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ISSN : 2288-3509(Print)
ISSN : 2384-1168(Online)

Journal of Radiological Science and Technology Vol.38 No.1 pp.31-38
DOI : https://doi.org/10.17946/JRST.2015.38.1.05

A Study of the Changes of Breast Uptake in Menstrual Cycle on 18F-FDG PET/CT

Yeojin Tak, Min Soo Park¹⁾, Juyoung Lee²⁾, Hoon-Hee Park

Dept. of Radiological Technology, Shingu College
¹⁾Dept. of Nuclear Medicine, Severance Hospital, YUHS
²⁾Graduate School of Public Health, Yonsei University

Corresponding author: Hoon-Hee Park (452-743) Department of Radiological Technology, Shingu College 377 Gwangmyeong-ro, Seongnam, Korea. Tel : +82-31-740-1638, Fax : +82-31-740-1589

Received January 2, 2015 Review February 11, 2015 Accepted March 19, 2015

Abstract

18F-FDG PET/CT has been known a useful modality to diagnose high-glucose-using cells such as cancer cells by glucose metabolism of FDG. Mainly, FDG takes on cancer and inflammatory cells; however, there have been FDG uptakes on normal tissues by individual physiological characteristics, occasionally. Especially, in fertile females, unusual FDG uptake of breast changes as the menstrual cycle, and disturb diagnosis. Therefore, the study aimed to evaluate the change of breast FDG uptake in menstrual cycle on 18F-FDG PET/CT. 160 females (34±3.5 years old) who do not undergo a gynecologic anamnesis and have regular menstrual cycle over the previous 6 months were examined. They were divided 4 groups (each 40 patients) as flow phase, proliferative phase, ovulatory phase and secretory phase using Pregnancy Calculator 0.14. and history taking. Discovery Ste (GE Healthcare, Milwaukee, Mi, USA) was used a s PET/CT. We analyzed SUVs on a ccumulated r egion on b reast, and 3 nuclear medicine specialists did the Blind test. SUVs on the Breast were flow phase (1.64±0.25), proliferative phase (0.93±0.28), ovulatory phase (1.66±0.26) and secretory phase (1.77±0.28). It showed high uptake value in secretory, flow phase and ovulatory phase (p<0.05). In gross analysis, the accumulation of breast was divided into 3 grades as comparing with lung and liver. The breast’s uptake was equal to lung (Grade Ⅰ); between lung and liver (Grade II); equal to or greater than liver (Grade III). The results showed high uptake value in secretory, flow phase and ovulatory phase (p<0.05). In fertile females, FDG uptake of breast changed as menstrual cycle, and it available to diagnose breast disease. Therefore, we consider reducing false-negative finding of breast disease, by doing examination on appropriate period through history taking about individual menstrual cycle.

Key Words : 18F-FDG PET/CT , Menstrual cycle , Breast

월경 주기에 따른 18F-FDG PET/CT에서 유방 섭취 변화에 관한 고찰

탁 여진, 박 민수¹⁾, 이 주영²⁾, 박 훈희

신구대학교 방사선과
¹⁾연세대학교 세브란스병원 핵의학과
²⁾연세대학교 보건대학원

초록

18F-FDG PET/CT는 당대사로 인한 암세포의 비정상적인 섭취를 통해 암을 진단하는 유용한 검사이다. 일반적 으로 FDG는 암세포와 염증성 질환에 높은 섭취를 보이나, 환자의 생리적 특성에 따라 정상세포에도 비정상적인 섭취를 나타내기도 한다. 특히 여성 월경 주기에 따른 유방의 비정상적인 섭취는 미세한 유방 병변의 정확한 진 단을 저해하는 요인이 될 수 있다. 따라서 본 연구는 월경 주기에 따른 유방의 FDG 섭취 변화를 비교 평가하고 자 한다. 평가 대상은 부인과 병력이 없고 6개월 이상 규칙적인 월경 주기를 가진 160명의 여성(34±3.5세)을 대상으로 하였다. 환자 문진과 Pregnancy Calculator 0.14.를 이용하여 월경기, 증식기, 배란기, 분비기로 나누어 각각 40명씩 정보를 수집하였으며, PET/CT 장비는 Discovery STe(GE Healthcare, Milwaukee, Mi, USA)를 이용 하였다. 분석 방법으로는 월경 주기 별 유방의 SUV 변화를 비교 분석하였으며, 핵의학 전문의 3명을 통해 Blind Test로 육안적 평가를 시행하였다. 유방의 SUV는 월경기(1.64±0.25), 증식기(0.93±0.28), 배란기(1.66±0.26), 분 비기(1.77±0.28)로 나타났으며 분비기가 가장 높고 월경기와 배란기에서도 높은 섭취를 나타냈다(p<0.05). 또한 육안적 분석에서는 간과 폐의 집적에 대하여 유방의 집적 정도를 단계별로 나누어 폐와 유사한 섭취를 보인 경 우(Grade I), 폐와 간 중간 정도의 섭취를 보인 경우(Grade II), 간과 같거나 높은 섭취를 보인 경우(Grade III) 로 구분하였으며, 육안적 평가에서도 분비기와 월경기에서 높은 섭취를 보였다(p<0.05). 가임기 여성은 월경 주 기에 따라 유방의 18F-FDG 섭취 정도가 변화되며, 특히 미세한 유방 병변을 진단하는데 월경 주기의 정보를 유 용하게 활용할 수 있다. 따라서 검사 전 문진을 통하여 가임기 여성의 정확한 월경 주기를 확인하고 적정한 시 기를 유도하여 검사를 시행함으로써 유방 질환에 대한 위음성 결과를 감소시킬 수 있을 것으로 사료된다.

키워드 : 18F-FDG PET/CT , 월경주기 , 유방

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I.INTRODUCTION

¹⁸F-FDG PET/CT is a useful test for detecting cancer by assessing the abnormal uptake of FDG by cancer cells due to the glucose metabolism^1-3). Generally, the high uptake of FDG by cancer cells and inflammatory diseases was observed⁴⁾. Nonetheless, normal cells may show abnormal uptake depending on the physiological characteristic of patients. In particular, the structural changes that occur in the uterine wall according to the menstrual cycle influence the pelvic ultrasonography results^5,6). Moreover, the endometrium shows abnormal FDG uptake and influences the PET/CT test due to the change i n female h ormones. In fertile w omen, the menstrual cycle is generally 28 days⁷⁾. The menstrual cycle is divided to the Menstrual Flow Phase, Proliferative Phase, Ovulatory Phase, and Secretory Phase according to the changes in the uterus and follicle⁸⁾. The uterus undergoes changes as a regular cycle. During each menstrual cycle, the ovary undergoes changes in two stages, Follicular Phase and Luteal Phase. During this process, the representative female hormones estrogen and progesterone are secreted^9-11). After menstruation, the endometrium becomes thick due to the influence of estrogen released from the follicle, and the uterine glands and blood vessels developed simultaneously^12-14). The progesterone released from the corpus luteum stimulates the proliferation of endometrium and blood flow in the breast resulting in an increase in the elasticity of breast connective tissues and fat deposition, which induces the development of the lactiferous duct and mammary glands^15,16). Therefore, its influence on the result of mammography and PET/CT should not be ruled out.

In Korean women, breast cancer is the second highest cancer next to thyroid cancer, and the importance of PET-CT for determining the stage of breast cancer and assessing the prognosis after the treatments has been emphasized. On the other hand, the abnormal FDG uptake by the breast of women according to the menstrual cycle may be a factor that impairs an accurate diagnosis of breast micro-lesions. Therefore, this study assessed the optimal time for a PET-CT test by comparing the uptake of FDG by the breast according to the menstrual cycle to improve the ability to diagnose micro-lesions in the breast.

II.MATERIALS & METHODS

A.Patients information

The subjects were 160 female patients (mean age, 34 ± 3.5 years) without a disease history of gynecological disease, and with a regular menstrual cycle for longer than 6 months(Figure 1). The subjects were divided into the following phases by history taking and the application of Pregnancy Calculator Ver.0.14: the menstrual flow phase, proliferative phase, ovulatory phase and secretory phase. Information of 40 patients in each phase was collected.

B.Equipment and test methods

The Discovery STE scanner (Milwaukee, Wi, GE Healthcare, Co., USA) was used for PET/CT. BGO was used a s the crystal. A 6 .0 mm f ull width at h alf maximum (FWHM) was used as the intrinsic resolution. The display field of view (DFOV) was 70.0 mm, and the Overlap per 1 bed was 9 mm. CT consisted of 8 slices with a 2 mm slice thickness. As the reconstruction method, “subset” was performed 28 times and “iterative” was performed 2 times using the iterative method. As the pretreatment test, the patients were fasted for a minimum of 8 hours, and excessive exercise was prohibited on the day before the test and on the day of the test. The patients took sufficient liquid, more than 100 ~ 500 ml. The blood glucose levels prior to the test were <6.69 mmol/l (120 mg/dl). For the administration of ¹⁸F-FDG, after the patients were allowed to rest for approximately 15 minutes, approximately 5.6 MBq/kg (0.15 mCi) was injected intravenously. Movements were restrained to prevent uptake by the muscles, and a full-body scan was performed after 60 ~ 90 minutes. In a full-body scan, the test range was from the base of the brain to the proximal femoral area in the supine position. Non contrast computed tomography (NCCT) without contrast was performed under the condition of 140 kVp and 30 mAs. Subsequently, an emission scan for 3 minutes per bed was performed (Figure 2). After the emission scan, contrast enhanced computed tomography (CECT) was performed. OMNIPAQ UE (300 mg iodine/ml, GE Healthcare Co., Ireland) was used as the contrast. At that time, it was injected at a dose of 2 cc per kg of the patient’s body weight and a speed of 2 ml per s econd. A d ual shot i njector optivantage (Mallinchrodt, LIEBEL FLARSHEIM Co., USA) was used as the automatic injector.

C.Image analysis

Using Pregnancy Calculator Ver. 0. 14 and history taking prior to the test, the women were classified according to their menstrual cycle, and in each phase, the changes in SUV in the liver, lung and breast were compared and analyzed (Figure 3).

In addition, a macroscopic evaluation was performed by 3 radiologists as a Blind Tests. The level of FDG uptake by the lung, liver and breast was measured in each menstrual phase. Cases in whom the FDG uptake by the breast was comparable to the lung were classified as Grade I. Cases in whom the FDG uptake of the breast was between the lung and liver were Grade II. Cases in whom the FDG uptake of the breast was comparable to the liver or higher than the liver were Grade III (Figure 4).

III.RESULTS

The SUVmax of the menstrual, proliferative, ovulatory and secretory phases was 1.64 ± 0.25 g/ml, 0.93 ± 0.28 g/ml, 1.66 ± 0.26 g/ml and 1.77 ± 0.28 g/ml, respectively(Table 1 ). The SUV was h ighest in the secretory phase followed in order by the menstrual flow phase and the ovulatory phase (p < 0.05).

In addition, the change in SUV in each menstrual phase was drawn as a Box Plot, which revealed an increased in the secretory phase, menstrual flow phase and ovulatory phase. The SUV was lower in the proliferative phase(Fig. 5). On the other hand, the SUV in the lung and the liver showed no change according to the menstrual cycle(Fig. 6).Table 2

Three radiologists evaluated the uptake of the 160 patients by macroscopic analysis as a blind test. The results revealed, Grade I in 34 patients (21.2 %). Among them, 2 and 32 cases were in the menstrual flow and proliferative phases, respectively. No cases were observed in the ovulatory and secretory phases. Most of the patients who underwent the test during the proliferative phase corresponded to Grade I. Forty six (28.8 %) patients were in Grade II; 13 and 16 cases were in the menstrual flow and ovulatory phase, respectively. Eighty cases (50 %) were Grade III, of which the FDG uptake was highest. Thirty one patients were in the secretory phase, and their ratio was highest. In particular, all images of the secretory phase corresponded to Grades II or III, and the FDG uptake by the breast was noticeably higher than the proliferative phase(Figure 7).

IV.DISCUSSION

In a PET/CT full-body scan, hormonal changes according to the menstrual cycle increase the FDG uptake by the breast. The change in FDG uptake was largest in the secretory phase, and its effect was lowest in the proliferative phase. Based on this study, the SUV changes in the breast according to the menstrual cycle and the macroscopic changes in uptake by the breast could be detected by a full-body PET/CT scan. If a PET/CT test is performed during the proliferative phase in collaboration with the diagnosis department, it can provide an accurate test that could detect even micro lesions in the breast. Nonetheless, in the present study, the subjects were patients with a regular menstrual cycle. Patients with an irregular menstrual cycle were excluded. Accordingly, many studies will be needed before this can be applied to patients with an irregular menstrual cycle.

V.CONCLUSION

The level of the FDG uptake by the breast in fertile women varies according to the menstrual cycle. In particular, information on the menstrual cycle can be applied widely for a diagnosis of breast micro-lesions. Through this study, the uptake of FDG by the breast in each phase was compared. In fertile women, the FDG uptake by the breast was highest during the secretory phase and lowest in the proliferative phase. Therefore, it is believed that false negative results of micro breast lesions may be reduced by assessing the accurate menstrual cycle through history taking before the test and by performing the test at the appropriate phase.

Figure

Fig. 1.

160 females (34±3.5 years old) who do not undergo a gynecologic anamnesis and have regular menstrual cycle (28 days) over the previous 6 months were examined. 1 ~ 4 days was classified as flow phase, 5 ~ 13 days was classified as proliferative phase, 13 ~ 16 days as ovulatory; and 16 ~ 28 days as secretory phase.

Fig. 2.

Before PET/CT procedure, we were confirmed each menstrual cycle through history taking, and then, Whole Body PET/CT was progressed.

Fig. 3.

We did semi-quantitative analysis using each SUV measured of breast, liver, and lung for identifying the change of SUVs as menstrual cycle.

Fig. 4.

Three nuclear medicine specialists did the Blind test. (A), (B), (C) were PET Whole Body images, and (A-1, B-1, C-1) were Fusion image of each Grade. The higher Grade was, the more Breast FDG uptake increased unusually.

Fig. 5.

Breast uptake values increased in order of secretory, flow, and ovulatory phase, similarly. Proliferative phase showed comparative low SUVs, only.

Fig. 6.

The uptake values of lung and liver had almost no variation over menstrual cycle. This suggested that breast’s SUVs were only influenced by menstrual cycle.

Fig. 7.

PET Whole Body images of Secretory phase (D) and flow phase (A) were the highest FDG uptake of breast, and each fusion images (D-1, A-1) showed increases remarkably. (B) and (B-1) were proliferative phase, and breast uptake was almost no increase. (C) and (C-1) were ovulatory phase that breast FDG uptake was increased more than proliferative.

Table

Table 1..

Analysis of SUV of Breast area.

Cycle Phase	No. of Patients	SUVmax (±SD)	SUVavg (±SD)
Menstrual Flow Phase	40	1.64±0.25 g/ml	1.40±0.22 g/ml
Proliferative Phase	40	0.93±0.28 g/ml	0.74±0.22 g/ml
Ovulatory Phase	40	1.66±0.26 g/ml	1.46±0.29 g/ml
Secretory Phase	40	1.77±0.28 g/ml	1.60±0.24 g/ml

Table 2..

Results of blind test.

FDG Uptake in Breast	Flow	Proliferative	Ovulatory	Secretory	Total No.
Grade I	2	32	0	0	34
Grade II	13	8	16	9	46
Grade III	25	0	24	31	80
Total No.	40	40	40	40	160

Reference

Engel H , Steinert H , Buck A , Berthold T , Rahel A , von Schulthess GK (1996) Whole-body PET: physiological and artifactual fluorodeoxyglucose accumulations , J Nucl Med, Vol.37; pp.441-6
Strauss LG (1996) Fluorine-18 deoxyglucose and falsepositive results: a major problem in the diagnostics of oncological patients , Eur J Nucl Med, Vol.23; pp.1409-15
Cook GJ , Fogelman I , Maisey MN (1996) Normal physiological and benign pathological variants of 18-fluoro-2-deoxyglucose positron-emission tomography scanning: potential for error in interpretation , Semin Nucl Med, Vol.26; pp.308-314
Shreve PD , Anzai Y , Wahl R (1999) Pitfalls in oncologic diagnosis with FDG PET imaging: physiologic and benign variants , Radiographics, Vol.19; pp.61-77
Cook GJ , Wegner EA (1999) Fogelman I: Normal variants, artefacts and interpretative pitfalls in PET imaging with 18-fluoro-2-deoxyglucose and carbon-11 methionine , Eur J Nucl Med Mol Imaging, Vol.26; pp. 363-1378
Blodgett TM , Fukui MB , Snyderman CH (2005) Combined PET-CT in the head and neck: part 1— physiologic, altered physiologic, and artifactual FDG uptake , Radiographics, Vol.25; pp.897-912
Prabhakar HB , Sahani DV , Fischman AJ , Mueller PR , Blake MA (2007) Bowel hot spots at PET-CT , Radiographics, Vol.27; pp.145-159
Mijin Yun , Arthur Cho , Jae Hoon Lee , Yun-Jung Choi , Jong Doo Lee , Chun K Kim (2010) Physiologic 18F-FDGUptakeintheFallopianTubes at Mid Cycle on PET/CT , J Nucl Med, Vol.51; pp.682-685
Treloar A E , Boyton R E , Behn B G , Brown B W (1967) Variations of the Human Menstrual Cycle through Reproductive Life , International Journal of Fertility, Vol.9; pp.77-126
Zangheri B , Messa C , Picchio M , Gianolli L , Landoni C , Fazio F (2004) PET/CT and breast cancer , Eur J Nucl Med Mol Imaging, Vol.31; pp.135-142
Tatsumi M , Cohade C , Mourtzikos KA , Fishman EK , Wahl RL (2006) Initial experience with FDG-PET/CT in the evaluation of breast cancer , Eur J Nucl Med Mol Imaging, Vol.33; pp.254-262
Radan L , Ben-Haim S , Bar-Shalom R , Guralnik L , Israel O (2006) The role of FDG-PET/CT in suspected recurrence of breast cancer , Cancer, Vol.107; pp.2545-2551
Beresford M , Lyburn I , Sanghera B , Makris A , Wong WL (2007) Serial integrated 18F fluorodeoxythymidine PET/CT monitoring neoadjuvant chemotherapeutic response in invasive ductal carcinoma , Breast J, Vol.13; pp.424-425
Rosenberg RD , Hunt WC , Williamson MR (1998) Effects of age, breast density, ethnicity, and estrogen replacement therapy on screening mammographic sensitivity and cancer stage at diagnosis: review of 183,134 screening mammograms in Albuquerque , New Mexico Radiology, Vol.209; pp.511
Kerlikowske K , Grady D , Barclay J (1996) Effect of age, breast density, and family history on the sensitivity of first screening mammography , JAMA, Vol.276; pp.33-38
Kavanagh AM , Cawson J , Byrnes G B e t al (2005) Hormone replacement therapy, percent mammographic density, and sensitivity of mammography , Cancer Epidemiol Biomarkers Prev, Vol.14; pp.1060-1064