Author: Stephanie Leisso

Enterovirus-68: Why is it a public health risk? How can wastewater-based epidemiology identify outbreaks?

Posted on by Stephanie Leisso

What is Enterovirus D68?

EV-D68 is a non-polio enterovirus that often leads to very mild symptoms such as runny nose, sneezing, and mild coughing (Hixon et al, 2019; Non-Polio Enterovirus, CDC). Children, particularly those with asthma or other respiratory conditions, are at higher risk for complications.

In 2014, EV-D68 gained national attention due to its association with accute flacid myelitis (AFM). This neurological condition is rare and leads to weakness in limbs, as well as the loss of muscle tone and reflexes.  Most AFM cases occur in children, and there is no vaccine available against EV-D68.

Wastewater surveillance as a public health tool in the fight against EV-D68

EV-D68 outbreaks tend to follow a biennial pattern, with spikes observed in 2014, 2016, 2018, and again in 2022 and 2024 (Nguyen-Tran et al. 2025). These outbreaks have coincided with increases in AFM cases, prompting the CDC to initiate active surveillance programs. As such, 2026 may be another year with a spike in EV-D68 cases.

Key advantages of WBE for EV-D68:

  • Early Detection: Viral RNA from EV-D68 can be detected in wastewater before clinical cases are reported, allowing for proactive public health responses.
  • Community-Level Monitoring: WBE captures data from symptomatic and asymptomatic individuals, offering a more comprehensive view of virus circulation (Mangeri et al, 2025).
  • Cost-Effective Surveillance: Compared to individual testing, wastewater sampling is scalable and efficient.

In California, researchers tracked EV-D68 RNA in wastewater solids over 26 months. They found that viral concentrations spiked between July and December 2022, aligning with confirmed clinical cases and AFM diagnoses. Similar studies in Israel and Colorado have demonstrated strong correlations between wastewater data and clinical surveillance, reinforcing the value of multimodal monitoring. [wwwnc.cdc.gov] [mdpi.com], [wwwnc.cdc.gov]

Looking ahead: Strengthening public health preparedness

As EV-D68 continues to circulate and evolve, integrating wastewater surveillance into routine public health monitoring can enhance outbreak preparedness. These data can offer health authorities a better understanding of transmission dynamics and emerging strains and ultimately allow them to allocate resources effectively.

At GT Molecular, we are committed to advancing molecular tools that support wastewater surveillance and pathogen detection. Our technologies empower communities to stay ahead of outbreaks and protect vulnerable populations.

ESR1 testing with digital PCR: A powerful tool for precision oncology

Posted on by Stephanie Leisso

Why do ESR1 mutations matter?

The ESR1 gene encodes estrogen receptor alpha (ERα), a transcription factor that drives tumor growth in ER+ disease. Acquired mutations in ESR1—especially in the ligand-binding domain such as Y537S, Y537N, Y537C, and D538G—can lock the receptor in an active state even in the absence of estrogen. These mutations have been linked to resistance to aromatase inhibitors and can influence choices of alternative therapies. Because ESR1 mutations often evolve under treatment pressure, their timely, accurate detection is crucial.

The case for liquid biopsy

Traditional tissue biopsies can be invasive and may not capture the full genomic diversity of metastatic disease. Liquid biopsy using circulating tumor DNA (ctDNA) offers a minimally invasive alternative that enables longitudinal monitoring. However, ctDNA often circulates at very low levels (as low as ~0.1% mutant allele fraction), which places high demands on the analytical sensitivity of testing methods.

Digital PCR vs. Next-Generation Sequencing for ESR1 testing

Digital PCR (dPCR)

Digital PCR partitions DNA into thousands of individual reactions and scores each for the presence or absence of target sequences. This approach allows absolute quantification without standard curves and pushes analytical sensitivity to very low variant allele frequencies (VAFs).

Key strengths of dPCR for ESR1 testing:

  • High sensitivity for known mutations: dPCR routinely detects ESR1 hotspot mutations at allele frequencies below 1%, even down toward ~0.1% or lower in well-optimized assays. (Raei, et al.)
  • Absolute quantification: Provides precise counts of mutant and wild-type alleles without standard curves.
  • Fast turnaround and simpler data: No complex bioinformatics required compared to sequencing.
  • Ideal for monitoring over time: Accurate, quantitative tracking of a known mutation burden as disease evolves.

Limitations:

  • Detects predetermined targets only—you must know which mutations you’re looking for in advance. dPCR is not designed for discovery of novel mutations outside the assay’s scope. (ESRI Biomarker testing, Eli Lilly)
  • Limited multiplexing compared with NGS (though newer panels like GT Molecular’s can multiplex several targets in one well). (GT Molecular ESR1 Panels)

Next-Generation Sequencing (NGS)

NGS provides a high-throughput approach that reads many DNA fragments in parallel, enabling comprehensive profiling of multiple genes and variants in a single run.

Key strengths of NGS for ESR1 testing:

Limitations:

  • Lower sensitivity at very low allele frequencies: Meta-analyses show that dPCR often outperforms NGS in sensitivity for detecting low-frequency ESR1 mutations in ctDNA. For example, sensitivity for dPCR in some studies was ~81% vs. ~57% for NGS. (Raei, et al.)
  • Longer turnaround and complex analysis: Sequencing workflows and bioinformatics can extend result times and require specialized expertise.
  • Potential higher cost per run: Especially when deep coverage is needed for low VAF detection.

When to use which method

In practical terms, many laboratories use both technologies in a complementary framework:

  • Use NGS initially to broadly profile tumors (including ESR1 and other genes), especially if unknown variants might be relevant.
  • Use dPCR for follow-up monitoring of known ESR1 mutations over time or in liquid biopsy when very small amounts of mutant DNA are expected. (Adorisio, et al.)

This integrated approach ensures both discovery power and sensitive longitudinal monitoring.

Why is Digital PCR a go-to tool for ESR1 testing?

Digital PCR’s combination of high analytical sensitivity, absolute quantification, and robust performance in liquid biopsy samples makes it an excellent choice for ESR1 mutation detection. It enables clinicians and researchers to:

  • Detect clinically important ESR1 mutations before radiographic progression
  • Track changes in mutation burden during therapy
  • Inform timely decisions about switching endocrine therapy or enrolling patients in clinical trials

By complementing broad sequencing efforts with focused, high-sensitivity testing, dPCR enhances molecular insight into treatment resistance.

GT Molecular’s dPCR ESR1 Testing Kit

For laboratories and research groups looking for a high-performance digital PCR solution for ESR1 mutation analysis, the GT-Plex™ ESR1 Mutation Panel from GT Molecular offers a powerful option. This multiplexed dPCR kit detects nine common ESR1 hotspot mutations plus wild-type ESR1 in a single well, enabling sensitive and specific quantification even in low-yield ctDNA samples. Designed for compatibility with widely used dPCR platforms, the kit includes all primers, probes, and controls to streamline workflows and support robust research results. (GT Molecular ESR1 Panel)

Whether you’re monitoring endocrine resistance during therapy or conducting preclinical research on breast cancer evolution, GT Molecular’s dPCR ESR1 testing kit provides a practical, high-sensitivity tool to deepen your molecular insights.

Whether you’re monitoring endocrine resistance during therapy or conducting preclinical research on breast cancer evolution, GT Molecular’s dPCR ESR1 testing kit provides a practical, high-sensitivity tool to deepen your molecular insights.