LabMedica

Download Mobile App
Recent News Expo ADLM 2026 Clinical Chem. Molecular Diagnostics Hematology Immunology Microbiology Pathology Technology Industry Focus

System Separates Circulating Tumor Cells from Blood Samples, Improves Cancer Diagnostics

By LabMedica International staff writers
Posted on 01 Jul 2022
Image: A new machine rapidly and robustly separates cancer cells from blood samples (Photo courtesy of DGIST)
Image: A new machine rapidly and robustly separates cancer cells from blood samples (Photo courtesy of DGIST)

Circulating tumor cells are cells that break off from cancers and are released into the blood stream. They can go on to form the seeds for new tumor formation in other parts of the body, known as metastases. The advantage of isolating them from the blood is that they represent the diversity of cancer cells found in a person’s body and identifying them could lead to more targeted therapies. But current techniques used to do this either miss some types of circulating tumor cells or are done manually, which takes a lot of time and specialized training. Now, a new approach can successfully and rapidly isolate rare circulating tumor cells from patient blood samples. The findings could help improve cancer diagnosis and the ability to provide targeted and personalized treatments.

The fully automated centrifugation approach developed by scientists at Daegu Gyeongbuk Institute of Science and Technology (DGIST, Daegu, Korea) and CTCELLS (Daegu, Korea) is called Continuous Centrifugal Microfluidics – Circulating Tumor Cell Disc (CCM-CTCD). It involves placing a tube containing a blood sample in a machine with a spinning disc. The spinning, or centrifugal force, causes the blood to separate into layers containing different components, with the heavier red blood cells dropping to the bottom, lighter cells floating in a middle layer, and plasma settling at the top.

After the disc begins to spin, a laser motor starts rotating at the same angular velocity and phase. This crucial step allows a laser to move and open a valve in the blood sample tube while the disc continues to spin, maintaining a thin layer of tumor and white blood cells, which are released into a separate chamber. The chamber contains antibodies that specifically attach to and separate white blood cells from the mixture. This allows the circulating tumor cells in the mixture to flow on their own into a final chamber.

The team went on to identify the different types of tumor cells and confirm by subsequent DNA testing that they represent the full diversity of different types of cells in the blood sample. They also used the technique on blood samples from patients with varying stages of lung cancer and found the number of circulating tumor cells in a sample correlated with the stage of disease progression. Identification of the types of tumor cells also allowed them to modify treatment strategies. The team is now working on commercializing the technique for clinical use and hopes to expand its application to isolate other types of cells, including nerve, stem and immune cells.

“Our smart and practical approach realizes a big dream in the field of liquid biopsy and demonstrates high performance across a wide range of cell types and different cancers with full automation,” said Minseok S. Kim at the Department of New Biology at DGIST.

Related Links:
DGIST 
CTCELLS 

Gold Member
Clinical Chemistry Assay
Sorbitol Dehydrogenase (SDH)
Online QC Software
Acusera 24•7
Electrolyte Analyzer
BKE-B
Clinical Informatics Platform
CLARION™

Channels

Hematology

view channel
Image Credit: Shutterstock

New Biomarkers Predict Resistance to Targeted Therapy in Rare Blood Cancer

Blastic plasmacytoid dendritic cell neoplasm (BPDCN) is a rare and aggressive leukemia with limited treatment options and a poor prognosis. Although tagraxofusp is the first approved targeted therapy for... Read more

Immunology

view channel
Image:Proteomic tear-fluid analysis revealed abnormal patterns in proteins that regulate nerves and T cells in individuals with eye problems (Image Credit: Adobe Stock)

Diagnostic Models Detect Hidden Eye Abnormalities After Mild COVID-19

Persistent ocular symptoms after COVID-19 can severely affect reading, work, and daily tasks, yet standard eye exams often reveal no clear abnormalities. Patients experiencing photophobia, eye pain, and... Read more

Industry

view channel
Photo courtesy of Natera

Natera’s Signatera Earns IVDR Certification for Solid Tumor MRD Testing

Natera’s Signatera has received certification as a Class C device under the European Union’s In Vitro Diagnostic Regulation (IVDR), becoming the first personalized MRD test for solid tumors to achieve... Read more
PURITAN MEDICAL