Discovery could lead to new clinical laboratory testing for cancer screening in new mothers
Any clinical laboratory test that returns unexpected results is worth looking into more deeply. Such was the case with a recent study conducted by the National Institutes of Health (NIH), which investigated cases of pregnant women who received “unusual” results to prenatal lab tests conducted at a dozen labs in North America.
Following cancer screening protocols that included rapid whole-body magnetic resonance imaging, NIH scientists discovered “previously undetected cancers in 48.6% of pregnant people who had abnormal results for prenatal cell-free DNA (cfDNA) testing used to screen for chromosomal disorders in the fetus,” according to an NIH news release.
“They looked like healthy young women, and they reported themselves as being healthy,” Diana Bianchi, MD, head of the Prenatal Genomics and Therapy Section for the Medical Genetics Branch at the NIH’s National Human Genetics Research Institute, and senior author of the government study, told the Associated Press (AP).
While cfDNA tests are not diagnostic, pathologists and clinical laboratory managers involved in genetic testing are likely familiar with them. The blood tests are used by expectant mothers to assess risk of a fetus with an abnormal number of chromosomes that could suggest disorders such as Down Syndrome, according to ARUP Laboratories.
Unexpected results from tests draw attention. This one seems to have a chance to get more traction with labs because the results point to a prenatal test having some success predicting cancer, even if incidentally.
“[The study participants] and their care providers need to take the results seriously and have additional testing because in that population there is a 48% risk of cancer,” Diana Bianchi, MD, senior author of the NIH study, told the AP. (Photo copyright: National Institutes of Health.)
Cancer Found in about Half of Those with Abnormal cfDNA
The NIH researchers started a long-term study, called IDENTIFY, to learn more about abnormal cfDNA results that could suggest cancer. Study participants must be:
Pregnant or postpartum with no known cancer.
Recipients of “unusual clinical cfDNA-sequencing results or results that are non-reportable (fetal aneuploidy status could not be assessed) from one of 12 different commercial laboratories,” they wrote in NEJM.
For the study’s initial cohort of 107 participants, researchers repeated cfDNA sequencing testing and coordinated standard medical diagnostic tests (such as Pap smears) and whole-body magnetic resonance imaging.
52 women (48.6%) were found to have “hidden cancers.”
32 had blood cancers.
20 had solid tumors in the breast, bile duct, colon, pancreas, lung, kidney, bone, and adrenal gland.
13 of the 20 with solid tumors were able to access “potentially curative treatments.”
55 women did not have cancer and may have obtained an unreliable cfDNA result.
“In this study, 48.6% of participants who received unusual or nonreportable clinical cfDNA-sequencing results had an occult cancer (cancer of unknown primary).
“Further study of DNA-sequencing patterns that are suggestive of occult cancer during prenatal screening is warranted,” the researchers wrote in NEJM.
Follow-Up Testing Needed
Cancers found in the study participants “included colorectal, breast, lung and pancreatic cancers, as well as lymphoma, cholangiocarcinoma and renal carcinoma. The screening test analyzes placental DNA fragments circulating in the maternal bloodstream to identify an extra chromosome or to determine the baby’s sex,” according to the NIH news release.
Bianchi told AP the study results also pointed to a “very chaotic” pattern in DNA-sequencing of women with cancer, and that more research is needed to find out who should be screened for cancer.
Clinical laboratories and pathologists who analyze cfDNA tests could take a leadership role in assessing current standards for the tests, determining how suspicious results are reported, and suggesting needed changes.
The discovery is yet another factor that must be considered when developing a liquid biopsy test clinical laboratories can use to detect cancer
How often do disruptive elements present in Liquid biopsies result in misdiagnoses and unhelpful drug therapies for cancer? Researchers at the University of Washington School of Medicine (UW Medicine) in Seattle wanted to know. And the results of their study provide another useful insight for pathologists about the elements that circulate in human blood which must be understood so that liquid biopsy tests can be developed that are not affected by that factor.
Based on their case series study of 69 men with advanced prostate cancer, the UW Medicine researchers determined that 10% of men have a clonal hematopoiesis of indeterminate potential (CHIP) that can “interfere” with liquid biopsies and cause incorrect reports and unneeded prostate cancer treatment, according to their paper published in the journal JAMA Oncology.
The UW Medicine researchers advised testing for “variants in the cell-free DNA (cfDNA)” shed in blood plasma to enable appropriate treatment for people with already diagnosed prostate cancer, noted to a UW Medicine news release.
According to pathologist Colin Pritchard, MD, PhD, Associate Professor of Laboratory Medicine and Pathology at the UW Medicine, who led the research team, “clonal hematopoiesis can interfere with liquid biopsies. For example, mutations in the genes BRCA1, BRCA2, and ATM have been closely linked to cancer development.
“The good news is that, by looking at the blood cellular compartment, you can tell with pretty good certainty whether something is cancer, or something is hematopoiesis,” he said in the news release.
What Does CHIP Interference Mean to a Clinical Laboratory Blood Test?
In their published study, the UW Medicine researchers stressed the “urgent need to understand cfDNA testing performance and sources of test interferences” in light of recent US Food and Drug Administration (FDA) clearance of two PARP inhibitors (PARPi) for prostate cancer:
“We found that a strikingly high proportion of DNA repair gene variants in the plasma of patients with advanced prostate cancer are attributable to CHIP,” the researchers wrote. “The CHIP variants were strongly correlated with increased age, and even higher than expected by age group.
“The high rate of CHIP may also be influenced by prior exposure to chemotherapy,” they added. “We are concerned that CHIP interference is causing false-positive cfDNA biomarker assessments that may result in patient harm from inappropriate treatment, and delays in delivering alternative effective treatment options.
“Without performing a whole-blood control, seven of 69 patients (10%) would have been misdiagnosed and incorrectly deemed eligible for PARP-inhibitor therapy based on CHIP interference in plasma. In fact, one patient in this series had a BRCA2 CHIP clone that had been previously reported by a commercial laboratory testing company with the recommendation to use a PARPi. To mitigate these risks, cfDNA results should be compared to results from whole-blood control or tumor tissue,” the researchers concluded.
To find the clinically relevant CHIP interference in prostate cancer cfDNA testing, researchers used the UW-OncoPlex assay (developed and clinically available at UW Medicine). The assay is a multiplexed next-generation sequencing panel aimed at detecting mutations in tumor tissues in more than 350 genes, according to the UW Medicine Laboratory and Pathology website.
“To improve cfDNA assay performance, we developed an approach that simultaneously analyzes plasma and paired whole-blood control samples. Using this paired testing approach, we sought to determine to what degree CHIP interferes with the results of prostate cancer cfDNA testing,” the researchers wrote in JAMA Oncology.
Men May Receive Unhelpful Prostate Cancer Drug Therapies
The research team studied test results from 69 men with advanced prostate cancer. They analyzed patients’ plasma cfDNA and whole-blood control samples.
Tumor sequencing enabled detection of germline (cells relating to preceding cells) variants from CHIP clones.
The UW Medicine study suggested CHIP variants “accounted for almost half of the somatic (non-germline) DNA repair mutations” detected by liquid biopsy, according to the news release.
> “About half the time when the plasma is thought to contain a mutation that would guide therapy with these drugs, it actually contains CHIP variants, not prostate cancer DNA variants. That means that in about half of those tested, a patient could be told that he should be administered a drug that is not indicated to treat to his cancer,” said Colin Pritchard, MD, PhD, pathologist and Associate Professor of Laboratory Medicine and Pathology at UW Medicine in the new release. (Photo copyright: University of Washington School of Medicine.)
Other detailed findings of the UW Medicine Study:
CHIP variants of 2% or more were detected in cfDNA from 13 of 69 men.
Seven men, or 10%, having advanced prostate cancer “had CHIP variants in DNA repair genes used to determine PARPi candidacy.
CHIP variants rose with age: 0% in those 40 to 50; 12.5% in men 51 to 60; 6.3% in those 61 to 70; 20.8% in men 71 to 80; and 71% in men 81 to 90.
Whole-blood control made it possible to distinguish prostate cancer variants from CHIP interference variants.
“Men with prostate cancer are at high risk of being misdiagnosed as being eligible for PARPi therapy using current cfDNA tests; assays should use a whole-blood control sample to distinguish CHIP variants from prostate cancer,” the researchers wrote in JAMA Oncology.
Liquid Biopsies Are ‘Here to Stay’
Surgical oncologist William Cance, MD, Chief Medical and Scientific Officer, American Cancer Society (ACS) in Atlanta, recognizes the challenge of tumor biology to liquid biopsies.
“Genetic abnormalities are only one piece of the puzzle. We need to look comprehensively at tumors for the best therapy, from their metabolic changes and protein signatures in the blood to the epigenetic modifications that may occur, as cancers take hold,” he told Oncology Times. “It’s not just shed DNA in the blood.”
The UW Medicine study demonstrates the importance of understanding how all elements in liquid biopsies interact to affect clinical laboratory test results.
“I think liquid biopsies are here to stay,” Cance told Oncology Times. “They’re all part of precision medicine, tailored to the individual.”