Use of Gamma Correction Pinhole Bone Scans in Trauma

Abstract: 99m Tc-hydroxydiphosphonate (HDP) bone scanning is a classic metabolic nuclear imaging method and the most frequently performed examination. Clinically, it has long been cherished as an indispensable diagnostic screening tool and for monitoring of patients with bone, joint, and soft tissue diseases. The HDP bone scan, the pinhole scan in particular, is known for its ability to detect increased, decreased, or defective tracer uptake along with magnified anatomy. Unfortunately, however, the findings of such upta… Show more

“…With the recent development of gamma correction pinhole scan (GCPS), many common bone diseases are now diagnosed at the dimension of trabeculae. They include occult fracture [1], trabecular mircofracture [2], and stress fracture, infection, and tumor [3]. To our knowledge, however, a mathematical method for the size quantification of such microscopic 99m Tc-HDP uptake has not been published.…”

“…The aim was to set up an in-vitro model of the size measurement of microscopic 99m Tc-HDP uptake that can be used clinically in in-vivo 99m Tc-HDP bone scan. Thus, the objectives of this study were first to secure the reliable source of microscopic 99m Tc-HDP deposits for micrometric measurement using standard flood phantom and handy small dish phantom; second, to demonstrate individual deposits with high 99m Tc-HDP radioactivity by GCPS [1,2]; and third, to mathematically calculate their size by pixelized measurement [4,5]. Microscopic 99m Tc-HDP deposits were easily formed in both large standard and small house-made dish phantoms, readily processed by GCPS and precisely calculated.…”

Pixelized Measurement of 99mTc-HDP Micro Particles Formed in Gamma Correction Phantom Pinhole Scan: a Reference Study

“…With the recent development of gamma correction pinhole scan (GCPS), many common bone diseases are now diagnosed at the dimension of trabeculae. They include occult fracture [1], trabecular mircofracture [2], and stress fracture, infection, and tumor [3]. To our knowledge, however, a mathematical method for the size quantification of such microscopic 99m Tc-HDP uptake has not been published.…”

“…The aim was to set up an in-vitro model of the size measurement of microscopic 99m Tc-HDP uptake that can be used clinically in in-vivo 99m Tc-HDP bone scan. Thus, the objectives of this study were first to secure the reliable source of microscopic 99m Tc-HDP deposits for micrometric measurement using standard flood phantom and handy small dish phantom; second, to demonstrate individual deposits with high 99m Tc-HDP radioactivity by GCPS [1,2]; and third, to mathematically calculate their size by pixelized measurement [4,5]. Microscopic 99m Tc-HDP deposits were easily formed in both large standard and small house-made dish phantoms, readily processed by GCPS and precisely calculated.…”

Pixelized Measurement of 99mTc-HDP Micro Particles Formed in Gamma Correction Phantom Pinhole Scan: a Reference Study

Gamma correction 99mTc-hydroxymethylene diphosphonate pinhole bone scan diagnosis and histopathological verification of trabecular contusion in young rats