Published on : Oct 21, 2020
The growing demand for single-photon emission computed tomography (SPECT) can be attributed to advancements in nuclear imaging and archiving. The medical industry has made formidable progress in the domain of disease testing, analysis, and diagnosis. In the absence of a prudent technique for medical imaging, medical practitioners would be rendered helpless in initiating a line of treatment. Therefore, use of medical imaging technology helps in reconciling diagnostics within the medical industry.
The use of gamma rays in single-photon emission computed tomography has played a defining role in driving sales across the global market. The total volume of revenues within the global single-photon emission computed tomography market is set to increase in the coming times.
In this review, Research Moz sheds value on a multitude of trends that have driven sales across the global single-photon emission computed tomography market. Barton Health has introduced a disruptive SPECT technology that offers improved 3D imaging. Barton Health uses its newly-developed MRI system to dispel information about radio imaging. Some of the leading players in the global single-photon emission computed tomography market are Siemens Healthineers, Toshiba Medical (Canon), Bruke, and Digirad Corporation.
Supremacy of SECT over Other Techniques
Although single-photon emission computed tomography is similar conventional nuclear medicine planar, the former is superseding conventional nuclear planar in terms of popularity. Advancements in nuclear medicine are set to bring in fresh revenues into the global market. Besides, the unprecedented need for gaining 3D information in a multitude of domains within medicine has aided market growth. The information gathered from single-photon emission computed tomography can be studied in greater detail to draw key analysis within medicine. Therefore, global single-photon emission computed tomography market is set to grow at a stellar pace in the times to follow.
Reformatting and manipulation of information embedded in cross-sectional slices is an important consideration for medical practitioners. Information from single-photon emission computed tomography is also presented in the form of a cross-sectional slice. SECT necessitates injection of a radionuclide into the blood stream of an individual. Injection of these radionuclides, also known as gamma-emitting radioisotope, has created fresh opportunities for market growth and maturity. The domain of radio-pharmaceuticals has gathered momentum in recent times, and this factor has played an integral role in market growth. Study of ligands in the body also necessitates the use of single-photon emission computed tomography within medicine.
Relevance of SECT in Cardiac Imaging
The use of single-photon emission computed tomography in the field of cardiac imaging is amongst the most stellar dynamics of market growth. The presence of ischemic heart disease can be diagnosed with the help of nucleic testing. Moreover, use of a specialised cardiac radiopharmaceutical also helps in resolving several issues related to heart functionality.
The medical industry has trodden along a lucrative growth path, and has made positive disruptions in the healthcare sector. The quest of the healthcare industry to optimize cardiac treatments has given a thrust to the growth of the global single-photon emission computed tomography market. MPI is a commonly used cardiac stress test.
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Need for Studying Brain Images
Use of single-photon emission computed tomography is also related to management of the body’s sensitivity to radiopharmaceuticals. The functionality of the brain is a complex domain that needs to be studied in immense detail. Use of single-photon emission computed tomography ensures that brain imaging samples can be easily accessed and analysed.
Therefore, several brain and neural disorders and deviances can be treated and controlled with the help of single-photon emission computed tomography. Use of gamma rays helps in getting precise information about the functionality of the brain. Moreover, SPECT can also help in keeping a check on blood flow in the brain area.