AI Article Synopsis
- Whole-body bone scintigraphy is a common and cost-effective imaging technique in nuclear medicine, known for its speed and sensitivity, but it suffers from low specificity, especially with ambiguous 'hot spots' that require further imaging.
- The introduction of a new superfast SPECT/CT protocol cuts scanning time down to under 4 minutes, significantly improving diagnostic efficiency while maintaining image quality.
- This technique, demonstrated through various cases, offers a valuable solution for nuclear medicine departments that cannot provide comprehensive SPECT/CT imaging to every patient, contributing to better patient management without straining resources.
Article Abstract
Whole-body bone scintigraphy remains widely used in nuclear medicine as it is a relatively inexpensive and quick test in which the whole body can be imaged with good sensitivity. However, one downside of the technique is its lack of specificity. The difficulty comes when there is a single 'hot spot' which usually requires further anatomical imaging to identify the cause and differentiate malignant from benign lesions. In this situation, hybrid imaging with single-photon emission computed tomography/computed tomography (SPECT/CT) can be a useful problem solver. The addition of SPECT/CT can however, be time-consuming, adding up to 15-20 min for every bed position required, a process that can tax the compliance of the patient and reduce the scanning capacity of the department. We report the successful implementation of a new superfast SPECT/CT protocol comprising a 1 s per view over 24 views point and shoot approach, reducing the SPECT scan time to less than 2 min and the whole SPECT/CT to under 4 min while still producing images that allow diagnostic certainty in previously equivocal lesions. This is faster than previously reported ultrafast SPECT/CT protocols. The utility of the technique is demonstrated in a pictorial review of four disparate causes of solitary bone lesions: fracture, metastasis, degenerative arthropathy and Paget's disease. This technique may prove a cost-effective problem-solving adjunct in nuclear medicine departments unable to yet offer whole-body SPECT/CT to every patient, without adding much burden to the department's gamma camera usage and patient throughput.
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| http://dx.doi.org/10.1097/MNM.0000000000001677 | DOI Listing |
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