Device could pave the way for real-time, noninvasive breath analysis to detect and monitor diseases and be a new service medical laboratories can offer
Breathalyzer technology is not new, but until now human breath detection devices have not been comparable to clinical laboratory blood testing for disease detection and monitoring. That may soon change and there are implications for clinical laboratories, partly because breath samples are considered to be non-invasive for patients.
Scientists with JILA, a research center jointly operated by the National Institutes of Standards and Technology (NIST) and the University of Colorado Boulder, recently increased the sensitivity of their laser frequency comb breathalyzer one thousand-fold. This created a device that can detect four disease biomarkers simultaneously, with the potential to identify six more, according to an NIST news release.
Medical laboratory scientists will understand the significance of this development. JILA’s enhanced breathalyzer device could pave the way for real-time, noninvasive breath analysis to detect and monitor diseases, and potentially eliminate the need for many blood-based clinical laboratory tests.
During their research, physicist Jun Ye, PhD, and David Nesbitt, PhD, both Fellows at JILA and professors at University of Colorado Boulder, detected and monitored four biomarkers in the breath of a volunteer:
These chemicals can be indicators of various health conditions. Methane in the breath, for example, can indicate intestinal problems.
The researchers say the JILA breathalyzer also could detect six additional biomarkers of disease without any further modifications to the device. They would include:
NIST/JILA Research Fellows Jun Ye, PhD (left), and David Nesbitt, PhD (right) of the University of Colorado Boulder, “built a breathalyzer that identifies biomarkers of disease by measuring the colors and amounts of light absorbed as a laser frequency comb passes through breath samples inside a glass tube,” according to an NIST news release. Should they succeed in creating a portable version, their noninvasive device could become an option compared to conventional clinical laboratory blood testing methods used to identify and monitor diseases. (Photos copyright: University of Colorado Boulder.)
“Determining the identity and concentration of the molecules present in breath is a powerful tool to assess the overall health of a person, analogous to blood testing in clinical medicine, but in a faster and less invasive manner,” the researchers wrote in PNAS.
“The presence of a particular molecule (or combination of molecules) can indicate the presence of a certain health condition or infection, facilitating a diagnosis. Monitoring the concentration of the molecules of interest over time can help track the development (or recurrence) of a condition, as well as the effectiveness of the administered treatment,” they added.
How the JILA Breathalyzer Detects Biomarkers
According to a 2008 NIST news release, JILA researchers had developed a prototype comb breathalyzer in that year. However, the research did not continue. But then the COVID-19 pandemic brought the JILA/NIST laboratories focus back to the breathalyzer with hopes that new research could lead to a breath test for detecting the SARS-CoV-2 coronavirus and other conditions.
“We are really quite optimistic and committed to pushing this technology to real medical applications,” Ye said in the 2021 NIST news release.
Analytical Scientist explained that JILA’s new and improved breathalyzer system “fingerprints” chemicals by measuring the amount of light absorbed as a laser frequency comb passes back and forth through breath samples loaded into a mirrored glass tube.
JILA’s original 13-year-old prototype comb analyzed colors and amounts of light in the near-infrared band. However, JILA’s recent improvements include advances in optical coatings and a shift to analyzing mid-infrared band light, allowing detection sensitivity up to parts-per-trillion level, a thousand-fold improvement over the prototype.
Corresponding study author Jutta Toscano, PhD, postdoctoral researcher at the University of Basel in Switzerland and previously Lindemann fellow at JILA, told Physics World the new frequency comb can “probe the molecular fingerprint region where fundamental, and more intense, spectroscopic transitions are found.
“By matching the frequency of the comb teeth with the cavity modes—the ‘standing modes’ of the cavity—we can increase the interaction path length between molecules inside the cavity and laser light by a factor of around 4000, equivalent to an effective path length of a few kilometers,” she added. “We then probe the light that leaks out of the cavity by sending it into an FTIR [Fourier-transform infrared] spectrometer to find out which exact comb teeth have been absorbed and by how much. In turn, this tells us which molecules are present in the breath sample and their concentration.”
Even Hippocrates Studied Breath
Ye noted in the NIST statement that JILA is the only institution that has published research on comb breathalyzers.
In their PNAS paper, the researchers wrote, “Breath analysis is an exceptionally promising and rapidly developing field of research, which examines the molecular composition of exhaled breath. … Despite its distinctive advantages of being a rapid, noninvasive technique and its long history dating back to Hippocrates, breath analysis has not yet been as widely deployed for routine diagnostics and monitoring as other methods, such as blood-based analysis.
“We have shown that this technique offers unique advantages and opportunities for the detection of light biomarkers in breath,” the researchers noted, “and it is poised to facilitate real-time, noninvasive monitoring of breath for clinical studies, as well as for early detection and long-term monitoring of temporary and permanent health conditions.”
Validation of these findings and further design research to make the system portable are required before JILA’s frequency comb breathalyzer can become a competitor to clinical laboratory blood tests for disease identification and monitoring. Nevertheless, JILA’s research brings breathalyzer technology a step closer to offering real-time, non-invasive analysis of human biomarkers for disease.
CDC asks physicians and clinical laboratories to be on the lookout and report symptoms of hepatitis to state health departments
Growing incidences of hepatitis in children are perplexing medical professionals and researchers in several countries around the world. The mysterious outbreak is occurring in otherwise healthy children and, to date, is of unknown origin, though an adenovirus may be involved.
Microbiologists and clinical laboratory scientists who perform virology testing may want to prepare for increased numbers of children presenting with hepatitis symptoms in the US.
On April 21, the Centers for Disease Control and Prevention (CDC) issued a nationwide health alert to notify the public about a cluster of children in Alabama who presented with hepatitis and adenovirus infections. The CDC asked physicians to watch for symptoms in children and to inform local and state health departments of any new suspected cases.
Also in April, the World Health Organization (WHO) issued its own alert to an outbreak of acute hepatitis of unknown etiology among young children in several countries. In addition to the United States, cases were reported in the United Kingdom, Spain, Israel, Denmark, Ireland, the Netherlands, Italy, Norway, France, Romania, and Belgium.
All the cases reported to the WHO involved children between one month and 16 years of age with the majority of cases occurring in children under five.
According to NBC News, as of May 19, the worldwide number of cases “under investigation” had reached 600 in more than 25 countries. In the US, more than 90% of the patients required hospitalization and 14% of those patients needed a liver transplant. The CDC is investigating five pediatric deaths that may be attributed to the mysterious hepatitis outbreak.
“Fifteen days ago, CDC issued a nationwide health alert to notify clinicians and public health authorities about an investigation involving nine children in Alabama identified between October of 2021 and February of 2022 with hepatitis or inflammation of the liver and adenovirus infection,” said pediatrician and epidemiologist Jay Butler, MD (above), Deputy Director for Infectious Diseases at the CDC. “We’re casting a broad net to increase our understanding,” he added. “As we learn more, we’ll share additional information and updates.” Hospital-based clinical laboratories that support emergency departments and urgent care centers with testing for hepatitis will want to monitor for upcoming CDC alerts. (Photo copyright: John Amis/AP/CNN.)
Adenovirus/SARS-CoV-2 May Be Linked to Hepatitis Outbreak
The cause of the hepatitis outbreak is as yet undetermined, but the pre-eminent theory among disease experts points to the presence of an adenovirus, which often causes cold and flu-like symptoms in addition to stomach issues.
NBC News reported that more than half of the US patients, 72% of the UK patients, and 60% of the affected patients across Europe tested positive for human adenovirus type 41. This virus, however, is generally not associated with hepatitis in healthy children, and rarely impacts the liver so severely.
Medical experts are also considering the possibility that COVID-19 infections could somehow be an underlying cause since the hepatitis outbreak occurred during the pandemic. The WHO is investigating whether exposure to the SARS-CoV-2 coronavirus might have prompted the immune systems in the infected children to react abnormally to adenoviruses that are typically non-life threatening.
“The big focus over the next week is really looking at the serological testing for previous exposure and infections with COVID,” Phillipa Easterbrook, MD, a senior scientist at the WHO headquarters in Geneva, told NBC News.
Hepatitis, or inflammation of the liver, is typically caused by heavy alcohol use, exposure to toxins, certain medical conditions and medications, or a virus.
The most recent children diagnosed with hepatitis presented with some or most of these symptoms, particularly stomach issues and fatigue. However, one symptom was present in all the children.
“The big symptom that made all of these kids different was that they all showed signs of jaundice, which is the yellowish coloration of the skin and eyes,” Markus Buchfellner, MD, a pediatric infectious disease fellow at the University of Alabama, told NBC News.
Buchfellner was the first person in the US to notice an unusual pattern of hepatitis among children. He reported his findings to the CDC last fall in 2021.
“We were able to uncover the possible association with the adenovirus 41 strain because it is our standard practice to screen patients diagnosed with hepatitis for adenovirus,” he said. “For us to dig deeper into this medical mystery and see if this strain is the cause of these severe hepatitis cases, we first need more data on how widespread the outbreak is.”
Adenovirus 41 is usually spread through fecal matter, which makes hand washing critical, especially after visits to the bathroom or diaper changes. This type of adenovirus typically presents as diarrhea, vomiting, and fever, and is often accompanied by respiratory issues.
Clinical Labs Performing Gene Sequencing Can Help
Medical scientists around the world are responding to this threat to the youngest and most vulnerable among us. Research is underway into identifying additional cases, determining what is causing the hepatitis globally among children, and establishing preventative measures.
Pathologists and clinical laboratory managers in the US will want to be on the alert for positive hepatitis tests in children whose specimens were tested at their facilities. With advances in gene sequencing that make testing economical and expeditious, more labs have the ability to not only detect hepatitis, but also to identify any genetic variants that may be associated with the increased number of pediatric hepatitis cases appearing around the world.
As demand for DTC at-home genetic testing increases among consumers and healthcare professionals, clinical laboratories that offer similar assays may want to offer their own DTC testing program
Things are happening in the direct-to-consumer (DTC) medical laboratory testing market. Prior to the pandemic, the number of consumers interested in ordering their own diagnostic tests grew at a rapid rate. The SARS-CoV-2 outbreak, however, and the need for consumers to access COVID-19 tests, caused DTC test sales to skyrocket.
One company benefiting from the DTC trend is New York City-based LetsGetChecked. In March, it announced its acquisition of Veritas Genetics which included that company’s Veritas Intercontinental business division. No purchase price was disclosed.
LetsGetChecked describes itself as a “virtual care company that allows customers to manage their health from home, providing direct access to telehealth services, pharmacy, and [clinical] laboratory tests with at-home sample collection kits for a wide range of health conditions,” according to the company’s LinkedIn page.
“Through these acquisitions, LetsGetChecked will leverage the power of whole genome sequencing to launch a full lifecycle of personalized healthcare, delivering the most comprehensive health testing and care solution on the market,” said Peter Foley, Founder and CEO of LetsGetChecked in a press release.
“By integrating Veritas Genetics’ and Veritas Intercontinental’s capabilities with LetsGetChecked’s scalable diagnostic and virtual care infrastructure, we are able to turn comprehensive genetic insights into practical recommendations and lifestyle changes, guided by clinical experts,” he added.
“Our mission to deliver the benefits of whole genome sequencing to millions of individuals continues as part of the LetsGetChecked family. I am particularly excited about the opportunity to combine genetic testing with the broad spectrum of virtual and at-home care models offered by LetsGetChecked. I expect these acquisitions will change the future of personalized healthcare as we know it,” said geneticist George Church, PhD, co-founder of Veritas Genetics, and Professor of Health Sciences and Technology at Harvard and MIT, in a press release. (Photo copyright: Wyss Institute at Harvard University.)
Leveraging the Power of Whole Genome Sequencing
To date, LetsGetChecked claims it has delivered nearly three million at-home direct-to-consumer tests and served more than 300 corporate customers with testing services and biometric screening solutions since its founding in 2015.
The company focuses on manufacturing, logistics, and lab analysis in its CAP-accredited, CLIA-certified laboratory in Monrovia, Calif., as well as physician support, and prescription fulfillment. The DTC company’s products include at-home tests for women’s health, men’s health, basic wellness, sexual health, and SARS-CoV-2 testing.
Veritas Genetics also was a DTC testing company co-founded by internationally-known geneticist George Church, PhD. In 2016, the company announced it would deliver a whole human genome sequence (WGS) for just $999—breaking the $1,000 cost barrier for whole genome sequencing.
“There is no more comprehensive genetic test than your whole genome,” Rodrigo Martinez, former Veritas Chief Marketing and Design Officer, told CNBC. “So, this is a clear signal that the whole genome is basically going to replace all other genetic tests. And this [price drop] gets it closer and closer and closer.”
That market strategy did not succeed. By the end of 2019, the company announced it would cease operations in the United States but continue operations in Europe and Latin America. It has sought a buyer for the company since that time. Now, almost three years later, LetsGetChecked will become the new owner of Veritas Genetics.
Veritas’ primary product, myGenome was launched in 2018 as a whole genome sequencing and interpretation service to help consumers improve their health and increase longevity. The myGenome test screens for and provides insight on many hereditary diseases such as cancer, cardiovascular disease, and neurological disorders. It also provides observations on more than 50 personal traits and ancestry information.
In addition to bringing whole genome sequencing abilities to its test offerings for consumers, LetsGetChecked hopes the acquisitions will create new testing capabilities such as pharmacogenomics, cancer and viral screenings, and maternal fetal screenings.
“By integrating Veritas Genetics’ and Veritas Intercontinental’s genetics offering with our scalable virtual care infrastructure, we are able to leverage the power of whole genome sequencing to launch a full lifecycle of personalized healthcare, which has always been our goal,” Foley told MobiHealthNews.
Veritas Genetics and Veritas Intercontinental will continue to operate under the LetsGetChecked family of companies.
BioIQ also Acquired by LetsGetChecked
In early May, LetsGetChecked also acquired diagnostic testing and health improvement technology company BioIQ, which will continue to operate as a wholly-owned subsidiary.
BioIQ offers at-home tests, health screenings, and vaccinations to consumers. The company’s products include:
Heart health panel,
Lipid panel,
Respiratory panel,
Prevention panel, and
Wellness panel.
Individual tests offered by BioIQ include:
A1C,
COVID-19,
Hepatitis C test and
Sexually transmitted diseases.
BioIQ also offer e-vouchers for health screenings and vaccinations at participating retail pharmacies, clinical laboratories, and physician’s offices.
“The future of healthcare is in providing high-quality at-home diagnostics and care that comprehensively serve an individual’s health needs throughout their whole life,” said Foley in a press release about the BioIQ acquisition. “With this acquisition, LetsGetChecked gains a trusted partner with an extensive knowledge base and a breadth of experience in serving health plans and employer markets to deliver healthcare solutions at scale.”
These acquisitions by LetsGetChecked demonstrate how genetic testing companies are pivoting to new strategies. Clinical laboratories that perform genetic testing will want to monitor how these partnerships unfold in the future as healthcare consumers and providers continue to embrace at-home genetic testing.
Federal agents allege ‘healthcare fraud abuses erode the integrity and trust patients have with those in the healthcare industry’
Here’s yet another example of how federal and state law enforcement agencies intend to further crack down on fraud involving COVID-19 testing, financial relief programs, vaccination cards, and other pandemic-related programs.
The United States Department of Justice (DOJ) announced it has charged the owners of a Calif. clinical laboratory—as well as 19 other defendants—for their roles in fraudulent billing, kickbacks, and money laundering schemes to defraud Medicare of more than $214 million.
Imran Shams and Lourdes Navarro—owners of Matias Clinical Laboratory, Inc., in Baldwin Park, Glendale, Calif.—which was doing business as Health Care Providers Laboratory, Inc. (Matias)—were charged along with the other defendants with participating in fraud that took place in nine federal court districts.
The indictment alleges the pair paid kickbacks to marketers to obtain specimens and test orders. The lab company owners then laundered their profits through shell corporations in the US, transferred the money to foreign countries, and used it to purchase “real estate, luxury items, and goods and services for their personal use,” according to court documents.
“While millions of Americans were suffering and desperately seeking testing and treatment for COVID-19, some saw an opportunity for profit,” said Assistant Attorney General for the Criminal Division Kenneth A. Polite Jr., JD, during a news conference at the Justice Department, The New York Times reported.
“The actions of these criminals are unacceptable, and the FBI, working in coordination with our law enforcement partners, will continue to investigate and pursue those who exploit the integrity of the healthcare industry for profit,” said Luis Quesada of the Federal Bureau of Investigation’s (FBI) Criminal Investigative Division in a press release.
“Throughout the pandemic, we have seen trusted medical professionals orchestrate and carry out egregious crimes against their patients all for financial gain,” said Assistant Director Luis Quesada (above) of the FBI’s Criminal Investigative Division in a DOJ press release. “These healthcare fraud abuses erode the integrity and trust patients have with those in the healthcare industry, particularly during a vulnerable and worrisome time for many individuals.” Clinical laboratories throughout the US should be aware of increased scrutiny to Medicare billing by the DOJ. (Photo copyright: El Paso Times.)
According to the DOJ’s Summary of Criminal Charges, “Matias” Clinical Laboratory also “performed and billed Medicare for urinalysis, routine blood work, and other tests, despite the fact that Shams had been excluded from all participation in Medicare for several decades.” The indictment alleges that Shams and Navarro fraudulently concealed Sham’s role in the clinical laboratory and his prior healthcare-related criminal convictions.
“She always tried to follow the law and provide appropriate and quality testing services to the laboratory’s patients. She looks forward to clearing her name in court,” Werksman said.
However, both Navarro and Shams have a checkered past with law enforcement agencies. According to a State of California Department of Justice news release, in 2000, the two were convicted in California on felony counts of Medi-Cal fraud, grand theft, money laundering, and identity theft for using the names of legitimate physicians without permission and filing thousands of false claims with the state for medical tests never performed.
The Calif. Attorney General’s Division of Medi-Cal Fraud and Elder Abuse (DMFEA) seized approximately $1.1 million in uncashed warrants, which were returned to the Medi-Cal program. Since the 2000 case, Shams has been barred from filing for Medicare reimbursement, the New York Times reported.
Other Felony Indictments and Criminal Complaints for Healthcare Fraud
In a separate case, the DOJ announced Ron K. Elfenbein, MD, 47, of Arnold, Md., was charged by indictment with three counts of healthcare fraud in connection with an alleged scheme to defraud the US of more than $1.5 million in claims that were billed in connection with COVID-19 testing. Elfenbein is owner and medical director of Drs Ergent Care, LLC, which operates as FirstCall Medical Center. Elfenbein allegedly told his employees to submit claims to Medicare and other insurers for “moderate-complexity office visits” even though the COVID-19 test patients’ visits lasted five minutes or less.
And in April, the DOJ filed a criminal complaint against Colorado resident, Robert Van Camp, 53, for allegedly forging and selling hundreds of fake COVID-19 vaccination cards, which he sold to buyers and distributors in at least a dozen states.
“Van Camp allegedly told an undercover agent that he had sold cards to ‘people that are going to the Olympics in Tokyo, three Olympians and their coach in Tokyo, Amsterdam, Hawaii, Costa Rica, Honduras,’” the DOJ said in a news release, CNBC reported.
Van Camp also allegedly told that agent, “I’ve got a company, a veterinary company, has 30 people going to Canada every f— day, Canada back. Mexico is big. And like I said, I’m in 12 or 13 states, so until I get caught and go to jail, f— it, I’m taking the money, (laughs)! I don’t care,” the DOJ stated.
Clinical laboratory directors and pathologists know these fraud charges provide another example of how the misdeeds of a few reflect on the entire healthcare industry, potentially causing people to lose trust in organizations tasked with providing their healthcare.
Tiny sensors with Bluetooth technology that measure useful biomarkers may eliminate need for invasive blood draws used for clinical laboratory tests
What if a baby’s pacifier could be used to measure electrolyte levels in newborns? An international research team has developed just such a device, and it has the potential to reduce invasive blood collections required to provide specimens for clinical laboratory testing of critical biomarkers. At the same time, this device may allow continuous monitoring of electrolyte levels with wireless alerts to caregivers.
Typical blood draws for NICU babies can cause information gaps as they are usually only performed twice a day. This can be problematic in cases where more frequent monitoring of these biomarkers is required to monitor the infant’s condition.
“We know that premature babies have a better chance of survival if they get a high quality of care in the first month of birth,” said Jong-Hoon Kim, PhD, Associate Professor at the WSU School of Electrical Engineering and Computer Science, in a WSU news release. “Normally, in a hospital environment, they draw blood from the baby twice a day, so they just get two data points. This device is a non-invasive way to provide real-time monitoring of the electrolyte concentration of babies.”
The smart pacifier (above) developed by researchers at the Washington State University School of Electrical Engineering and Computer Science—in collaboration with scientists in two South Korean institutions—provides continuous monitoring of sodium and potassium ion levels. This can help detect and prevent potentially dangerous dehydration issues in NICU babies without invasive blood draws for traditional clinical laboratory testing. (Photo copyright: University of Washington.)
How the Smart Pacifier Works
The miniature system developed by the WSU researchers utilizes a typical, commercially available pacifier outfitted with ion-selective sensors, flexible circuits, and microfluidic channels that monitor salivary electrolytes. These flexible, microfluidic channels attract the saliva when the pacifier is in the infant’s mouth which enables continuous and efficient saliva collection without the need for any type of pumping system. The gathered data is relayed wirelessly to caregivers using Bluetooth technology.
When the researchers tested their smart pacifier on infants, they discovered that the results captured from the device were comparable to information obtained from normal blood draws and standard clinical laboratory tests. Kim noted in the press release that technology currently in use to test infant saliva for electrolytes tend to be bulky, rigid devices that require a separate sample collection.
“You often see NICU pictures where babies are hooked up to a bunch of wires to check their health conditions such as their heart rate, the respiratory rate, body temperature, and blood pressure,” said Kim in the press release. “We want to get rid of those wires.”
The researchers intend to make the components for the device more affordable and recyclable. They also plan to perform testing for their smart pacifier on larger test groups to prove efficacy and hope the gadget will help make NICU treatment less disruptive for infant patients.
Going as far back as 2013, Dark Daily has covered research into the use of sensors placed in wearables and disposables to detect and monitor health issues.
“It should be noted that the ability to put reliable diagnostic sensors in disposables like diapers has been around for almost a decade and does not seem to have caught on with either caregivers or the public,” said Robert Michel, Editor-in-Chief of Dark Daily and its sister publication, The Dark Report. “Because the researchers who developed the pacifier are attempting to solve a problem for NICU babies, this solution might find acceptance.”
This is another example of how researchers are thinking outside the box as to how to measure critical biomarkers without the need to send a specimen to the core clinical laboratory and wait hours—sometimes overnight—for results.
