Test Results of Fingerstick Blood Vary Significantly
By LabMedica International staff writers Posted on 29 Nov 2015 |
Image: Blood obtained via fingerstick is commonly used in point-of-care assays (Photo courtesy of The Health).
Blood obtained via fingerstick is commonly used in point-of-care assays, but few studies have assessed variability in parameters obtained from successive drops of fingerstick blood, which may cause problems for clinical decision making and for assessing accuracy of point-of-care tests.
The most accurate way to carry out medial laboratory tests is to draw blood from a vein and send it to a laboratory but sometimes, such as in low-resource settings, results are needed more rapidly, or the health professional is not trained to draw vein-blood, or there is no laboratory. In such settings, there is a higher reliance on fingerstick tests.
Bioengineers at Rice University (Houston, TX, USA) used a hematology analyzer to analyze the hemoglobin concentration, total white blood cell (WBC) count, three-part WBC differential, and platelet count in six successive 20 µL of blood collected from one fingerstick from each of 11 donors. The team used a hemoglobinometer to measure the hemoglobin concentration of 10 drops of fingerstick blood from each of seven donors to check whether the minimum droplet size made a difference and they checked all the results against blood taken from donors' veins. They also followed best practice to ensure accurate results. For example, they wiped away the first droplet to remove traces of disinfectant, and they did not squeeze or "milk" the finger.
The results showed that hemoglobin content, platelet count and white blood cell count varied significantly from drop to drop. The average percent coefficient of variation (CV) for successive drops of fingerstick blood was higher by up to 3.4 times for hemoglobin, 5.7 times for WBC count, three times for lymphocyte count, 7.7 times for granulocyte count, and four times for platelets than in venous controls measured using a hematology analyzer. The average percent CV for fingerstick blood was up to five times higher for hemoglobin than venous blood measured using a point-of-care hemoglobinometer. The investigators found that averaging the results of six to nine successive droplet tests produced results on a par with the venous blood tests.
Meaghan M. Bond, a doctoral student and first author of the study, said, “In some donors, the hemoglobin concentration changed by more than 2 g/dL in the span of two successive drops of blood. Our results show that people need to take care to administer fingerstick tests in a way that produces accurate results because accuracy in these tests is increasingly important for diagnosing conditions like anemia, infections and sickle-cell anemia, malaria, HIV and other diseases.” The study was published on November 18, 2015, in the American Journal of Clinical Pathology.
Related Links:
Rice University
The most accurate way to carry out medial laboratory tests is to draw blood from a vein and send it to a laboratory but sometimes, such as in low-resource settings, results are needed more rapidly, or the health professional is not trained to draw vein-blood, or there is no laboratory. In such settings, there is a higher reliance on fingerstick tests.
Bioengineers at Rice University (Houston, TX, USA) used a hematology analyzer to analyze the hemoglobin concentration, total white blood cell (WBC) count, three-part WBC differential, and platelet count in six successive 20 µL of blood collected from one fingerstick from each of 11 donors. The team used a hemoglobinometer to measure the hemoglobin concentration of 10 drops of fingerstick blood from each of seven donors to check whether the minimum droplet size made a difference and they checked all the results against blood taken from donors' veins. They also followed best practice to ensure accurate results. For example, they wiped away the first droplet to remove traces of disinfectant, and they did not squeeze or "milk" the finger.
The results showed that hemoglobin content, platelet count and white blood cell count varied significantly from drop to drop. The average percent coefficient of variation (CV) for successive drops of fingerstick blood was higher by up to 3.4 times for hemoglobin, 5.7 times for WBC count, three times for lymphocyte count, 7.7 times for granulocyte count, and four times for platelets than in venous controls measured using a hematology analyzer. The average percent CV for fingerstick blood was up to five times higher for hemoglobin than venous blood measured using a point-of-care hemoglobinometer. The investigators found that averaging the results of six to nine successive droplet tests produced results on a par with the venous blood tests.
Meaghan M. Bond, a doctoral student and first author of the study, said, “In some donors, the hemoglobin concentration changed by more than 2 g/dL in the span of two successive drops of blood. Our results show that people need to take care to administer fingerstick tests in a way that produces accurate results because accuracy in these tests is increasingly important for diagnosing conditions like anemia, infections and sickle-cell anemia, malaria, HIV and other diseases.” The study was published on November 18, 2015, in the American Journal of Clinical Pathology.
Related Links:
Rice University
Latest Technology News
- New Diagnostic System Achieves PCR Testing Accuracy
- DNA Biosensor Enables Early Diagnosis of Cervical Cancer
- Self-Heating Microfluidic Devices Can Detect Diseases in Tiny Blood or Fluid Samples
- Breakthrough in Diagnostic Technology Could Make On-The-Spot Testing Widely Accessible
- First of Its Kind Technology Detects Glucose in Human Saliva
- Electrochemical Device Identifies People at Higher Risk for Osteoporosis Using Single Blood Drop
- Novel Noninvasive Test Detects Malaria Infection without Blood Sample
- Portable Optofluidic Sensing Devices Could Simultaneously Perform Variety of Medical Tests
- Point-of-Care Software Solution Helps Manage Disparate POCT Scenarios across Patient Testing Locations
- Electronic Biosensor Detects Biomarkers in Whole Blood Samples without Addition of Reagents
- Breakthrough Test Detects Biological Markers Related to Wider Variety of Cancers
- Rapid POC Sensing Kit to Determine Gut Health from Blood Serum and Stool Samples
- Device Converts Smartphone into Fluorescence Microscope for Just USD 50
- Wi-Fi Enabled Handheld Tube Reader Designed for Easy Portability