1. Introduction:
The liver is an active metabolic organ that is easily influenced by many environmental conditions [1]. Hepatocellular carcinoma (HCC) is ranked as the third most prevalent cause of cancer-related deaths globally [2, 3]. Environmental agents play a dominant role in causing HCC. Exposure to hepatitis B and C viruses are among the most common causes leading to HCC [4]. Other risk factors of HCC include consumption of alcoholic drinks, aflatoxins, diabetes mellitus, and non-alcoholic hepatic steatosis disease, as well as immune-related factors such as autoimmune hepatitis and primary biliary cirrhosis [5, 6].
Despite the presence of different novel treatment options, including cryo-surgery, radio-frequency thermal ablation, and chemo-embolization, the management of patients with severe HCC has remained difficult. Therefore, it is extremely necessary to develop appropriate therapeutic approaches [7]. Radiotherapeutic strategies have been chosen to control tumor growth during the progressive stages of HCC [6]. Radiotherapy can be classified into either internal (IR) or external beam radiotherapy (EBR). EBR can be used solely for tumor growth control or, in most cases, together with chemotherapy. Such combination has not succeeded in therapeutic trials; even so, this combination may still have a positive impact on the tumor. A better way is to target the affected part of the liver via radiation [2]. IR is achieved by delivering radioisotopes to the site of interest through different administration routes. The ideal criteria of the radioisotopes used in IR include: a short half-life, beta (β) ray emission for therapeutic purpose, and a small fraction of gamma (γ) ray emission which is necessary for verification. The most commonly used isotopes are Yttrium-90 (90Y), 131I, and Holmium-199 (199Ho). 90Y is a pure β-emitter with a physical half-life of 2.7 days. It has been introduced by intratumoral injection of 90Y-glass microspheres [6, 8, 9] or via a transarterial strategy. 131I, a mostly β- and a little γ-emitter, with a half-life of 8 days [10], was used as 131I-lipiodol [11, 12]. 199Ho, also mostly a β-ray emitter with little γ emission, with a half-life of 26.8 h, has also been evaluated in a chitosan complex form and was administered either intratumorally or via a transarterial approach [13, 14].
Atorvastatin (ATV) is a drug that inhibits hydroxymethylglutaryl coenzyme A (HMG-CoA) reductase, the enzyme that catalyzes the rate-limiting step of the cholesterol biosynthetic pathway. ATV is among the most frequently prescribed drugs worldwide [15] for the treatment of hypercholesterolemia. ATV is localized in the liver as its target organ [16] and inhibits HMG-CoA reductase. ATV not only competes with the enzyme's active site but also changes its conformation, making the enzyme fail to perform its main function. Additonally, the change in conformation at the active site makes ATV very effective and specific [17]. Previously, statins have been introduced as potential agents for cancer therapy [18-21]. Furthermore, ATV has other biological properties [22] such as anti-inflammatory, antiproliferative, antioxidant, and anti-apoptotic activities [23-25].
Considering the liver targeting ability of ATV, this work was designed to explore the localization and radiotherapeutic efficacy of [131I]atorvastatin in HCC-induced rat models. Therefore, ATV radiolabeling processes with 131I isotope were optimized to deliver this radionuclide to rat livers for the radiotherapy of HCC.
2. Experimental
2.1. Materials and Animals
ATV and chloramine-T (CAT) were ordered from Sigma Aldrich, Homburg, Germany. The rest of the chemicals used were reactive reagents. No-carrier-added 131I (nca Na131I, 3.7 GBq/ml diluted with 0.1 N NaOH) was kindly received from the Radioisotope Production Facility, RPF, EAEA, Cairo, Egypt.
Male albino rats (150 ± 5 g) were collected from the Animal House of Nuclear Researches Center, EAEA, Cairo, Egypt and fed a normal rodent diet. Animals were housed under 12 h of light and 12 h of darkness per day in the animal care unit and maintained at 24–28°C with relative humidity of 60–70% and water given ad libitum.. In a separate, lead-shielded animal shelter, the animals that received [131I]atorvastatin were housed. All animal-related procedures were conducted according to the regulations defined by Animal Ethical-Committee of EAEA.
2.2. Methods
2.2.1. Optimization of [131I]atorvastatin preparation
ATV was electrophilically substituted by the 131I isotope for radiolabeling in the subsistence of CAT as an associate oxidizer. Various parameters (ATV amount, CAT amount, reaction mixture pH, reaction temperature, and reaction time) which influence the reaction were optimized to prepare [131I]atorvastatin. Briefly, different volumes of ATV methanol solution (1 mg/ml), Na131I solution (10 µl, 3.7 MBq), and different volumes of freshly prepared CAT methanol solution (1 mg/ml) were added successively into a tightly screw-capped brown vial. The pH of the reaction solution was adjusted to a wide range of values (2–11) thereafter. The mixtures were completed to the same final volume using double distilled water (DDW) and stirred with a vortex generator for 1 min. After that, the mixtures were incubated at different temperatures ranging from ambient temperature (25 ± 5 °C) up to 100 °C for different reaction times (5–60 min). Finally, the reactions were terminated after the addition of an aqueous solution of sodium metabisulfite (50 µl, 20 mg/ml) and subsequent vortex stirring was performed for 2 min [26].
2.2.2. Radiochemical yield assay
An [131I]atorvastatin radiochemical yield assay was conducted using thin layer chromatography (TLC, silica GF254 plates backed by aluminium). The plates were cut into strips of 1×13 cm. At a point 2 cm from one end, 5 µl of each sample was added and left to dry. The solvent, a homogenous mix of chloroform:ethanol in a ratio 9:1 v/v, was allowed to reach 10 cm from the origin. After drying, the strips were cut into small segments with dimensions of 1 cm by 1 cm each. A well-type NaI gamma-counter, Scaler-Ratemeter SR-7 (Nuclear Enterprises LTD, USA), assessed radioactivity in each segment. [131I]atorvastatin moved with the solvent front and free iodide (131I-) remained at the point of application. The radiochemical yield was calculated by dividing radioiodinated compound activity over the total activity multiplied by 100, according to Eq. (1) [27, 28]:
2.2.3. Radiochemical purity assay of [131I]atorvastatin
The radiochemical purity of the freshly prepared [131I]atorvastatin compound was analyzed via high-performance liquid chromatography (HPLC). HPLC of inactive ATV, radiotracer [131I]atorvastatin, and free iodide were performed using a Shimadzu-model (Kyoto, Japan) detector SpD-6A, with the column RP‐C18, 250 mm × 4.6 mm, 5 μm, and LiChrosorb as a stationary phase. A sample volume (10 µl) was injected and a mixture of DDW and acetonitrile (15:85, v/v) in a medium of pH 4.5 (adjusted with phosphoric acid) that was adjusted by adding phosphoric acid, was utilized as an eluent in the isocratic strategy. The rate of fluid flow was adjusted to 1 ml/min and the UV detector was adjusted to a wavelength of 261 nm [29]. A refractive index detector was used in combination with a NaI gamma scanner detector for monitoring 131I- activity.
2.2.4. Stability of [131I]atorvastatin in vitro
The HPLC-purified [131I]atorvastatin obtained under the optimized reaction conditions was placed at ambient temperature to observe its radiolabeling stability in vitro. The mixture was incubated for 1 day. Stability was evaluated using the TLC method as described before [28] and the result was expressed as percentage of radioactivity of [131I]atorvastatin relative to all radioiodine activity.
2.2.5. HCC induction in rats
Diethyl-nitrosamine (DENA) or N-nitrosamine-related compounds are considered as animal hepatocarcinogens [30]. DENA is commonly used to initiate cancer in HCC induction experiments, whereas other factors such as carbon tetrachloride (CCl4) are introduced as promoters of carcinogenesis [31, 32].
Pure DENA was dissolved in a physiological saline solution (0.9% sodium chloride) and intraperitoneally administered to every rat in a single injection of 200 mg/kg bodyweight [33]. Two weeks later, CCl4 was subcutaneously injected into the animals at a dosage of 3 ml/kg bodyweight once a week for six weeks to boost the carcinogenicity of DENA [34]. At the end of the HCC induction cycle, the animals were made to fast overnight, were anesthetized, and euthanized. Blood samples were then collected, centrifuged at 3,000 rpm for 15 minutes, and the sera carefully isolated and preserved at −20 °C for further biochemical analyses. Hepatic tissue was fixed in 10% buffered formalin and prepared for histopathological examination.
2.2.6. In vivo radiopharmacokinetic evaluation of [131I]atorvastatin in normal and HCC-bearing rats
In this study, two groups of animals, normal rats and HCC-induced rats (five rats for each time point, total of 20 rats per group), were used. The two groups received intravenous injections of 0.2 mCi [131I]atorvastatin (200 µl) to determine the biodistribution of the radioiodinated compound at 1, 2, 4 and 8 h post injection (p.i.) The rats did not receive inactive iodine prior to the experiment. Thereafter, the injected rats were anesthetized by chloroform and were euthanized. Organ and tissue samples (blood, bone and muscle) were isolated, weighed, counted, and claimed to be 7, 10, and 40 percent of the overall weight, respectively [35]. Next, the heart, liver, spleen, lungs, kidneys, intestine, stomach, and thyroid glands, were excised, washed with normal saline, and weighed carefully. Radioactivity uptake in these organs was then measured using a gamma counter. The radioactivity concentration in the organs and body fluids were reported as percent injected dose per gram (%ID/g).
2.2.7. Radiotherapeutic efficacy of [131I]atorvastatin on rats with HCC
A maximum of ten rats with HCC were divided randomly into two groups (treatment group and control group) to evaluate the radiotherapeutic efficacy of [131I]atorvastatin. A dose of 0.1 ml [131I]atorvastatin (5 mCi/day) was injected intravenously into the tail vein of each rat as a bolus dose for 3 days. The control group received 0.1 ml of 0.9% sodium chloride intravenously for comparison. The rats were then anesthetized after treatment and euthanized. The blood samples and liver tissues were collected as described before.
2.2.8. Statistical analysis
SPSS software was used to conduct all statistical analyses (version 20; SPSS Inc., Chicago, IL). Values are expressed as the mean ± standard deviation of three independent optimization processes for radiolabeling experiments and five independent biological studies experiments. The statistical analysis between groups was carried out using one-way ANOVA. A p-value < 0.05 was considered to be statistically significant.
3. Results and discussion
3.1. Radiochemistry
ATV (100 µg) was radiolabeled with 131I isotope via an electrophilic substitution reaction after oxidizing radioiodide (131I-) to iodonium ion using 100 µg of CAT. The reaction mixture, adjusted to be of neutral pH, was incubated at ambient condition for 30 minutes. The maximum radiochemical output of the prepared [131I]atorvastatin was 86.7 ± 0.49%.
Figure 1 illustrates the chemical scheme of [131I]atorvastatin radiolabeling which was unambiguously determined by Moustapha et al. [36] by synthesizing the 127I analog. Moreover, the synthesized [127I]atorvastatin was interpreted using elemental analysis, mass spectrometry, and proton-NMR strategies [36].
-202011/1001-8042-31-11-001/media/1001-8042-31-11-001-F001.jpg)
The radioiodination of ATV, the influence of ATV amount, CAT amount, pH of the medium, incubation temperature, and incubation time on the radio yield of [131I]atorvastatin were systemically altered to optimize the radioiodination conditions.
As shown in Fig. 2, when the amount of ATV was increased from 50 µg to 100 µg, the radio yield increased from 66.5 ± 0.41% to 86.7 ± 0.49%, respectively. It was found that any further increase in the amount of ATV was accompanied by a notable decrease in the radiochemical yield, thereby demonstrating that 100 µg of ATV was enough to capture all of the released iodonium cations [37]. Alternatively, it may be due to the fact that the molarity of ATV exceeded the molarity of iodonium cations in the solution [38]. In addition, upon increasing the amount of ATV, solubility become an important factor [39]. An increase in ATV concentration may lead to insufficient solubility, which made the radiolabeling process difficult, consequently leading to a decrease in the radio yield [39].
-202011/1001-8042-31-11-001/media/1001-8042-31-11-001-F002.jpg)
Figure 3 shows that by using CAT as an oxidizing agent, radiochemical yield increased with increasing CAT concentration until it reached 86.7 ± 0.49%, when the amount of CAT was 100 µg. Furthermore, it was noticed that the radiochemical yield decreased with any further increase in CAT amount, which is explained by the genesis of oxidative byproducts.
-202011/1001-8042-31-11-001/media/1001-8042-31-11-001-F003.jpg)
The radiochemical yield, as seen in Fig. 4, depended heavily on the pH of the reaction solution. By increasing the pH up to 7, the radioiodination rate was obviously improved. Subsequently, it decreased with a further increase in the pH value; thus the peak radiochemical yield of [131I]atorvastatin (86.7 ± 0.49%) was reached at around pH 7. This might be explained by the fact that by producing HOI species, CAT functions well as an oxidizer in neutral media [40]. It might also be associated with the improved stability of the [131I]atorvastatin and the good performance of the direct radioiodination processes at pH 7.
-202011/1001-8042-31-11-001/media/1001-8042-31-11-001-F004.jpg)
The influence of incubation temperature on the radio yield of [131I]atorvastatin was also investigated. The results are shown in Fig. 5 and seem to suggest that ambient temperature (25 ± 5 °C) has the highest impact on the radiochemical yield of [131I]atorvastatin, which reached its maximum value of 86.7 ± 0.49%. It was found that raising the reaction temperature above the ambient temperature led to a lowering of the radio yield of [131I]atorvastatin, which shows that [131I]atorvastatin had poor stability at elevated temperatures.
-202011/1001-8042-31-11-001/media/1001-8042-31-11-001-F005.jpg)
Additionally, it is evident in Fig. 6 that incubation time substantially influences the radio yield of [131I]atorvastatin, where the highest value (86.7 ± 0.49 %) was achieved after incubation for 30 minutes.
-202011/1001-8042-31-11-001/media/1001-8042-31-11-001-F006.jpg)
Analysis of [131I]atorvastatin via HPLC illustrated that ~85% of 131I binds with ATV (Fig. 7), forming a single labeled compound. The retention time for inactive ATV was 6 min, the retention time for [131I]atorvastatin was 9 min, whereas the retention time for free 131I- was 3 min. [131I]atorvastatin-containing fractions were eluted, pooled together, evaporated to dryness, and dissolved in physiological saline. Finally, the [131I]atorvastatin solution was filtered through a Millipore filter (0.22 μm) and used in biodistribution studies.
-202011/1001-8042-31-11-001/media/1001-8042-31-11-001-F007.jpg)
The in vitro stability of HPLC-purified [131I]atorvastatin was evaluated upon incubation at ambient temperature up to 24 h. It is important to note that the percentage of radioactivity of [131I]atorvastatin relative to all radioiodine activity was 99.8 ± 0.08% and 99.5 ± 0.09% at 1 and 12 h post labeling, respectively. [131I]atorvastatin deiodinated at a much slower rate over time, implying its good stability up to 12 h (Table 1). It is worth mentioning that, although the radioactivity percentage of [131I]atorvastatin (98.7 ± 0.31) significantly differed from the others at 24 h, it indicated a good stability of the radio-labelled compound. The in vitro stability of the [131I]atorvastatin enabled it to be used as a radiotracer for cancer therapy.
| Incubation time (h) | Radiochemical yield of [131I]atorvastatin (%) | Free iodide (%) |
|---|---|---|
| 1 | 99.8 ± 0.08 | 0.2 ± 0.08 |
| 2 | 99.8 ± 0.09 | 0.2 ± 0.09 |
| 4 | 99.7 ± 0.13 | 0.3 ± 0.13 |
| 8 | 99.6 ± 0.22 | 0.4 ± 0.22 |
| 12 | 99.5 ± 0.09 | 0.5 ± 0.09 |
| 24 | 98.7 ± 0.31 | 1.3 ± 0.31 |
3.2. Animal experiments
Serum aspartate-transaminase (AST) and alanine-transaminase (ALT) are the prime enzyme biomarkers used to observe hepatic constitutional function and injury, and they also assists in the identification of hepatotoxicity [41]. Additionally, alpha fetoprotein (AFP) is the most prevalent tumor marker applied in HCC screening [42]. Elevation of AFP grade denotes poor prognosisin contrast to the low AFP grades [43, 44]. The reference values of AST, ALT, and AFP are 50–150 IU/L, 10–40 IU/L, and 2–20 ng/ml, respectively [45]. As shown in Table 2, the group that received DENA/CCl4 demonstrated a significant rise in the biochemical markers ALT, AST, and AFP when compared to the negative control group as well as to the normal values.
| Biochemical parameter, | DENA/CCl4-treated group | Negative control |
|---|---|---|
| AST, IU/L | 575±10 | 175±8 |
| ALT, IU/L | 360±5 | 53±7 |
| AFP, ng/mL | 51±2 | 18±1.5 |
Histological analysis (Fig. 8) showed that low-grade HCC was composed of moderately pleomorphic cells with prominent nucleoli arranged in a trabecular pattern, separated by thin fibrovascular septa, and micro- and macrovesicular steatosis, which indicated the successful induction of HCC in rats.
-202011/1001-8042-31-11-001/media/1001-8042-31-11-001-F008.jpg)
Treatment of HCC often leads to poor results [46]. Therefore, it is necessary to pursue better therapy modalities to offer hope for patients with HCC. In the current study, [131I]atorvastatin was used as a relatively novel radioformula to evaluate its impact as a treatment for HCC. In this investigation, the β-emitter 131I isotope was chosen to radiolabel ATV.
The tissue uptake pattern of [131I]atorvastatin in animals is illustrated in Table 3. The analysis suggests that the rescue of the radiotracer from circulation was slightly low as the proportion decreased from 10.1 ± 2.5% at 1 h p.i. to 3.99 ± 0.9% at 8 h p.i. This may be due to the ability of ATV to bind plasma protein. The liver-targeting ability of [131I]atorvastatin was also observed as there was a high uptake in the liver, which reached its maximum value of 20.3 ± 3.9%, at 2 h p.i. Because the elimination of ATV happens through the liver, the gut content of the radio compound elevated over time from 13.2 ± 2.9% at 1 h p.i to 20.45 ± 3.4% at 8 h p.i. Although [131I]atorvastatin is metabolized by the liver, part of it is eliminated through the kidneys. Radioactivity was found in the kidneys, confirming that hypothesis, and the radioactivity in urine increased with time. The other organs (bone, lung, heart, muscles, and spleen) showed a minimal uptake. The thyroid glands showed normal uptake over time, which indicated the in vivo stability of [131I]atorvastatin.
| Organ/Body fluid | %ID/g at different time intervals | |||
|---|---|---|---|---|
| 1 h | 2 h | 4 h | 8 h | |
| Blood | 10.1±2.5 | 8.11±1.7 | 5.81±1.2 | 3.99±0.9 |
| Heart | 0.35±0.05 | 0.76±0.2 | 0.42±0.06 | 0.22±0.03 |
| Lungs | 0.87±0.1 | 3.25±0.9 | 1.3±0.3 | 0.93±0.02 |
| Spleen | 0.62±0.04 | 0.97±0.1 | 0.72±0.2 | 0.28±0.02 |
| Liver | 15.31±3.2 | 20.3±3.9 | 12.31±1.9 | 9.61±1.3 |
| Kidneys | 3.06±0.4 | 3.09±0.2 | 2.71±0.98 | 1.22±0.78 |
| Intestine | 13.2±2.9 | 14.05±1.7 | 18.43±2.7 | 20.45±3.4 |
| Stomach | 12.54±1.8 | 14.2±1.6 | 17.15±2.5 | 19.89±2.9 |
| Bone | 3.37±0.8 | 5.21±1.1 | 2.98±0.5 | 1.34±0.02 |
| Muscles | 2.89±0.2 | 3.15±0.3 | 3.71±0.4 | 0.9±0.01 |
| Urine | 4.03±0.9 | 5.13±1.3 | 6.84±1.6 | 7.47±1.1 |
| Thyroid glands | 0.02±0.01 | 0.08±0.02 | 0.12±0.01 | 0.09±0.01 |
The tissue distribution profile of [131I]atorvastatin in HCC-induced rat models upon intravenous administration is demonstrated in Table 4. The analysis shows that [131I]atorvastatin uptake was focused in the liver, with a percentage equal to 30.01 ± 4.3% at 2 h p.i. The results revealed the ability of [131I]atorvastatin to target the radionuclide, 131I, in the HCC area, which indicated the potential use of ATV as a vehicle to deliver 131I isotopes to liver tissues for radiotherapy in HCC.
| Organ/Body fluid | %ID/g at different time intervals | |||
|---|---|---|---|---|
| 1 h | 2 h | 4 h | 8 h | |
| Blood | 8.1±2.1 | 6.11±2.2 | 3.81±1.1 | 1.99±0.8 |
| Heart | 0.27±0.03 | 0.65±0.1 | 0.31±0.1 | 0.06±0.01 |
| Lungs | 0.61±0.05 | 1.42±0.1 | 0.34±0.1 | 0.16±0.01 |
| Spleen | 0.41±0.02 | 0.77±0.09 | 0.19±0.02 | 0.09±0.02 |
| Liver | 26.91±3.2 | 30.01±4.3 | 19.89±2.68 | 15.85±1.32 |
| Kidneys | 3.84±0.5 | 6.03±2.27 | 5.13±1.5 | 2.47±0.7 |
| Intestine | 11.2±1.32 | 14.15±1.58 | 23.3±3.5 | 25.31±3.1 |
| Stomach | 9.15±1.27 | 11.04±1.37 | 13.43±2.1 | 15.2±1.7 |
| Bone | 2.89±0.03 | 4.31±1.1 | 2.45±0.56 | 0.61±0.1 |
| Muscles | 1.36±0.06 | 2.29±0.41 | 0.71±0.05 | 0.22±0.02 |
| Urine | 3.54±0.1 | 5.58±0.62 | 5.71±1.3 | 7.21±1.1 |
| Thyroid glands | 0.07±0.01 | 0.18±0.02 | 0.22±0.02 | 0.03±0.01 |
Figure 9 illustrates the difference of liver uptakes of [131I]atorvastatin at different time points in normal and HCC-bearing rats. The p values were calculated for each time point and found to be less than 0.01 at 1 and 4 h p.i. Meanwhile, the p values were found to be less than 0.05 at 2 h p.i. and less than 0.001 at 8 h p.i. These findings confirmed the significant difference between the uptake of [131I]atorvastatin in the normal rat liver and HCC liver at different time intervals.
-202011/1001-8042-31-11-001/media/1001-8042-31-11-001-F009.jpg)
The effects of [131I]atorvastatin on selected biochemical parameters (AST, ALT, and AFP) are presented in Table 5. It was found that [131I]atorvastatin administration resulted in a significant decrease in all tested enzyme activities, including AFP, in blood plasma compared to the control group: by 60.6 % for AST, 77.9 % for ALT, and 51 % for AFP (p< 0.05).
| Biochemical parameter | [131I]atorvastatin treated group | Control group |
|---|---|---|
| AST (IU/L) | 189±7.4 | 480±10 |
| ALT (IU/L) | 64±6.5 | 290±8 |
| AFP (ng/mL) | 24±1.1 | 49±2.3 |
Figure 10 shows a liver containing portal tracts with dilated, congested, and thrombosed portal veins, fibrous bands extending from one portal tract to another (P-P), dilated central veins with a detached lining, scattered apoptosis in peri-portal and peri-venular areas, macro- and microvesicular steatosis more marked in peri-venular area, and no viable tumor cells. In contrast, no histopathological changes were observed in the control group (data not shown). After [131I]atorvastatin radiotherapy, all the data yielded results confirming the positive impact of [131I]atorvastatin on HCC.
-202011/1001-8042-31-11-001/media/1001-8042-31-11-001-F010.jpg)
4. Conclusion
Our hypothesis regarding the potential use of [131I]atorvastatin as a radiopharmaceutical agent for HCC radiotherapy was successfully confirmed in this study. ATV was radioiodinated using the beta emitter 131I isotope, generating 86.7% of stable [131I]atorvastatin for 12 h in vitro. The biodistribution profile of [131I]atorvastatin in both normal and HCC-induced rat models showed a good localization in liver tissues even at 2 h p.i. Interestingly, biochemical parameter analysis (AST, ALT, and AFP) and histopathological studies provided evidence that [131I]atorvastatin has a positive impact against DENA/CCl4-induced HCC in rats.
Author’s Contributions
Nourihan S. Farrag carried out the practical work and analyzed the data. Abeer M. Amin supervised the design of the experimental plan. All the authors wrote and revised the manuscript.
Radiation-Induced Reactions in The Liver - Modulation of Radiation Effects by Lifestyle-Related Factors
. Int J Mol Sci, 19(12): 3855 (2018). https://doi.org/10.3390/ijms19123855Challenge and hope in radiotherapy of hepatocellular carcinoma
. Yonsei Med J, 50(5): 601-612 (2009). https://doi.org/10.3349/ymj.2009.50.5.601Development of Semiautomated Module for Preparation of (131)I Labeled Lipiodol for Liver Cancer Therapy
. Cancer Biother Radiopharm, 32(1): 33-37 (2017). https://doi.org/10.1089/cbr.2016.2088Epidemiology of hepatocellular carcinoma
. Clin Liver Dis, 9(2): 191-211 (2005) https://doi.org/10.1016/j.cld.2004.12.009Hepatocellular cancer: a guide for the internist
. Am J Med, 120(3): 194-202 (2007). https://doi.org/10.1016/j.amjmed.2006.11.020Role of radiotherapy in the management of hepatocellular carcinoma: A systematic review
. World J Hepatol, 7(1): 101-112 (2015). https://doi.org/10.4254/wjh.v7.i1.101Sodium iodide symporter (NIS)-mediated radionuclide ((131)I, (188)Re) therapy of liver cancer after transcriptionally targeted intratumoral in vivo NIS gene delivery
. Hum Gene Ther, 22(11): 1403-1412 (2011). https://doi.org/10.1089/hum.2010.158Treatment of nonresectable hepatocellular carcinoma with intrahepatic 90Y-microspheres
. J Nucl Med, 41(10): 1673-1681 (2000). PMID: 11037997Yttrium-90 microspheres for the treatment of hepatocellular carcinoma
. Gastroenterology, 127(5 Suppl 1): S194-S205 (2004). https://doi.org/10.1053/j.gastro.2004.09.034In Vitro Incorporation of Radioiodinated Eugenol on Adenocarcinoma Cell Lines (Caco2, MCF7, and PC3)
. Cancer Biother Radiopharm, 32(3): 75-81 (2017). https://doi.org/10.1089/cbr.2017.2181A randomized prospective trial comparing full dose chemotherapy to 131I antiferritin: an RTOG study
. Int J Radiat Oncol Biol Phys, 20(5): 953-963 (1991). https://doi.org/10.1016/0360-3016(91)90191-6Prospective randomized trial of chemoembolization versus intra-arterial injection of 131I-labeled-iodized oil in the treatment of hepatocellular carcinoma
. Hepatology, 26(5): 1156-1161 (1997). https://doi.org/10.1002/hep.510260511Long-term clinical outcome of phase IIb clinical trial of percutaneous injection with holmium-166/chitosan complex (Milican) for the treatment of small hepatocellular carcinoma
. Clin Cancer Res, 12(2): 543-548 (2006). https://doi.org/10.1158/1078-0432.CCR-05-1730Phase II study of transarterial holmium-166-chitosan complex treatment in patients with a single, large hepatocellular carcinoma
. Oncology, 76(1): 1-9 (2009). https://doi.org/10.1159/000173735Statins and liver injury
. Gastroenterol Hepatol (N Y), 9(9): 605-606 (2013). PMID: 24729773Statins and primary liver cancer: a meta-analysis of observational studies
. Eur J Cancer Prev, 22(3): 229-234 (2013). https://doi.org/10.1097/CEJ.0b013e328358761aStatins: mechanism of action and effects
. J Cell Mol Med, 5(4): 378-387 (2001). https://doi.org/10.1111/j.1582-4934.2001.tb00172.xChemopreventive efficacy of Atorvastatin against nitrosamine-induced rat bladder cancer: antioxidant, anti-proliferative and anti-inflammatory properties
. Int J Mol Sci, 13(7): 8482-8499 (2012). https://doi.org/10.3390/ijms13078482Statins and cancer prevention
. Nat Rev Cancer, 5(12): 930-942 (2005). https://doi.org/10.1038/nrc1751Cholesterol, statins and cancer
. Clin Exp Pharmacol Physiol, 34(3): 135-141 (2007). https://doi.org/10.1111/j.1440-1681.2007.04565.xStatins in tumor suppression
. Cancer Lett, 260(1-2): 11-19 (2008). https://doi.org/10.1016/j.canlet.2007.11.036Pleiotropic effects of statins
. Annu Rev Pharmacol Toxicol, 45: 89-118 (2005). https://doi.org/10.1146/annurev.pharmtox.45.120403.095748Inflammation, immunity, and HMG-CoA reductase inhibitors: statins as antiinflammatory agents?
Circulation, 109(21 Suppl 1): II18-II26 (2004). https://doi.org/10.1161/01.CIR.0000129505.34151.23Cellular antioxidant effects of atorvastatin in vitro and in vivo
. Arterioscler Thromb Vasc Biol, 22(2): 300-305 (2002). https://doi.org/10.1161/hq0202.104081Anti-apoptotic effect of atorvastatin, a 3-hydroxy-3-methylglutaryl coenzyme a reductase inhibitor, on cardiac myocytes through protein kinase C activation
. Clin Exp Pharmacol Physiol, 31(5-6): 360-364 (2004). https://doi.org/10.1111/j.1440-1681.2004.04010.xFacile radiolabeling optimization process via design of experiments and an intelligent optimization algorithm: Application for omeprazole radioiodination
. J Labelled Comp Radiopharm, 62(6): 280-287 (2019). https://doi.org/10.1002/jlcr.3734Iodine-125-Chlorambucil as Possible Radioanticancer for Diagnosis and Therapy of cancer: preparation and tissue distribution British
Journal of Pharmaceutical Research, 4(15): 1873-1885 (2014). https://doi.org/10.9734/BJPR/2014/10520Comparative study on radiolabeling and biodistribution of core-shell silver/polymeric nanoparticles-based theranostics for tumor targeting
. Int J Pharm, 529(1-2): 123-133 (2017). https://doi.org/10.1016/j.ijpharm.2017.06.044Development and validation of RP-HPLC method for determination of Atorvastatin calcium and Nicotinic acid in combined tablet dosage form
. Journal of Saudi Chemical Society, 20: S328-S333 (2016). https://doi.org/10.1016/j.jscs.2012.12.005Potential preventive effect of carvacrol against diethylnitrosamine-induced hepatocellular carcinoma in rats
. Mol Cell Biochem, 360(1-2): 51-60 (2012). https://doi.org/10.1007/s11010-011-1043-7Melatonin modulates the oxidant-antioxidant imbalance during N-nitrosodiethylamine induced hepatocarcinogenesis in rats
. J Pharm Pharm Sci, 8(2): 316-321 (2005). PMID: 16124941Prevention by melatonin of hepatocarcinogenesis in rats injected with N-nitrosodiethylamine
. J Pineal Res, 43(3): 305-312 (2007). https://doi.org/10.1111/j.1600-079X.2007.00478.xBeta-carotene inhibits rat liver chromosomal aberrations and DNA chain break after a single injection of diethylnitrosamine
. Br J Cancer, 76(7): 855-861 (1997). https://doi.org/10.1038/bjc.1997.475.Therapeutic efficacy of licorice and/or cisplatin against diethylnitrosamine and carbon tetrachloride-induced hepatocellular carcinoma in rats
Journal of American Science, 12(1): 10-19 (2016). https://doi.org/10.7537/marsjas120116.02.Platelet-12 lipoxygenase targeting via a newly synthesized curcumin derivative radiolabeled with technetium-99m
. Chem Cent J, 10: 73 (2016). https://doi.org/10.1186/s13065-016-0220-x.Organic Synthesis of Iodinated Atorvastatin via Nucleophilic Substitution Reaction: Experimental and DFT Studies
. Current Organic Chemistry, 22: 2017-2022 (2018). https://doi.org/10.2174/1385272822666180913111819.Novel radioiodinated sibutramine and fluoxetine as models for brain imaging
. J Radioanal Nucl Chem, 2011. 289: 915-921. https://doi.org/10.1007/s10967-011-1182-z.Purification and biological evaluation of radioiodinated clozapine as possible brain imaging agent
. J Radioanal Nucl Chem 304: 837-844 (2015). https://doi.org/10.1007/s10967-014-3894-3.Labeling and evaluation of 99mTc-tricarbonylmeloxicam as a preferential COX-2 inhibitor for inflammation imaging
. J. Label Compd. Radiopharm 59: 284-290 (2016). https://doi.org/10.1002/jlcr.3396.An investigation of the 125I-radioiodination of colchicine for medical purposes
J. Label Compd. Radiopharm. 52:1-5 (2008). https://doi.org/10.1002/jlcr.1556.Enhancement of lindane-induced liver oxidative stress and hepatotoxicity by thyroid hormone is reduced by gadolinium chloride
. Free Radic Res, 36(10): 1033-1039 (2002). https://doi.org/10.1080/1071576021000028280.Alpha-fetoprotein-L3 in hepatocellular carcinoma: a meta-analysis
. Clin Chim Acta, 425: 212-220 (2013). https://doi.org/10.1016/j.cca.2013.08.005AFP-L3: a new generation of tumor marker for hepatocellular carcinoma
. Clin Chim Acta, 313(1-2): 15-19 (2001). https://doi.org/10.1016/S0009-8981(01)00644-1Elevation of tumour markers TGF-beta, M2-PK, OV-6 and AFP in hepatocellular carcinoma (HCC)-induced rats and their suppression by microalgae Chlorella vulgaris
. BMC Cancer, 17(1): 879 (2017). https://doi.org/10.1186/s12885-017-3883-3.Biochemical and histopathological profiling of Wistar rat treated with Brassica napus as a supplementary feed
Food Science and Human Wellness 7: 77-82 (2018). https://doi.org/10.1016/j.fshw.2017.12.002Evaluating the potential of (188)Re-ECD/lipiodol as a therapeutic radiopharmaceutical by intratumoral injection for hepatoma treatment
. Cancer Biother Radiopharm, 24(5): 535-541 (2009). https://doi.org/10.1089/cbr.2008.0603.