• 대한핵의학회지
• /
• 제29권1호
• /
• pp.31-40
• /
• 1995

휴식/부하 Rb-82 PET으로 평가한 심근혈류와 부하/휴식 Tc-99m-MIBI SPECT 심근혈류평가소견을 비교하였다. 관상동맥질환에 이환된 23명의 환자와 6명의 정상인에서 휴식기 Rb-82 PET을 촬영한후 디피리다몰 부하를 가하면서 Rb-82 PET을 촬영하고 Rb-82주사와 동시에 주사한 Tc-99m-MIBI의 SPECT를 1시간 후 촬영하였다. 4시간 후에는 휴식기 Tc-99m-MIBI SPECT 촬영을 하였다. 수직, 수평장축과 세 단축상에서 29개의 분절들의 관류점수를 정상부터 결손까지 5개 등급으로 나누어 점수판정하고 동맥영역별 점수는 합산한 값을 영역의 점수로 삼았는데 점수 2점인 분절이 둘 이상 또는 3점인 분절이 하나이상일 때 해당 관상동맥의 협착이 유의하다고 보았다. 46개의 동맥영역이 협착된 동맥에 의해 혈류공급을 받는 심근인데 이중 78%가 Rb-82 PET에서 확인되었고, 67%가 Tc-99m-MIBI SPECT에 이상을 나타냈다. 12명환자는 CABG 수술후의 환자였는데 이환동맥 28개 영역 중 14 영역이 Rb-82와 Tc-99m-MIBI에 모두 정상으로 판명되었다. 부하기심근분절은 모두 709 분절이 비교가능하였는데 이중 Rb-82와 Tc-99m-MIBI 분절혈류점수가 일치한 것이 72%이었고 휴식기 825 분절중에는 80%가 점수등급이 일치하였다. 휴식기 Rb-82 혈류점수가 Tc-99m-MIBI 보다 작은 경우가 9%, 큰 경우가 11%이었고 부하기 Rb-82 점수가 Tc-99m-MIBI보다 작은 경우가 9%, 큰 경우가 20%이었다. Spearman의 순서상관 분석에 Rb-82 PET의 분절점수와 Tc-99m-MIBI SPECT의 분절점수 사이에 구한 상관계수 rho는 부하기에는 0.7(p<0.005), 휴식기에는 0.5(p<0.005) 이었다. 기울기는 Tc-99m-MIBI SPECT 분절점수/Rb-82 PET분절점수로 표현한 상관기울기는 부하기 0.7, 휴식기에 0.9이었다. 좌전하행동맥영역의 기울기는 Tc-99m-MIBI SPECT/Rb-82 PET 분절점수비로서 1보다 컸고 46동맥중에서 7동맥영역이 Tc-99m-MIBI SPECT 에서 휴식기 결손의 정도가 심했다. 부하기와 휴식기의 점수의 차가 허혈정도를 나타낸다 할 때 Rb-82 PET에 더 크게 나타났다. 이 심근분절혈류감소 비교 결과로 보아 Rb-82 심관관류 PET 검사가 하루안에 시행하는 부하/휴식순서의 Tc-99m-MIBI 심관관류, SPECT 보다 더 큰 허혈부위를 찾아주며, 부하 4시간후 휴식기 Tc-99m-MIBI SPECT에 휴식기 Rb-82 PET 보다 더 큰 결손이 관찰됨을 알았다.

• 대한방사성의약품학회지
• /
• 제5권2호
• /
• pp.71-78
• /
• 2019

Nuclear imaging is one of the most powerful measures for non-invasive diagnosis of myocardial vascular disease. Radionuclide such as ¹³N, ¹⁵O, ²⁰¹Tl and ⁸²Rb is used for the measurement of cardiac blood flow. ¹³N, ¹⁵O and ²⁰¹Tl are produced in cyclotrons while ⁸²Rb is obtained from generator. Rubidium (Rb), an alkali ion, behaves biologically like potassium, and accumulates in myocardial tissue. Rb has rapid blood clearance profile which allows the use of ⁸²Rb with a short physical half-life of 75 s for non-invasive evaluation of regional myocardial perfusion. There are several advantages of ⁸²Rb over other radioisotopes. An ultra-short half-life significantly reduces the exposure of patients to radiation and allows to repeat injections for studying the effects of medical intervention. As a positron emitter, ⁸²Rb allows positron emission tomography (PET) imaging which have shown superior diagnostic performances. ⁸²Rb can be produced from generator by decay of its parent ⁸²Sr. However, the preparation of ⁸²Sr is difficult, because appropriate purity is required to meet the specification of the product. Recently reported procedure from ARRONAX research institute showed that a Chelex-100 resin is sufficient for this purpose and additional column is not necessary. Whereas Brookhaven National Laboratory (BNL) procedure contains three ion exchange resin separation, including Chelex-100 resin. Currently, since ⁸²Sr production site is non-existent in Korea, Korea Atomic Energy Research Institute (KAERI) has plan to produce ⁸²Sr within specifications. We compared ⁸²Sr purification procedures reported from ARRONAX and BNL to investigate the most suitable procedure for our conditions.

• 대한의용생체공학회:의공학회지
• /
• 제16권2호
• /
• pp.223-230
• /
• 1995

Rb-82 dynamic PET과 이중적분법에 의한 국소 심근 혈류측정 연구를 시행하고자 실험 개를 이용한 심근 경색 모델과 허혈성 심근질환에서 좌심실 입력함수에 의한 정상 및 관류결손 심근에서의 혈류를 측정하였다. 이중적분법이 선형회귀모델에 의한 혈류측정방법에 비하여 안정도가 높고 심근내혈류가 선형적인 가정을 배제할 수 있어 사용 가능한 방법이 될 수 있음을 확인하였다.

• 대한의용생체공학회:학술대회논문집
• /
• 대한의용생체공학회 1995년도 추계학술대회
• /
• pp.157-158
• /
• 1995

• 대한핵의학회지
• /
• 제28권3호
• /
• pp.326-330
• /
• 1994

A $^{82}Sr/^{82}Rb$ generator was prepared by loading $^{82}Sr$ to preconditioned tin dioxide column. The generator was eluted by normal saline with flow rate up to 8m1/min, and the eluted radioactivity was monitored by dose calibrator. Radioactivity began to come out at 5ml and reached to peak around 9ml. The total eluted radioactivity increased linearly with flow rate, and the maximum obtained radioactivity was 35mCi at 8m1/min. The $^{82}Rb$ preparation was proven to be free from both strontium radioactivity and pyrogen. The $^{82}Rb$ was injected to normal female volunteer and positron emission tomographic Image of heart was obtained successfully.

• Nuclear Medicine and Molecular Imaging
• /
• 제43권3호
• /
• pp.174-178
• /
• 2009

Many radiopharmaceuticals have been developed and wildy used in the imaging cardiac function. Myocardial perfusion imaging (MPI) is a well established noninvasive method of assessing coronary blood flow and has been widely used in patients diagnosed or suspected with coronary artery diseases. The innovation of radiopharmaceuticals used in the cardiac imaging is one of the most important contributors to the development of nuclear cardiology. Thallium-201 and various technetium-99m agents have been globally used for myocardial perfusion SPEG, and N-13 ammonia (13NH3), rubidium-82 (82Rb), 0-15 water (H2150) for myocardial perfusion PET. As well as the cardiac perfusion studies, new radiopharmaceuticals that visualize fat metabolism or receptors of the sympathetic nervous system have successfully been applied to clinical practice. Useful information can be obtained for diagnosing coronary artery disease, evaluating patients' condition, or assessing therapeutic effects. In this review, we describe the characteristics and clinical usefulness of radiopharmaceuticals used for cardiac SPEG and PET.

• 대한방사성의약품학회지
• /
• 제7권2호
• /
• pp.119-125
• /
• 2021

⁸²Sr for ⁸²Rb generator was produced through the irradiation of the proton beam on the ^nat.RbCI target at the target irradiation facility installed at the end of the Rl-dedicated beamline of the 100 MeV proton linear accelerator of KOMAC (Korea Multi-purpose Accelerator Complex). The average current of the proton beam was 1.2 µA for irradiation time of 150 min. For the separation and purification of the ⁸²Sr from ^nat.RbCI irradiated, Chelex-100 resin was used. The activities of ⁸²Sr in the irradiated ^nat.RbCI target solution and after purification were 45.29 µCi and 43.4 µCi, respectively. The separation and purification yield was 95.8%. As an adsorbent to be filled in the generator for ⁸²Sr adsorption hydrous tin oxide was selected. The adsorption yield of ⁸²Sr into the generator adsorbent was > 99 %, and the total amount of ⁸²Sr adsorbed to the generator was 21.6 µCi as of the day of the ⁸²Rb elution experiment. When the elution amount was 22 mL, the maximum⁸²Rb elution yield was 93.3%, and the elution yield increased as the flow rate increased. After the eluted ⁸²Rb was filled in the correction phantom of the small PET for animals, a PET image was taken. The image scan time was set to 5 min, and the phantom PET image was successfully obtained. As results of impurity analysis on eluted ⁸²Rb using ICP-MS, ^nat.Rb stable isotopes that compete in vivo of ⁸²Rb were identified as undetected levels and were determined to be No-Carrier-Added (NCA).

• 대한핵의학회지
• /
• 제36권1호
• /
• pp.1-7
• /
• 2002

Positron Emission Tomography (PET) is a nuclear medicine imaging modality that consists of systemic administration to a subject of a radiopharmaceutical labeled with a positron-emitting radionuclide. Following administration, its distribution in the organ or structure under study can be assessed as a function of time and space by (1) defecting the annihilation radiation resulting from the interaction of the positrons with matter, and (2) reconstructing the distribution of the radioactivity from a series of that used in computed tomography (CT). The nuclides most generally exhibit chemical properties that render them particularly desirable in physiological studies. The radionuclides most widely used in PET are F-18, C-11, O-15 and N-13. Regarding to the number of the current PET Centers worldwide (based on ICP data), more than 300 PET Centers were in operation in 2000. The use of PET technology grew rapidly compared to that in 1992 and 1996, particularly in the USA, which demonstrates a three-fold rise in PET installations. In 2001, 194 PET Centers were operating in the USA. In 1994, two clinical and research-oriented PET Centers at Seoul National University Hospital and Samsung Medical Center, was established as the first dedicated PET and Cyclotron machines in Korea, followed by two more PET facilities at the Korea Cancer Center Hospital, Ajou Medical Center, Yonsei University Medical Center, National Cancer Center and established their PET Center. Catholic Medical School and Pusan National University Hospital have finalized a plan to install PET machine in 2002, which results in total of nine PET Centers in Korea. Considering annual trends of PET application in four major PET centers in Korea in Asan Medical Center recent six years (from 1995 to 2000), a total of 11,564 patients have been studied every year and the number of PET studies has shown steep growth year upon year. We had 1,020 PET patients in 1995. This number increased to 1,196, 1,756, 2,379, 3,015 and 4,414 in 1996,1997,1998,1999 and 2000, respectively. The application in cardiac disorders is minimal, and among various neuropsychiatric diseases, patients with epilepsy or dementia can benefit from PET studios. Recently, we investigated brain mapping and neuroreceptor works. PET is not a key application for evaluation of the cardiac patients in Korea because of the relatively low incidence of cardiac disease and less costly procedures such as SPECT can now be performed. The changes in the application of PET studios indicate that, initially, brain PET occupied almost 60% in 1995, followed by a gradual decrease in brain application. However, overall PET use in the diagnosis and management of patients with cancer was up to 63% in 2000. The current medicare coverage policy in the USA is very important because reimbursement policy is critical for the promotion of PET. In May 1995, the Health Care Financing Administration (HCFA) began covering the PET perfusion study using Rubidium-82, evaluation of a solitary pulmonary nodule and pathologically proven non-small cell lung cancer. As of July 1999, Medicare's coverage policy expanded to include additional indications: evaluation of recurrent colorectal cancer with a rising CEA level, staging of lymphoma and detection of recurrent or metastatic melanoma. In December of 2001, National Coverage decided to expand Medicare reimbursement for broad use in 6 cancers: lung, colorecctal, lymphoma, melanoma, head and neck, and esophageal cancers; for determining revascularization in heart diseases; and for identifying epilepsy patients. In addition, PET coverage is expected to further expand to diseases affecting women, such as breast, ovarian, uterine and vaginal cancers as well as diseases like prostate cancer and Alzheimer's disease.