Depiction of Nidi and Fibrovascular Zones of Osteoid Osteomas Using Gamma-Correction Tc-99m HDP Pinhole Bone Scan and Conventional Radiograph, and Correlation with CT, MRI, and PVC Phantom Imaging

Bahk, Yong‐Whee; Kim, Sung Hoon; Chung, Yong An; Bahk, Won Jong; Park, Jung Mee; Kang, You Mee; Choi, Woo Hee; Park, Young Ha; Sohn, Hyung Sun; Kim, Byung Ki; Chung, Soo Kyo

doi:10.1007/s13139-010-0073-5

Cited by 4 publications

(1 citation statement)

References 11 publications

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“…The gamma correction pinhole bone scan (GCPBS) is a recently developed image-processing algorithm that has been shown to be able to extract fine, specific, and complex morphological changes in various types of occult fractures [1], and the nidus and fibrovascular zone in osteoid osteomas [2], from simply homogeneous or heterogeneous 99m Tc-hydroxydiphosphonate ( 99m Tc-HDP) uptake in the penumbra. The rationale for such diagnostic performances of GCPBS is that the pinhole bone scan (PBS) produces images with higher resolution through optical magnification with increased photon acquisition [3][4][5][6], and added gamma correction (GC) distinguishes occult fractures with higher 99m Tc-HDP uptake from edema, hyperemia, or hemorrhage with lower uptake (Fig.…”

Section: Introductionmentioning

confidence: 99%

Use of Gamma Correction Pinhole Bone Scans in Trauma

Bahk

Chung

Park

2012

Nucl Med Mol Imaging

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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 uptake changes are not specific in many traumatic bone disorders, especially when lesions are minute and complex. This study discusses the recently introduced gamma correction pinhole bone scan (GCPBS), emphasizing its usefulness in the diagnosis of traumatic bone diseases including occult fractures; cervical sprains; whiplash injury; bone marrow edema; trabecular microfractures; evident, gaping, and stress fractures; and fish vertebra. Indeed, GCPBS can remarkably enhance the diagnostic feasibility of HDP pinhole bone scans by refining the topography, pathologic anatomy, and altered chemical profile of the traumatic diseases in question.The fine and precise depiction of anatomic and metabolic changes in these diseases has been shown to be unique to GCPBS, and they are not appreciated on conventional radiographs, multiple detector CT, or ultrasonographs. It is true that MR imaging can portray proton change, but understandably, it is a manifestation that is common to any bone disease.

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