. Screening technologies that allow
for the earliest detection of lung cancer would therefore have tremendous potential to
substantially improve outcomes. Recently, and for the first time, a screening test for lung
cancer of high risk individuals has been recommended by the US Preventive Services Task
Force, as well as others, for the reduction of lung cancer mortality. This recommendation was
based primarily on the results of the National Lung Screening Trial (NLST) that randomized
over 53,000 individuals considered at high risk for lung cancer to 3 annual screenings with
either low-dose CT (LDCT) or a chest x-ray and then followed for a median of 6.5 years. In
this study LDCT scanning was associated with a statistically significant 20% relative
decrease in lung cancer mortality, and a smaller, but still significant 6.7% decrease in
overall mortality. Despite these encouraging results of LDCT, as a screening tool it has
substantial limitations. Beyond the costs, inconvenience and radiation exposure associated
with LDCT, its performance characteristics are far from optimal. For example, nearly a
quarter of the LDCT population had a positive screening test, with the vast majority - 96.4%
- proving to be false-positive. With a positive predictive value of <4% LDCT screening will
lead to a great number of unnecessary diagnostic procedures as well as substantial anxiety in
the screened population and their family.
Breath analytics is a new and very promising tool for diagnosing lung cancer, as well as
multiple other conditions. Previous studies identified that dog's heightened olfactory senses
were able to detect cancer in an individual's breath with an accuracy of nearly 100%. Since
then attempts have been made to mimic canine capabilities with "electronic noses" to detect
and quantitate the nearly 3000 compounds, many in the parts per billion or even parts per
trillion ranges, in exhaled breath. Early studies of these technologies support great
potential as a diagnostic and screening tool. As a screening tool it could be ideal as it is
noninvasive, painless and free of any undesirable side effects. In addition, new advances in
nanotechnology have allowed these extremely sensitive detection technologies to be
miniaturized to the point that they can be linked to a smartphone, providing future
possibilities to almost continuously surveil individuals for the development of lung cancer
and other life-threatening conditions. This study is concerned with comparing the
concentrations of volatile organic compounds (VOCs) in the breath of lung cancer patients
(cases) and lung-cancer-free individuals (controls).
Inclusion Criteria:
- Adults age 18 and over with diagnosed Stage 1 Lung Cancer (cases)
- Adults age 18 and over without Lung cancer (type 1 controls)
- Adults age 18 and over who live in the same environment as the cases (type 2 controls)
Exclusion Criteria N/A
We found this trial at
1
site
1800 Orleans St.
Baltimore, Maryland 21287
Baltimore, Maryland 21287
410-955-5000
Principal Investigator: Lonny Yarmus
Phone: 410-502-2533
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