Point-of-care tests are simple medical tests that can be performed at the bedside. In many cases, the simplicity was not achievable until
technology developed not only to make a test possible at all but then also to mask its complexity. For example, various kinds of
urine test strips have been available for decades, but
portable ultrasonography did not reach the stage of being advanced, affordable, and widespread until the 2000s and 2010s. Today, portable ultrasonography is often viewed as a "simple" test, but there was nothing simple about it until the more complex technology was available. Similarly,
pulse oximetry can test arterial
oxygen saturation in a quick, simple, noninvasive, affordable way today, but in earlier eras this required an intra-arterial needle puncture and a laboratory test; and
rapid diagnostic tests such as
malaria antigen detection tests or
COVID-19 rapid tests that rely on a
state of the art in
immunology that did not exist until recent decades. Thus, over decades, testing continues to move toward the point of care more than it formerly had been. A recent survey in five countries (Australia, Belgium, the Netherlands, the UK and the US) indicates that general practitioners / family doctors would like to use more POCTs. The driving notion behind POCT is to bring the test conveniently and immediately to the patient. This increases the likelihood that the patient, physician, and care team will receive the results quicker, which allows for better immediate clinical management decisions to be made. In addition, this technology enables remote communities as First Nations people, to have access to laboratory testing, thereby allowing for more assertive health care. POCT includes: blood glucose testing, blood gas and electrolytes analysis, rapid coagulation testing, rapid cardiac markers diagnostics, drugs of abuse screening, urine strips testing, pregnancy testing, fecal occult blood analysis, food pathogens screening, hemoglobin diagnostics, infectious disease testing (such as
COVID-19 rapid tests), cholesterol screening and emerging technologies in micronutrient deficiency screening and diagnosis of acute febrile illness.
Lab-on-a-chip technologies are one of the main drivers of point-of-care testing, especially in the field of
infectious disease diagnosis. These technologies enable different
bioassays such as
microbiological culture,
PCR,
ELISA to be used at the point of care. POCT is often accomplished through the use of transportable, portable, and handheld instruments (e.g.,
blood glucose meter,
nerve conduction study device) and test kits (e.g., CRP, HBA1C, Homocystein, HIV salivary assay, etc.). Small bench analyzers or fixed equipment can also be used when a handheld device is not available—the goal is to collect the specimen and obtain the results in a very short period of time at or near the location of the patient so that the treatment plan can be adjusted as necessary before the patient leaves. Cheaper, faster, and smarter POCT devices have increased the use of POCT approaches by making it cost-effective for many diseases, such as
diabetes,
carpal tunnel syndrome (CTS) and
acute coronary syndrome. Additionally, it is very desirable to measure various analytes simultaneously in the same specimen, allowing a rapid, low-cost, and reliable quantification. Therefore,
multiplexed point-of-care testing (xPOCT) has become more important for
medical diagnostics in the last decade. Many
point-of-care test systems are realized as easy-to-use membrane-based test strips, often enclosed by a plastic test cassette. These tests require only a single drop of whole blood, urine or saliva, and they can be performed and interpreted by any general physician within minutes. Recently, a portable medical diagnostic device called "BioPoC" has been reported which employs free-standing enzyme-modified responsive polymer membrane-based biosensors and a newly devised low-cost transduction principle for the detection of
H. pylori and urea. During the
COVID-19 pandemic, rapid development of POCT occurred, aiming to improve the turnaround time and ease of use compared to the gold standard lab-based
PCR test. These have included
rapid antigen tests, alternate nucleic acid amplification methods, and novel sensors. A range of test have been developed including
smartphone based platforms, and tests targeting
blood,
saliva,
faecal matter,
urine, and
tears have been proposed. Saliva in particular may offer sufficiently high detection rates in tandem with a
non-invasive and user friendly procedure, although reliability requires improvement. Emerging technology at the
point of care setting is being developed to allow for rapid assessment of
micronutrient deficiency. The Cornell NutriPhone is a promising technology for determining nutritional status at the point of care. This technology allows assessment of
iron,
vitamin A, and
vitamin B12 from a single drop of blood in around 15 minutes. Building on this same platform, there are proof-of-concept studies for fever and cancer. == Benefits ==