Impact of Cold Somatostatin Analog Administration on Somatostatin Receptor Imaging: A Systematic Review

Somatostatin receptor (SSTR) imaging currently plays a central role in the management of several types of tumors, first and foremost neuroendocrine tumors (NETs).1 Initially confined to single-photon emitting radiopharmaceuticals with 111In-pentetreotide, SSTR imaging possibilities have been extended to positron emitters with the arrival of 68gallium-labeled peptides, notably 68Ga-DOTATATE and 68Ga-DOTATOC.

The benefit of treatment with cold somatostatin analogs (cSAs) is widely demonstrated in NETs,2 both for secretory syndrome and tumor control. Initially limited to short-acting release (SAR) formulations, long-acting release (LAR) cSA formulations have made their appearance.2 The interactions between cSAs, whether SAR or LAR, and their radiolabeled counterpart remain unclear.3 To date, in the hypothesis of a competitive action on SSTRs between the two, a discontinuation of cSAs before SSTR imaging has been advised, most often based on a precautionary principle. The European Association of Nuclear Medicine procedure guidelines recommend a time interval of 3 to 4 weeks after administration of LAR cSAs before performing PET/CT, meanwhile acknowledging that the effects of cSAs therapy have not been well characterized.4

The aim of this systematic review was to gather information from the literature to evaluate the true consequences of cSA administration on tumor uptake as well as on healthy organs' uptake, based on within-patient data.

METHODS Research Strategy

This systematic review was performed according to the standards of the PRISMA-P statement and was registered on the Prospero Web site (registration code: CRD42022360260). An electronic search of PubMed and Scopus databases was independently performed by 2 authors (D.M. and N.L.) to identify articles evaluating the impact of cSA administration on SSTR imaging. The search strategy was built using the following search string (Equation 1) and was last updated on September 6, 2022:

Scintigraphy ORPETANDsomatostatin OR SSTR ORSST

ANDcold OR octreotide OR lanreotide

Screening and Inclusion and Exclusion Criteria

First, duplicate findings between PubMed and Scopus were automatically removed through the functions available in the reference manager used (JabRef, JabRef Bibliography Management). The remaining articles were screened for eligibility, based on title and abstract.

Inclusion criteria were as follows: (i) human patients referred for SSTR imaging for oncological purposes; (ii) at least 1 examination performed either before cSA administration or after a long-enough withdrawal of cSA treatment (>24 hours for subcutaneous formulations; imaging performed the week before the next administration, for long-acting formulations); (iii) at least 1 examination performed under cSA treatment; (iv) available quantitative or semiquantitative data on the uptake of healthy organs or tumoral lesions; (v) intrapatient comparison (percentage of decrease/increase in the measures on the same patients); and (vi) written in the first language of at least 2 of the authors of this review (English, French, or Italian). Exclusion criteria were as follows: (i) diseases other than cancer; and (ii) reviews, expert opinions, comments, letters to the editor, case reports, studies on animals, and conference reports.

Full texts of the potentially eligible studies were retrieved for further evaluation. A cross-reference check was also performed to identify any additional studies to be included.

Quality Assessment

Two authors (D.M. and N.L.) independently assessed the methodological quality of the included articles using the standardized protocol provided by the Quality Assessment of Diagnostic Accuracy Studies (QUADAS-2). Any disagreement was solved by consensus. The QUADAS-2 scores of its 4 key domains (patient selection, index test, reference standard, flow and timing), evaluated with regard to the risk of bias and methodological applicability, were recorded and tabulated for all included studies, and a summary report was constructed. Studies with a low risk of bias for all items or not more than 1 item evaluated with uncertain risk were deemed of sufficient quality for final inclusion.

Data Collection

An Excel review database was generated. The following parameters were extracted from each article: year of publication, first author, number of patients in the subgroup of interest, cancer type, administered radiotracer (name, activity, peptide mass), first imaging session data (patient's preparation regarding cSAs, acquisition protocol), delay between first and second imaging sessions, cSAs data (name, administration protocol, last administration before radiotracer administration during the second imaging session), ratio between cold and hot somatostatin analog; second imaging session acquisition protocol; quantitative/semiquantitative measures (% of decrease, evolution of absolute SUVmax values) for healthy organs (spleen, liver, kidneys, adrenals, pituitary, thyroid, bone marrow, pancreas), and tumoral lesions. This database was independently filled in by 2 authors (D.M. and N.L.), and discrepancies were solved by consensus.

RESULTS

This systematic literature search initially yielded a total of 3706 articles (PubMed: 1774 articles; Scopus: 1932 articles). Once the 1165 duplicates were excluded, 2541 articles were screened based on their title and abstract. Of these, 20 full texts were sought for retrieval. Eight articles were further excluded: 1 did not have an available manuscript, 1 was a duplicate, and 6 did not have any within-patient comparison. Finally, 12 articles were included in the study3,5–15 (Fig. 1). All studies were deemed of sufficient methodological quality based on QUADAS-2 assessment (Table 1). All articles rely on the same design, with a baseline imaging (without administration of cSAs or after a sufficiently long period of withdrawal of a long-term treatment, later referred as “imaging session 1”) and a second imaging session under cSA treatment (later referred as “imaging session 2”). One article included patients with small cell lung cancer (SCLC); the other 11 articles included patients with NETs. Studies' design and results are presented in Table 2 and Table 3.

F1FIGURE 1:

Systematic review flowchart. EN, English; FR, French; IT, Italian.

TABLE 1 - QUADAS-2 Assessment of Included Studies Author (Year) Patient Selection Index Test Reference Standard Flow and Timing Risk of Bias Applicability Concerns Risk of Bias Applicability Concerns Risk of Bias Applicability Concerns Risk of Bias Dörr et al (1993)5 Unclear Low Low Low Low Low Low Soresi et al (1997)6 Unclear Low Low Low Low Low Low Janson et al (1999)7 Low Low Low Low Low Low Low Rolleman et al (2007)8 Low Low Low Low Low Low Unclear Velikyan et al (2010)9 Low Low Low Low Low Low Low Haug et al (2011)10 Low Low Low Low Low Low Low Ayati et al (2017)11 Low Low Low Low Low Low Low Aalbersberg et al (2018)12 Low Low Low Low Low Low Low Cherk et al (2018)13 Low Low Low Low Low Low Unclear Gålne et al (2019)14 Low Low Low Low Low Low Low Jahn et al
(2021)15 Low Low Low Low Low Low Low Lodge et al (2021)3 Low Low Low Low Low Low Low
TABLE 2 - Studies' Design Study Data Tracer Administration Imaging Session 1 (Before Intervention) Intervention Imaging Session 2 (After Intervention) Author (Year) No. Patients Tracer Activity, MBq Cold Octreotide Before Imaging Protocol (Uptake Time Awaited) Delay Imaging 1 Imaging 2 Octreotide Before Imaging 2 Last Administration of Cold Octreotide Before Imaging 2 Protocol (Uptake Time Awaited) Dörr et al
(1993)5 5 [111In]pentetreotide 105–237 None or withdrawal >24 h Planar (30 min,
4 h, 24 h) <28 d Octreotide (600 μg/d,
ongoing) <1 d Planar (30 min,
4 h, 24 h) Soresi et al
(1997)6 12 [111In]pentetreotide 110–130 None Planar (5 h) 7 d Octreotide (600 μg/d, 7 d) <1 d Planar (5 h) Janson et al
(1999)7 8 [111In]pentetreotide 114–238 None Planar (19–24 h) 10–13 mo Lanreotide (6000–12,000 μg/d) 3 d Planar (19–24 h) Rolleman et al
(2007)8 10 [111In]pentetreotide 220 None Planar (24 h) 50–397 d Octreotide (200–300 μg/d or LAR 20–30 mg/28 d) 4–21 d (LAR) Planar (24 h) Velikyan et al
(2010)9 6 [68Ga]DOTATOC 15–80 None Dynamic + whole
body (50 min) <1 d Octreotide (50 μg, 250 or 500 μg, single dose) 10 min Dynamic + whole
body (50 min) Haug et al
(2011)10 9 [68Ga]DOTATATE 200 None Whole body (60 min) 13.8 wk Octreotide LAR
(20–50 mg/28 d) NA Whole body (60 min) Ayati et al
(2017)11 30 [68Ga]DOTATATE 110–185 None Whole body (60 min) 9.6 mo Octreotide LAR
(30–60 mg/28 d) 25.1 +/− 14.8 d Whole body (60 min) Aalbersberg et al
(2018)12 34 [68Ga]DOTATATE 100 Yes, imaging performed the day before the next administration Whole body (45 min) 2 d Lanreotide LAR
(60–120 mg/3–4 wk) 1 d Whole body (45 min) Cherk et al
(2018)13 21 [68Ga]DOTATATE 85–307 None Whole body
(35–88 min) 2–12 mo Unspecified LAR (/28 d) 21–28 d Whole body (60 min) Gålne et al
(2019)14 19 [68Ga]DOTATATE 2.5/kg None Whole body (60 min) 202 d Unspecified LAR (/21
or /28 d) Between 1 and 31 d Whole body (60 min) Jahn et al
(2021)15 4 [68Ga]DOTATOC 167 Yes, 7–27 d Whole body (1 h) 1–3.5 mo Octreotide 400 μg (in
addition to LAR
treatment) 15 min Whole body (1 h, 4 h,
7 h) and dynamic
studies in between Lodge et al
(2021)3 7 [68Ga]DOTATOC 185 None 8 Whole body
(8–100 min) 1–20 d Octreotide (50 μg, single
dose) 10–15 min 8 Whole body
(8–100 min)
TABLE 3 - Studies' Results Author (Year) Measure Effect of cSAs on Tumor Uptake Effect of cSAs on Healthy Organ Uptake Histology Tumor Spleen Liver Kidneys Others Dörr et al (1993)5 Semiquantitative NET T/L: >20%* Decrease (60%) Decrease (28%) Decrease (17%) NA Soresi et al (1997)6 Semiquantitative SCLC Increase in ratios
T/Lg: 1.98 vs 1.83
T/L: 0.78 vs 0.67 NA NA NA NA Janson et al (1999)7 Semiquantitative NET T/B: +50% (−79% to 1085%) Decrease (55%) NA NA NA Rolleman et al (2007)8 Semiquantitative NET T: NS (−15%) Decrease (69%) NS (decrease 17%) NS (decrease 18%) NA Velikyan et al (2010)9 SUV NET T/L: increase (1%–223%) Decrease (>40%*) Decrease (>20%*) Decrease (20%*) NA Haug et al (2011)10 SUV NET T: NS (21.7 vs 20.6) NS (21.7 vs 23.3) Decrease (7.1 vs 9.1) NA Adrenals: NS (7.8 vs 16.9) Ayati et al (2017)11 SUV NET T: NS Decrease (18.8 vs 24.5) Decrease (7.6 vs 9.8) NA Adrenals: NS (14.6 vs 14.9)
Pituitary: NS (6.2 vs 6.3)
Thyroid: decrease (2.6 vs 3.9) Aalbersberg
et al (2018)12 SUV NET T/L: increase (2.59 vs 2.21) Decrease (22.4 vs 25.8) Decrease (9.1 vs 10.2) NS (20.7 vs 19.8) Adrenals: NS (20.6 vs 19.2)
Pituitary: NS (7.1 vs 6.6)
Parotid: NS (4.2 vs 4.0)
Thyroid: decrease (3.1 vs 4.1)
Bone marrow: NS (2.2 vs 2.4) Cherk et al (2018)13 SUV NET T: NS Decrease (23.1 vs 30.3) Decrease (8 vs 10.3) NA Adrenals: NS
Pituitary: increase (11.9 vs 10.2)
Thyroid: decrease (3.5 vs 5.9) Gålne et al (2019)14 SUV NET T/L: increase (5.6 vs 2.6) NA Decrease (6.0 vs 8.6) NA NA Jahn et al (2021)15 SUV NET T: decrease (1 h: 0%–60%*) Decrease (at 1 h: 60%–80%*) Decrease (at 1 h: 40%–60%) NA Pancreas: decrease (40%–60%*) Lodge et al (2021)3 SUV NET NS (12.8 vs 12.4) Decrease (4.6 vs 8.8) Decrease (2.7 vs 3.7) NS (6.4 vs 6.2) Red marrow: NS (1.1 vs 1.0)
Pituitary: NS (5.9 vs 7.4)

Effects of cSAs on tumor or healthy organs' uptake are presented either as percentage value (%) or with changes in SUVmax values.

*Estimated based on figures.

B, background; L, liver; Lg, lung; NA, not available; NS, nonsignificant; T, tumor.


Octreotide-Naive Patients Before Baseline Imaging (Imaging Session 1) Start of Short-Acting Octreotide Treatment Immediately Before Imaging Session 2

Two prospective studies fall into this category: one published by Velikyan et al9 in 2010 and a second proposed by Lodge et al3 in 2021.

In the study by Velikyan et al,9 a subgroup of 6 patients underwent sequential 68Ga-DOTATOC PET/CT examinations preceded by the administration of 0 (baseline, image 1), 50 (image 2), and 250 or 500 μg of octreotide (high dosage, image 3) 10 minutes before tracer administration. A 3-hour interval between the examinations was observed, and each PET/CT was performed 50 minutes after radiopharmaceutical administration. Injected 68Ga-DOTATOC activities ranged from 15 (image 1) to 80 MBq (images 2 and 3). In 4 of 5 patients, for which liver values were available, the lesion-to-liver ratio increased from baseline to the 50-μg pretreated scan (average increase ranging from 13% to 108%). From baseline to the last study, the lesion-to-liver ratio also increased with an average of 88% (range, 1%–223%). Liver and spleen uptake decreased after 50-μg and high-dosage octreotide pretreatment (at least −20% and −40%, respectively, based on the reported figure at high dosage). Kidney uptake only decreased after high cold octreotide pretreatment.

Lodge et al3 published a prospective study including 7 patients who underwent 2 68Ga-DOTATOC PET/CT scans: the first without cold octreotide and the other with the administration of 50 μg of short-acting octreotide 10 to 15 minutes before radiotracer administration. The 2 examinations were performed less than 21 days from each other (1–20 days). Spleen uptake and liver uptake were significantly decreased on the second PET/CT (−48% and −27%, respectively) with images performed 60 minutes after radiotracer administration. No significant difference was noted for other healthy organs or tumor's uptake.

Start of Short-Acting Octreotide Treatment Less Than 2 Weeks Before Imaging Session 2

In 1997, Soresi et al6 published a prospective study including 12 patients with SCLC. Two scans were performed, both 5 hours after the administration of 110 to 130 MBq of 111In-pentetreotide: a first one without any treatment and a second one after a 7-day treatment of short-acting octreotide (600 μg/d). Tumor-to-lung and tumor-to-liver ratios increased at imaging session 2 (1.98 vs 1.83 and 0.78 vs 0.67, respectively).

Long-term Octreotide Treatment Started Before Imaging Session 2

Six studies allow intrapatient comparisons before and after initiation of long-term (between 2 and 13 months) octreotide treatment.

The 2 oldest studies7,8 used 111In-pentetreotide scintigraphy. Janson et al7 compared spleen-to-background and tumor-to-background ratios of 8 patients after 10 to 13 months of lanreotide treatment. The spleen-to-background ratio was reduced by 55%, and the tumor-to-background ratio was increased by 50% (range, −79% to 1087%). A similar study was conducted by Rolleman et al8: 2 scans were performed 50 to 397 days from each other: a significant decrease in spleen uptake was noted (−69%). A nonsignificant decrease in liver, kidney, and tumoral uptake was also observed.

The remaining 4 studies used 68Ga-DOTATATE PET/CT and LAR cSAs. Intrapatient analysis was possible for a subgroup in the study by Haug et al10 (9 patients), a subgroup in the study by Gålne et al14 (19 patients), and the entire population of the other 2 studies (30 patients and 34 patients, respectively).11,13 Tumor uptake was not significantly altered by the pretreatment with cSAs, differently from tumor–to–healthy organ ratios, which were found increased.14 The liver uptake was systematically decreased under cSAs.

Patients Under Long-term Octreotide Treatment Before Baseline Imaging

Aalbersberg et al12 prospectively studied the effect of cSAs on 68Ga-DOTATATE uptake, 1 day before and 1 day after injection of lanreotide in 34 patients whose treatment had been initiated at least 4 months earlier. The tumor-to-liver ratio increased moderately but significantly on day +1 of the analogs (2.59 vs 2.21); liver, spleen, and thyroid uptake decreased significantly.

Jahn et al15 studied the effect of 400-μg octreotide administration at 15 minutes before 68Ga-DOTATOC in 4 patients already treated with LAR cSAs. Three whole-body acquisitions were performed (1, 4, and 7 hours) and compared with a baseline acquisition performed 1 to 3.5 months before. Tumor SUV values decreased significantly from baseline to 1 hour after injection, but subsequently increased over time and became similar to baseline at 4 and 7 hours. The uptake in liver, spleen, and pancreas remained significantly below baseline levels.

Other Studies

The oldest study5 included in our review prospectively gathered 5 patients (2 octreotide-naive patients and 3 patients who withdrew short-acting octreotide 24 hours before imaging). Two sessions of 3 scans (planar acquisitions 0.5, 4, and 24 hours after 105–237 MBq of 111In-pentetreotide) were performed without and with octreotide (600 μg/d) within 28 days from each other. Healthy organs concentrated less tracer under treatment (at 4 hours: −60% for the spleen, −28% for the liver, and −17% for the kidneys), whereas the tumor-to-liver ratio increased (>20%).

Peptide Mass, Cold-to-Radiolabeled Ratio

The administered radiolabeled peptide mass was not available in all studies. In the absence of further pharmacokinetic studies with LAR cSAs, the cold-to-radiolabeled ratio was only calculable with SAR cSAs and encompassed at least the range from 33:1 (50 μg of cold peptide for 1.5 μg of radiolabeled peptide9) to 100:1 (500 μg of cold peptide for 4.95 μg of radiolabeled peptide9).

DISCUSSION Effect of cSAs on Healthy Organs' Uptake

Administration of cSAs consistently resulted in decreased spleen and liver uptake. A total of 10 studies explicitly reported splenic uptake: 9 described a significant decrease and 1 a nonsignificant decrease. The magnitude of the decrease varied between 6.9% and 80%. A similar phenomenon was observed for the liver: 10 studies reported hepatic uptake, 9 of which with a significant decrease (between 10 and 60%) and 1 with a nonsignificant decrease. Data were scarcer for the kidneys' uptake, taking into consideration the proximity of the urinary tract, which may act as a confounding factor. A significant decrease in thyroid uptake was noted in 2 studies and in the pancreas in 1 study. A moderate increase in uptake was noted for the pituitary gland in Cherk and colleagues'13 study. However, the difficulty of measuring this structure may have influenced the result (small size, attenuation correction artifacts).

Effect of cSAs on Tumor Uptake

The time elapse between the 2 imaging studies should be taken into consideration. Indeed, cSAs have a long-term antitumor effect that could decrease tumor fixation due to a volumetric reduction and a partial volume effect.

In 5 studies, the 2 imaging procedures were performed within 1 month from each other.3,5,6,9,12 Four of these 5 studies found an increase in the tumor–to–healthy organ ratio.5,6,9,12 The last one, measuring tumor uptake without normalization, reported stability. These studies seem to indicate that cSAs have little or no effect on tumor uptake and that the increased ratios are driven by the decrease in the uptake of the surrounding organs.

This hypothesis seems to be confirmed by considering the 7 other studies, for which the delay between the 2 images was greater. Five of the 7 studies measured tumor uptake, without any ratio, and found no change8,10,11,13 or a moderate decrease15 under cSAs. The remaining 2 studies, using ratios, confirm an increased uptake.7,14

Timing and Impact of Cold-to-Radiolabeled Ratio

The previously described effects seem to occur whether or not long-term treatment with cSAs has already been initiated. No negative impact on the tumor/healthy organ contrast was observed even when the injection of cSAs took place immediately before the radiotracer (up to 10 minutes before injection).

Bakker et al16 reported complete saturation of SSTR in octreotide-pretreated rats with a cSA–to–111In-pentetreotide ratio of 1000:1. In this experiment, the administration of cSAs prevented visualization of tumor lesions. We hypothesize that this ratio of 1000:1 is likely to be higher than that used in clinical routine and could explain the discrepancies with our results. However, the included studies only occasionally report the ratio between radiolabeled analogs and cSAs.

Clinical Considerations

The benefit of treatment with cSAs is well documented in NETs.2 Long administration of cSAs inhibits tumor growth and prolongs progression-free survival in patients with well-differentiated NETs17 and helps to control the secretory syndrome.2 Treatment with cSA is thus frequently encountered in patients referred for SSTR imaging for a NET.

Our results support the fact that there is no imperative to discontinue cSAs before SSTR imaging. On the contrary, treatment with cSAs before imaging, besides the known effects on symptoms and tumor growth, could improve the contrast and the performances of the examination, a phenomenon that is reminiscent of what has already been shown between 18F-FDOPA and cold carbiDOPA.18 The increase in tumor-to-liver ratio results in better visualization of liver metastases. In clinical practice, this finding should be considered when SSTR imaging is performed for response monitoring.18

In perspective, the data collected could impact recommendations of procedure guidelines. More broadly, these results can also be applied to the field of theranostics: decreasing the uptake of healthy organs while preserving the tumor uptake could be very important for limiting the toxicity of 177Lu-labeled analogs.

LIMITATIONS

The main limitation of this review is the number of analyzable patients in each study (from 4 to 34). However, SSTR imaging is now used primarily for NETs, which are inherently rare. The dosages and mode of administration of cSAs are heterogeneous in terms of quantity and rate of administration, as are the acquisition protocols for planar scintigraphy and PET/CT.

Considering the amount of data analyzed, a risk of collection bias is possible but limited by double reading at all stages of the inclusion process.

CONCLUSIONS

The use of cSAs does not seem to alter the visualization of tumor lesions at SSTR imaging, being able to rather improve contrast by decreasing healthy organs' uptake, particularly in the liver.

REFERENCES 1. Refardt J, Hofland J, Wild D, et al. Molecular imaging of neuroendocrine neoplasms. J Clin Endocrinol Metab. 2022;107:e2662–e2670. 2. Modlin IM, Moss SF, Oberg K, et al. Gastrointestinal neuroendocrine (carcinoid) tumours: current diagnosis and management. Med J Aust. 2010;193:46–52. 3. Lodge MA, Solnes LB, Chaudhry MA, et al. Prospective within-patient assessment of the impact of an unlabeled octreotide pre-dose on the biodistribution and tumor uptake of (68)Ga DOTATOC as assessed by dynamic whole-body PET in patients with neuroendocrine tumors: implications for diagnosis and therapy. Mol Imaging Biol. 2021;23:766–774. 4. Virgolini I, Ambrosini V, Bomanji JB, et al. Procedure guidelines for PET/CT tumour imaging with 68Ga-DOTA-conjugated peptides: 68Ga-DOTA-TOC, 68Ga-DOTA-NOC, 68Ga-DOTA-TATE. Eur J Nucl Med Mol Imaging. 2010;37:2004–2010. 5. Dörr U, Räth U, Sautter-Bihl ML, et al. Improved visualization of carcinoid liver metastases by indium-111 pentetreotide scintigraphy following treatment with cold somatostatin analogue. Eur J Nucl Med. 1993;20:431–433. 6. Soresi E, Invernizzi G, Boffi R, et al. Intensification of 111In-DTPA-octreotide scintigraphy by means of pretreatment with cold octreotide in small cell lung cancer. Lung Cancer. 1997;17:231–238. 7. Janson ET, Kälkner KM, Eriksson B, et al. Somatostatin receptor scintigraphy during treatment with lanreotide in patients with neuroendocrine tumors. Nucl Med Biol. 1999;26:877–882. 8. Rolleman EJ, Kooij PPM, de Herder WW, et al. Somatostatin receptor subtype 2–mediated uptake of radiolabelled somatostatin analogues in the human kidney. Eur J Nucl Med Mol Imaging. 2007;34:1854–1860.

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