Pharmacokinetics and Tissue Distribution of Enavogliflozin in Mice and Rats

This study investigated the pharmacokinetics and tissue distribution of enavogliflozin, a novel sodium-glucose cotransporter 2 inhibitor that is currently in phase three clinical trials. Enavogliflozin showed dose-proportional pharmacokinetics following intravenous and oral administration (doses of 0.3, 1, and 3 mg/kg) in both mice and rats. Oral bioavailability was 84.5–97.2% for mice and 56.3–62.1% for rats. Recovery of enavogliflozin as parent form from feces and urine was 39.3 ± 3.5% and 6.6 ± 0.7%, respectively, 72 h after its intravenous injection (1 mg/kg), suggesting higher biliary than urinary excretion in mice. Major biliary excretion was also suggested for rats, with 15.9 ± 5.9% in fecal recovery and 0.7 ± 0.2% in urinary recovery for 72 h, following intravenous injection (1 mg/kg). Enavogliflozin was highly distributed to the kidney, which was evidenced by the AUC ratio of kidney to plasma (i.e., 41.9 ± 7.7 in mice following its oral administration of 1 mg/kg) and showed slow elimination from the kidney (i.e., T1/2 of 29 h). It was also substantially distributed to the liver, stomach, and small and large intestine. In addition, the tissue distribution of enavogliflozin after single oral administration was not significantly altered by repeated oral administration for 7 days or 14 days. Overall, enavogliflozin displayed linear pharmacokinetics following intravenous and oral administration, significant kidney distribution, and favorable biliary excretion, but it was not accumulated in the plasma and major distributed tissues, following repeated oral administration for 2 weeks. These features may be beneficial for drug efficacy. However, species differences between rats and mice in metabolism and oral bioavailability should be considered as drug development continues.


Introduction
Sodium-glucose cotransporter 2 (SGLT2) is abundantly expressed in the S1 segment of the proximal kidney and plays a major role in the reabsorption of filtered glucose [1]. Based on this mechanism, SGLT2 inhibitors have been developed as antidiabetic drugs that achieve glycemic control by inhibiting renal tubular glucose reabsorption [2] and reducing the risk of hypoglycemia [3]. Additionally, SGLT2 inhibitors show beneficial effects on cardiovascular risk and nephrotoxicity [4][5][6][7][8][9].
Several SGLT2 inhibitors, such as canagliflozin, dapagliflozin, empagliflozin, and ipragliflozin etc., are approved for the treatment of type 2 diabetes [3,10]. These SGLT2 inhibitors show higher inhibitory potency for SGLT2 than for SGLT1 (more than 400-fold) and half-maximal inhibitory concentrations (IC 50 ) for SGLT2 are in the low nanomolar

Pharmacokinetic Study
Male Institute of Cancer Research (ICR) mice (7 weeks old, 27-33 g) and male Sprague Dawley (SD) rats (7 weeks old, 230-250 g) were purchased from Samtako Co. (Osan, Kyunggido, Korea). The animals were acclimatized for one week in an animal facility at the College of Pharmacy, Kyungpook National University. Food and water were available ad libitum.

Pharmacokinetic Study
Fifty-four ICR mice were randomly divided into nine groups (n = 6 per group; Table 1) and intravenously administered an enavogliflozin solution at doses of 0.3, 1, and 3 mg/kg. The drug was dissolved in a mixture of 10% DMSO and 90% saline and injected via the tail vein. Before blood sampling, mice were anesthetized for 5 min using 2% isoflurane in a vaporizer with an oxygen flow of 0.8 L/min. Blood sampling used a sparse sampling method via the right or left retro-orbital vein using heparinized capillary tubes (Heinz Herenz, Hamburg, Germany). Final blood was collected from the abdominal artery using a heparin-treated 1 mL syringe (Jung Lim Co. Ltd., Choong-Buk, Korea) under isoflurane anesthesia (Table 1). Blood samples were collected at 0, 0.083, 0.25, 0.5, 1, 2, 4, 8, and 24 h and centrifuged at 12,000× g for 1 min to separate plasma. An aliquot (30 µL) of each plasma sample was stored at −80 • C until enavogliflozin analysis.
Mice were fasted with water ad libitum for at least 12 h before oral administration with enavogliflozin. Fifty-four mice were randomly divided into nine groups (n = 6 per group, Table 1) and were administered an enavogliflozin solution at doses of 0.3, 1, and 3 mg/kg via oral gavage. The drug was dissolved in a mixture of 10% DMSO and 90% saline. Blood samples were collected at 0, 0.083, 0.25, 0.5, 1, 2, 4, 8, and 24 h with the same procedures described above and provided in Table 1. Three mice received enavogliflozin (1 mg/kg) intravenously and were returned to metabolic cages with food and water ad libitum and urine and feces samples were collected every 24 h for 72 h. Urine and feces were weighed, and 30 µL aliquots of urine and 50 µL aliquots of 10% feces homogenates were stored at −80 • C until enavogliflozin analysis. Four mice received enavogliflozin (1 mg/kg) by oral gavage and were returned to their metabolic cages to collect urine and feces samples every 24 h for 72 h with the same protocols described above.
Twelve rats were randomly divided into three groups (n = 4 per each group) and injected with an enavogliflozin solution at doses of 0.3, 1, and 3 mg/kg. The drug was dissolved in a mixture of 10% DMSO and 90% saline and administered intravenously via the tail vein. Before blood sampling, rats were anesthetized using 2% isoflurane in a vaporizer with an oxygen flow of 0.8 L/min, for 5 min. Blood samples (approximately 100 µL) were collected at 0, 0.05, 0.33, 0.67, 1, 2, 4, 6, and 8 h via the jugular vein under isoflurane anesthesia using a heparin-treated 1 mL syringe (Jung Lim Co. Ltd., Jincheon, Korea). Samples were centrifuged at 12,000× g for 1 min to separate the plasma. An aliquot (30 µL) of each plasma sample was stored at −80 • C until analysis.
Rats were fasted with water ad libitum for at least 12 h before the oral administration of enavogliflozin. Eighteen rats were randomly divided into three groups (n = 6 per each group) and administered the drug dissolved in a mixture of 10% DMSO and 90% saline at doses of 0.3, 1, and 3 mg/kg by oral gavage. Blood samples were collected at 0, 0.083, 0.25, 0.5, 1, 2, 4, 6, 8, and 24 h with the same procedures described above.
Three rats received enavogliflozin (1 mg/kg) intravenously and were returned to metabolic cages with food and water ad libitum and urine and feces samples were collected every 24 h for 72 h. Four rats received enavogliflozin (1 mg/kg) by oral gavage and were returned to their metabolic cages to collect urine and feces samples every 24 h for 72 h with the same protocols described above.

Tissue Distribution Study
Thirty-six ICR mice were fasted with water ad libitum for at least 12 h before oral administration of enavogliflozin and randomly divided into six groups (n = 6 per each sampling time point) and administered with an enavogliflozin solution at a dose of 1 mg/kg via oral gavage. Blood samples (approximately 0.2 mL) were collected at 0.5, 1, 2, 4, 8, 24 h via the abdominal artery. Subsequently, whole tissues, including stomach, small intestine, large intestine, liver, kidney, brain, heart, lung, spleen, and testis, were isolated. Blood samples were centrifuged at 12,000× g for 1 min to separate plasma. Tissue samples were minced thoroughly and homogenized with four volumes of saline using a tissue grinder. An aliquot (30 µL) of plasma and aliquots (50 µL) of tissue homogenate samples were stored at −80 • C until analysis.
Thirty-five ICR mice were randomly divided into five groups (n = 7 per sampling time point) and administered with an enavogliflozin solution (1 mg/kg, once daily) for 14 days via oral gavage. Another thirty-five ICR mice were randomly divided into five groups (n = 7 per sampling time point) and administered with an enavogliflozin solution (1 mg/kg, once daily) for 7 days via oral gavage. The other thirty-five ICR mice were randomly divided into five groups (n = 7 per sampling time point) and administered with an enavogliflozin solution at a dose of 1 mg/kg via oral gavage. Blood samples (approximately 0.2 mL) were collected at 1, 2, 8, 24, and 48 h via the abdominal artery. Subsequently, whole tissues, including kidney, liver, small intestine, and large intestine, were isolated. An aliquot (30 µL) of plasma and aliquots (50 µL) of tissue homogenate samples were prepared and stored with the same procedures described above.

LC-MS/MS Analysis of Enavogliflozin
Concentrations of enavogliflozin in plasma and tissue homogenate samples were analyzed using an Agilent 6430 triple quadrupole liquid chromatography-mass spectrometry (LC-MS/MS) system (Agilent, Wilmington, DE, USA) following a previously published method [20].
Aliquots of plasma or urine (30 µL each) and tissue homogenate (50 µL each) were added to 100 µL of aqueous solution of d4-enavogliflozin (IS, 20 ng/mL), and vigorously mixed with 500 µL MTBE for 15 min. After centrifugation at 16,000× g for 5 min, samples were kept for 1 h, at a temperature of −80 • C to freeze the aqueous layer freeze. The organic upper layer was then transferred to a clean tube and evaporated to dryness under a gentle stream of nitrogen. The dried extract was reconstituted in 150 µL of mobile phase, and a 3 µL aliquot was injected into the LC-MS/MS system. Enavogliflozin was separated on a Synergi Polar RP column (2.0 × 150 mm, 4 µm particle size; Phenomenex, Torrence, CA, USA) using a isocratic mobile phase consisting of water (15%) and methanol (85%) containing 0.1% formic acid at a flow rate of 0.25 mL/min. Quantification of the analyte peak at m/z 464 → 131 for enavogliflozin (T R (retention time) 2.8 min), and m/z 468 → 135 for d4-enavogliflozin (T R 2.8 min) used positive ionization mode with a collision energy of 25 eV. The calibration standards of enavogliflozin in the plasma and tissue homogenates were linear in the range of 5-3000 ng/mL. The inter-day and intra-day precision and accuracy were within 15% for respective quality control samples (5,15,250, and 2000 ng/mL). Extraction recovery and matrix effect were in the range of 80.7-89.0% and 98.40-108.2%, respectively.

Statistics
The data were expressed as the means ± standard deviation for the groups. Pharmacokinetic parameters, such as the area under the plasma concentration-time curve during the period of observation (AUC last ), AUC to infinite time (AUC ∞ ), clearance (CL), and volume of distribution at steady-state (V d,ss ), the terminal half-life (t 1/2 ), and mean residence time (MRT) were calculated using non-compartment analysis with WinNonlin software (version 5.1; Pharsights, Cary, NC, USA). The AUC ratios were calculated by dividing the AUC last of enavogliflozin in the tissue samples by the plasma AUC last values of enavogliflozin [15].
The normal distribution of the data was assessed using the Shapiro-Wilk test for normality and comparisons of the pharmacokinetic parameters (i.e., AUC ∞ /D, C o /D, CL, V d,ss , T 1/2 , MRT in both mice and rats following intravenous administration of enavogliflozin; AUC ∞ /D, C max /D, T max , T 1/2 , MRT in both mice and rats following oral administration of enavogliflozin; AUC and AUC ratio in mice following single or repeated oral administration of enavogliflozin) were made for three groups using the non-parametric Kruskal-Wallis test because of the small number of the sample size. SPSS for Windows software (version 25.0; IBM Corp., Armonk, NY, USA) was used and a difference was considered significant at p < 0.05.

Pharmacokinetics of Enavogliflozin in Mice
AUC ∞ and C o of enavogliflozin in ICR mouse plasma increased with increasing intravenous doses of 0.3, 1, and 3 mg/kg following intravenous injection ( Figure 2A, Table 2). The normality test using the Shapiro-Wilk method indicated that the pharmacokinetic parameters (i.e., Dose normalized AUC (AUC ∞ /D), and dose normalized initial concentration (C o /D), CL, V d,ss , T 1/2 , and MRT] showed normal distribution (Table S1). The Kruskal-Wallis test for these kinetic parameters recognized no significant differences in these pharmacokinetic parameters (Table 2). Thus, enavogliflozin displayed linear kinetics in an intravenous dose range of 0.3-3 mg/kg.   The plasma concentration-time profile of enavogliflozin in mice following oral administration of enavogliflozin is shown in Figure 2B and the respective pharmacokinetic parameters are summarized in Table 2. The pharmacokinetic parameters of orally administered enavogliflozin showed normal distribution using the Shapiro-Wilk test (Table S2) and the dose correlation among the pharmacokinetic parameters of the three dose groups were tested using the Kruskal-Wallis test. Dose normalized maximum plasma concentration (C max /D), AUC ∞ /D, and time to reach C max (T max ) obtained after administration of doses of 0.3, 1, and 3 mg/kg, showed no significant differences in the three different dosing groups ( Figure 2B and Table 2; p > 0.05 using Kruskal-Wallis test). Thus, enavogliflozin pharmacokinetic parameters obtained after its oral administration showed no significant differences in the oral dose range of 0.3-3 mg/kg. The oral bioavailability of enavogliflozin was 97.2%, 84.5%, and 93.7% for doses of 0.3, 1, and 3 mg/kg, respectively ( Table 2).

Pharmacokinetics of Enavogliflozin in Rats
Plasma concentration-time profiles of enavogliflozin in rats following intravenous injection of enavogliflozin were similar to the results found in mice ( Figure 3A and Table 3). No significant differences were observed for C o /D, AUC ∞ /D, CL, and V d,ss (Table 3; p > 0.05 using Kruskal-Wallis test), and normal distribution of these parameters was confirmed by the Shapiro-Wilk test (Table S3). Thus, enavogliflozin also showed linear kinetics in rats in the intravenous dose range of 0.3-3 mg/kg. This was evidenced by a doseproportional increase of AUC values of enavogliflozin in both rats and mice ( Figure 4A,B). The T 1/2 and MRT values obtained from 0.3, 1, and 3 mg/kg groups were significantly different. However, the plasma concentrations of enavogliflozin at 24 h following intravenous administrations of 0.3, 1, and 3 mg/kg groups were below the detection limit and resulted in incomplete elimination phase to estimate T 1/2 and MRT (Table 3).   Similarly, plasma concentration-time profiles of enavogliflozin in rats following oral administration of enavogliflozin were also similar to results from mice ( Figure 3B and Table 3). Normal distribution of these parameters was confirmed by the Shapiro-Wilk test (Table S4) but no significant differences in C max /D, AUC/D, and T max were observed (Table 3; p > 0.05 using Kruskal-Wallis test). Thus, enavogliflozin also showed linear kinetics in rats in an oral dose range of 0.3-3 mg/kg. Similarly, AUC values of enavogliflozin increased dose proportionally in both rats and mice ( Figure 4C,D). In addition, the oral bioavailability of enavogliflozin in rats at doses of 0.3, 1, and 3 mg/kg was 62.1%, 58.9%, and 56.3%, respectively (Table 3). These values were lower than values obtained from mice treated with the same doses.

Recovery of Enavogliflozin in Mice
Recovery of enavogliflozin was assessed from the urine and the feces samples collected over 72 h for mice and rats. The amount of enavogliflozin recovered in feces for 24 h and for 72 h after dosing was 36.3% and 39.3%, respectively ( Table 4). The amount of enavogliflozin recovered in urine for 24 h and for 72 h was 6.3% and 6.6%, respectively (Table 4). Thus, most enavogliflozin was eliminated from the body within 24 h. Recovery of enavogliflozin in feces was about 6-fold greater than in urine and enavogliflozin seemed to be excreted mainly via the biliary route in mice. However, total recovery of enavogliflozin was about 46%, suggesting that enavogliflozin was metabolized prior to elimination. After oral administration (1 mg/kg) of enavogliflozin in mice, most enavogliflozin was again recovered within 24 h and recovery from feces was much greater than from urine (Table 4), consistent with recovery after intravenous administration. However, recovery from feces after 72 h was 51.4%. Considering the BA of enavogliflozin in mice was 84.5%, unabsorbed fraction could have contributed to the increased fecal recovery.

Recovery of Enavogliflozin in Rats
Recovery of enavogliflozin in urine and feces was assessed in rats over 72 h. The amount recovered in feces and urine was 15.9% and 0.7%, respectively, after IV dose, and most enavogliflozin was recovered within 24 h ( Table 5). The recovery of enavogliflozin in feces was about 22.7-fold greater than in urine and enavogliflozin seemed to be excreted mainly via the biliary route, similar to the case of mice. However, total recovery of enavogliflozin was about 16.6%, suggesting greater metabolism before elimination in rats than in mice. These data demonstrated that elimination and extent of metabolism showed species differences. Most enavogliflozin was also recovered within 24 h after oral administration of enavogliflozin and recovery from feces was much greater than from urine (Table 5), consistent with recovery after intravenous administration. However, recovery from feces after 72 h was 45.5%. Again, this finding might be attributed to unabsorbed drug, considering the BA of enavogliflozin (58.9%).

Single Oral Administration of Enavogliflozin in Mice
Concentrations of enavogliflozin in ten tissues were assessed; the drug was not detected in brain tissue and enavogliflozin concentration and its elimination in nine tissues varied ( Figure 5). Elimination constants K and T 1/2 of enavogliflozin in various tissues are summarized in Table 6. The kidney showed a prolonged half-life and the highest enavogliflozin concentrations among the ten tissues in mice. Enavogliflozin in the stomach, small intestine, large intestine, liver was higher than in plasma and, consequently, showed a greater AUC ratio (higher than 5-fold) ( Table 6). Enavogliflozin concentrations in the heart and lung were similar to plasma concentrations and those in testis and spleen were lower than plasma ( Figure 5). The half-lives in the lung and testis were longer than in plasma but elimination half-lives in other tissues were similar to the half-life in plasma ( Table 6).  Tissue distribution (AUC ratios) of enavogliflozin in the kidney, stomach, small intestine, large intestine, liver, heart, and lung were higher than unity, whereas distribution in the brain, spleen, and testis was lower than unity ( Table 6). The order of AUC ratios was kidney > stomach, small intestine, large intestine > liver > lung, heart > testis, spleen > brain.

Tissue Distribution of Enavogliflozin following Repeated Oral Administration of Enavogliflozin in Mice
To investigate the effect of repeated doses of enavogliflozin on the pharmacokinetics and tissue distribution of enavogliflozin, this study measured the enavogliflozin concentrations in the plasma and major distributed tissues, such as the kidney, liver, small intestine, and large intestine for 48 h following single or repeated oral doses of enavogliflozin for 7 or 14 days ( Figure 6) and AUC values and AUC ratios are shown in Table 7. Normal distribution of AUC values and AUC ratios from different tissues and treatment groups were assessed by the Shapiro-Wilk test (Table S5). The plasma concentration-time profile of enavogliflozin in mice, following repeated oral administration of enavogliflozin (1 mg/kg) for one and two weeks, indicated that kinetics were not significantly different in terms of the Kruskal-Wallis test among three dosage regimes (p > 0.05) ( Table 7). Based on this statistical similarity, further post-hoc analysis was not performed. Enavogliflozin concentrations and AUC 48 h for the kidney, liver, small intestine, and large intestine were not significantly different, regardless of treatment period (single or repeated dose for 7 or 14 days) (Figure 6B-E; Table 7). Likewise, tissue distribution parameters calculated from AUC ratios, following single or repeated oral doses, were not significantly different (p > 0.05) ( Table 7).

Discussion
Previously, we investigated in vitro inhibition mechanisms of SGLT2 and in vivo pharmacokinetic properties of enavogliflozin in mice in a comparison with clinically used SGLT2 inhibitors, dapagliflozin and ipragliflozin. Enavogliflozin, dapagliflozin, and ipragliflozin showed high distribution and long elimination half-lives (t 1/2 ) in the kidney and enavogliflozin showed the highest kidney distribution among these three drugs [20]. These properties are thought to be important for efficacy and duration of action of SGLT2 inhibitors [22]. The substrate specificity of enavogliflozin for OAT1 and OAT3 could contribute to renal accumulation [20]. Further, IC 50 values of enavogliflozin to SGLT2 and SGLT1 are lower than for dapagliflozin and ipragliflozin, suggesting greater affinity to SGLT2 inhibition and, thus. selectively over SGLT1 [20].
In a study for investigating drug metabolism of enavogliflozin in hepatocytes from mouse, rat, dog, monkey, and human, it showed species-different metabolism [23]. Kim et al. identified five phase I metabolites from hepatocytes including, two monohydroxylated metabolites for which CYP3A4 and CYP2C19 were mainly involved, and three dihydroxylated metabolites. Five glucuronide metabolites of enavogliflozin were identified, and UGT1A4 and UGT2B7 were primarily involved in the formation of these glucuronide metabolites [23]. Major phase I metabolites-M1 (6-hydroxy envogliflozin), M3 (subsequent oxidation of M1), and M2 (hydroxylation at the cyclopropyl benzene moiety)-were all found in mouse, rat, dog, monkey, and human hepatocytes. CYP3A4 and CYP2C19 participated in the formation of M1, M2, and M3. UGT1A4, UGT1A9, and UGT2B7 participated in the formation of glucuronide conjugates (U1, U2). These latter metabolites were also found in the hepatocytes of all the species, but the intensity of the respective metabolites were different depending on the species [23]. In vitro hepatic clearance was calculated as 36.5 mL/min/kg for mouse, 8.3 mL/min/kg for rats, 17.9 mL/min/kg for dogs, 18.5 mL/min/kg for monkeys, and 4.5 mL/min/kg for human cells [23].
Species differences were also shown in the pharmacokinetics of enavogliflozin in mice and rats. Systemic clearance following intravenous injection of enavogliflosin (0.3-3 mg/kg) in rats was significantly greater than in mice-10.1 ± 1.59 mL/min/kg and 6.35 ± 1.14 mL/min/kg for mice and rats, respectively (p < 0.05) (Tables 2 and 3). However, recovery from the feces following intravenous injection (1 mg/kg) in rats was less than in mice (Tables 4 and 5). Metabolic activity in rats, thus, appears to be greater than that in mice. However, Kim et al. reported that hepatic metabolic clearance in rats was less than in mice [23]. Collectively, the hepatic and intestinal metabolism may both contribute to enavogliflozin metabolism but intestinal clearance may contribute mainly to systemic clearance, based on higher clearance in rats compared with mice. Oral BA in rats (56.3-62.1%) was also lower than that in mice (84.5-97.2%), which might be explained by favorable intestinal permeability or lower intestinal metabolism in mice.
Enavogliflozin showed higher biliary excretion compared with renal excretion in both rats and mice following intravenous injection; 39.3% and 15.9% of intravenous injection of enavogliflozin were recovered unchanged from feces samples in mice and rats, respectively (Tables 4 and 5). In the present study, fecal recovery of unchanged enavogliflozin after oral administration was 51.4% and 45.5% (Table 4). Considering the lower in vitro hepatic clearance in humans than in rats and mice [23], the recovery of enavogliflozin as a parent form following intravenous injection may be greater than that in rats and mice. Moreover, the intestinal first-pass effect of enavogliflozin in humans awaits further investigation to understand the pharmacokinetic and oral BA of enavogliflozin in humans. Conversely, more than 90% of drug-related radioactivity of dapagliflozin and its glucuronide metabolite were recovered in urine from rats and humans after single oral dose administration of [ 14 C]dapagliflozin. Thus, renal excretion is the primary route for dapagliflozin and its metabolites [15]. In contrast, cumulative fecal recovery of drug-related radioactivity was 86.9% ± 2.6% following a single oral administration of [ 14 C]ipragliflozin. Unchanged ipragliflozin accounted for less than 5% identified in feces and glucuronide metabolite for about 64% identified in feces [16]. Among the fecal recovery (about 85.4-93.7%) of [ 14 C]canagliflozin, unchanged canagliflozin, accounted for 3.5-38.7% and hydroxylated metabolites accounted for 7.6-64.3%, following a single oral administration of [ 14 C] canagliflozin [24].
The steady-state volume of distribution (V d,ss ) of enavogliflozin in mice (3.1-3.2 L/kg) was much higher than total body water (0.7 L/kg), suggesting high extravascular distribution. The drug was highly distributed to the kidney and intestinal tract, displaying a more than 10-fold AUC ratio compared with plasma. Liver distribution was 5.8-fold greater in comparison to plasma AUC (Table 6). Enavogliflozin was not highly distributed to other tissues, such as the heart, lung, brain, spleen, and testis (Table 6). These distribution characteristics were similar for dapagliflozin and ipragliflozin [20]. However, the elimination half-life of enavogliflozin in the kidney was much higher than for dapagliflozin and ipragliflozin [20]. Substrate specificity for renal transporters OAT1 and OAT3 and retained affinity to SGLT2 may contribute to high kidney distribution. The accumulation of enavogliflozin following the repeated oral dosing for 7 and 14 days showed no significant changes in AUC values of enavogliflozin in plasma, kidney, liver, small intestine, and large intestine compared to a single oral dose, suggesting that enavogliflozin can be administered without accumulating in the plasma and major organs within the effective dose range of enavogliflozin (0.1-2 mg in humans) [21].
Up to now, little information has been reported regarding the pharmacokinetics and tissue distribution of enavogliflozin. This study aimed to define its pharmacokinetic profiles in mice and rats following intravenous and oral administration, and to investigate the proportionality between doses and plasma exposures. Therefore, we employed noncompartmental analysis to calculate the main pharmacokinetic parameters. However, population PK analysis has been frequently used to guide drug development [25]. In this regards, the pharmacokinetics and kidney distribution results obtained in this study could be used to develop allometric scaling, and to understand the influence of pharmacokinetics on pharmacodynamics along with the in vitro SGLT2 inhibition results and in vivo pharmacological results.

Conclusions
This study reports on the linear pharmacokinetic features of enavogliflozin following intravenous and oral administration in a dose range of 0.3-3 mg/kg in both rats and mice. Enavogliflozin was highly accumulated in the kidney, being 41.9-fold higher in kidney AUC than plasma AUC. The drug also displays considerable distribution to the gastrointestinal tract (8.5-12.1-fold plasma AUC ratio) and the liver (5.8-fold plasma AUC ratio). Moreover, the drug shows no accumulation after repeated oral administration in mice. However, species differences in metabolism and oral BA between rats and mice should be recognized as drug development continues.
Supplementary Materials: The following supporting information can be downloaded at: https://www. mdpi.com/article/10.3390/pharmaceutics14061210/s1, Table S1. p values and Q-Q plot from the normality test for the pharmacokinetic parame-ters of enavogliflozin in mice following its intravenous administration using the Shapiro-Wilk test. Table S2. p values and Q-Q plot from the normality test for the pharmacokinetic parame-ters of enavogliflozin in mice following its oral administration using the Shapiro-Wilk test. Table S3. p values and Q-Q plot from the normality test for the pharmacokinetic parame-ters of enavogliflozin in rats following its intravenous administration using the Shapiro-Wilk test. Table S4. p values and Q-Q plot from the normality test for the pharmacokinetic parame-ters of enavogliflozin in rats following its oral administration using the Shapiro-Wilk test. Table S5. p values and Q-Q plot from the normality test for AUC values and AUC ratios of enavogliflozin in various tissues after single or repeated oral doses (1 mg/kg) of enavogli-flozin in mice using the Shapiro-Wilk test.