The Vanilloid Receptor TRPV1 Is Tonically Activated In Vivo and Involved in Body Temperature Regulation

TRPV1 antagonists representing multiple different chemotypes cause hyperthermia

In our efforts to identify a TRPV1 antagonist for clinical evaluation, we synthesized a variety of novel small molecule antagonists (Doherty et al., 2005; Xi et al., 2005; Ognyanov et al., 2006) (data not shown). To measure antagonism of TRPV1 in vivo, we and others tested the ability of antagonists to block capsaicin-induced eye wipe (Gavva et al., 2005b; Jakab et al., 2005), capsaicin-induced hypothermia (Bannon et al., 2004; Jakab et al., 2005; Swanson et al., 2005), and/or capsaicin-induced flinch behavior (Seabrook et al., 2002) in rats. We previously showed that AMG9810 is a potent antagonist of TRPV1 in vitro and blocks capsaicin-induced eye wipe in rats (Gavva et al., 2005b). Here, we evaluated whether AMG9810 can inhibit capsaicin-induced hypothermia in rats implanted with radiotelemetry probes to monitor body temperature (Fig. 1 a). AMG9810 not only inhibited capsaicin-induced hypothermia but also caused an ∼1°C increase in body temperature (hyperthermia) by itself within 30 min after administration (Fig. 1) (Bannon et al., 2004). Ten to 30 min after vehicle administration, the average temperature in the vehicle/vehicle group was 37.56 ± 0.11°C (n = 5), which as expected was comparable to the vehicle/capsaicin group (n = 6), because only the vehicle had been administered in both groups during this time period (Fig. 1 a). The average temperature in the AMG9810-treated group (AMG9810/capsaicin) was 38.37 ± 0.13°C (n = 6), which was significantly higher than the vehicle/vehicle group temperature (F _(2,14) = 14.92; p < 0.01). Forty to 100 min after additional vehicle or capsaicin administration, the average temperature of the vehicle/capsaicin group mean of 35.93 ± 0.17°C (n = 5) was significantly lower (hypothermia) than the vehicle/vehicle group mean of 37.20 ± 0.16°C (n = 5; t = 4.75; p < 0.001). AMG9810 inhibited capsaicin-induced hypothermia with a group mean temperature of 37.02 ± 0.21°C (AMG9810/capsaicin; n = 6), which was significantly higher than the vehicle/capsaicin group temperature (t = 4.27; p < 0.01). Additionally, we assessed the effect of AMG9810 alone on core body temperature over time (Fig. 1 b). The maximum average temperature of 38.93 ± 0.16°C (n = 6) observed 20 min after dosing was significantly higher than the vehicle group mean temperature of 38.01 ± 0.15°C (n = 5; t = 4.20; p < 0.01). The average temperature after AMG9810 administration was also significantly higher at 30 min (38.77 ± 0.18°C; n = 6) relative to the vehicle-treated group (37.86 ± 0.14°C; n = 5; t = 3.85; p < 0.01).

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Figure 1.

AMG9810 blocks capsaicin-induced hypothermia and causes hyperthermia by itself in rats. a , Body temperatures of rats recorded from implanted radiotelemetry probes. Rats were first administered with either vehicle or 30 mg/kg AMG9810 intraperitoneally and 30 min later were challenged with capsaicin (20 μg/20 μl). Note that the capsaicin-induced decrease in body temperature of rats at 60 min was greater in the vehicle/capsaicin group (red) compared with the AMG9810/capsaicin group (green) (t = 4.63; p < 0.001). AMG9810 caused a significant increase in rat body temperature at 20 and 30 min (F _(2,14) = 20.98; F _(2,14) = 26.60; p < 0.001). b , Body temperature of rats administered with either vehicle or 30 mg/kg AMG9810 intraperitoneally. A significant increase in body temperature was seen 20 and 30 min after AMG9810 administration (t = 4.20 and 3.85; p < 0.01). Error bars indicate SEM.

To investigate whether all TRPV1 antagonists cause hyperthermia, we evaluated the effect of various structurally distinct TRPV1 antagonists on body temperature in rats. First, we identified several compounds representing different chemotypes that block TRPV1 activation by capsaicin, protons, and heat (compounds A through H) (Table 1). To investigate the specific contributions of the antagonism of capsaicin, protons (pH 5.5 and 5), and heat activation of TRPV1 to hyperthermia, we subsequently examined antagonism data for several hundred compounds and found that (1) most compounds that blocked capsaicin activation also blocked heat activation and (2) a small group of compounds that block capsaicin and heat activation were ineffective against blocking proton activation (e.g., compounds I and J) (Table 1). Finally, we evaluated a large number of compounds (including compounds A through J; chemical structures are shown in supplemental Fig. 1, available at www.jneurosci.org as supplemental material) for their effect on body temperature in rats. Body temperature in rats increased by 0.5–1.5°C within 30–90 min after administration of all TRPV1 antagonists tested, but not after treatment with the vehicle (Table 1) (supplemental Fig. 2, available at www.jneurosci.org as supplemental material, and data not shown). These observations suggested that antagonist-induced hyperthermia is not chemotype specific but rather occurs because of TRPV1 antagonism. Furthermore, the data suggested that antagonism of capsaicin (and by inference proposed endogenous chemical ligands) and heat activation of TRPV1 is sufficient to cause hyperthermia.

Both brain-penetrant and peripherally restricted TRPV1 antagonists cause hyperthermia

To evaluate whether peripheral restriction of antagonists eliminates hyperthermia, we synthesized several compounds with decreased logP (octanol/water partition coefficient), increased polar surface area, and an increased number of hydrogen-bond donors to restrict their CNS penetration. Here, we evaluated in vitro and in vivo pharmacology, brain penetration, and pharmacokinetic properties of three molecules in detail. Tert-butyl-2-(6-{[2-(acetylamino)-1,3-benzothiazol-4-yl]oxy}pyrimidin-4-yl)-5-(trifluoromethyl)phenylcarbamate (AMG8163), N-[4-({[3-{6-[(2-amino-1,3-benzothiazol-4-yl)oxy]pyrimidin-4-yl)}-6-(trifluoromethyl)pyridin-2-yl]amino}methyl)-2-fluorophenyl]methanesulfonamide (AMG3731), and 3-amino-5-({2-[(2-methoxyethyl)amino]-6-[4-(trifluoromethyl)phenyl]pyrimidin-4-yl}oxy)quinoxalin-2(1H)-one (AMG1629) block capsaicin, proton, and heat activation of rat TRPV1 potently with IC₅₀ values <7 nm (Table 2). All three antagonists are >4000-fold selective relative to the closely related TRP channels (TRPV2, TRPV3, TRPV4, TRPA1, and TRPM8; data not shown). All three antagonists are orally bioavailable with pharmacokinetic properties that are amenable for in vivo studies (Table 2). Intraplantar injection of capsaicin induces paw flinching in rats, and TRPV1 antagonists block this behavior (Seabrook et al., 2002). We tested each one of the three antagonists delivered orally for their ability to block capsaicin-induced flinch in rats as a measure of TRPV1 antagonism in vivo. All three antagonists, AMG8163, AMG3731, and AMG1629, blocked 100% of capsaicin-induced flinch at doses of 3, 10, and 3 mg/kg, respectively (Table 2). Plasma and brain concentrations of these antagonists measured in rats used in the capsaicin-induced flinch study and in another study after intravenous administration to rats indicated that AMG8163 was brain penetrant (brain/plasma ratio, 0.18–0.5), whereas AMG3731 and AMG1629 were relatively peripherally restricted molecules (brain/plasma ratios: 0.02, −0.05, and ∼0.05, respectively) (Table 2 and data not shown).

Next, we evaluated the effect of all three TRPV1 antagonists on body temperature (Table 2, Fig. 2 a–c). AMG8163 caused hyperthermia of 1–1.5°C within 30–60 min after administration in rats (Fig. 2 a). The maximum body temperature in the AMG8163-administered group was 38.23 ± 0.24°C (n = 6), which occurred 50 min after dosing and was significantly higher than the maximum vehicle group temperature of 37.18 ± 0.18°C (n = 5; t = 3.43; p < 0.01). Similar to brain-penetrant AMG8163, both AMG3731 and AMG1629 caused hyperthermia of 0.5–1.2°C within 30–60 min after their administration (Fig. 2 b,c). The maximum temperature in the AMG3731-administered group was 38.49 ± 0.30°C (n = 6), which occurred 50 min after dosing and was significantly higher than the maximum temperature of the vehicle group, which was 37.18 ± 0.18°C (n = 5; t = 3.56; p < 0.01). The maximum temperature in the AMG1629 -administered group was 38.09 ± 0.11°C (n = 5), which occurred 20 min after dosing and was significantly higher than the maximum temperature of the vehicle group, which was 37.45 ± 0.10°C (n = 5; t = 4.19; p < 0.01). Brain and plasma concentrations of AMG3731 and AMG1629, determined from the same rats, confirmed their peripheral restriction (brain/plasma ratios were 0.03 and 0.05, respectively). In addition to AMG3731 and AMG1629, two other peripherally restricted antagonists, 3-amino-5-((2-(((1S)-1-(2-pyridinyl)ethyl)amino)-6-(4-(trifluoromethyl)phenyl)-4-pyrimidinyl)oxy)-2(1H)-quinoxalinone (AMG1394) and 3-amino-5-((6-(2-((2-(methyloxy)ethyl)amino)-6-(trifluoromethyl)-3-pyridinyl)-4-pyrimidinyl)oxy)-2(1H)-quinoxalinone (AMG2915) (both with a brain/pasma ratio of 0.04), also caused hyperthermia in rats (data not shown).

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Figure 2.

Both brain-penetrant (AMG8163) and peripherally restricted (AMG1629 and AMG3731) TRPV1 antagonists cause hyperthermia in rats. a–c , Body temperatures of rats administered with vehicle or 3 mg/kg AMG8163( a ), 3 mg/kg AMG1629 ( b ), and 10 mg/kg AMG3731 ( c ). All TRPV1 antagonists were given orally to rats, and body temperature was monitored for 120 min after administration. Compared with vehicle treatment, all four antagonists caused significant increase in body temperature (p < 0.01) at each time point or the average temperature from 0 to 120 min. d , Time course of body temperature in rats administered with vehicle or 0.1, 1, or 10 mg/kg AMG8163. During hours 2–11, ANOVA at each time point was significant (p < 0.01), and Dunnett's multiple comparison to vehicle was significant at each time point for 1 and 10 mg/kg doses (p < 0.01). During hours 16–21, ANOVA at each time point was nonsignificant (p > 0.05). Error bars indicate SEM.

TRPV1 antagonist-induced hyperthermia is transient in nature

To understand whether hyperthermia correlates with plasma concentrations of TRPV1 antagonists, we administered different oral doses of AMG8163 to rats implanted with radiotelemetry probes and monitored their temperatures for 24 h (Fig. 2 d). AMG8163-induced hyperthermia showed a steep dose dependence, with 0.1 mg/kg causing a 0.5°C increase in body temperature and both 1 and 10 mg/kg causing a maximal increase of 1–1.5°C in body temperature that reached a plateau at 38.5°C. ANOVA at each time point revealed the greatest F value (F _(3,18) = 23.73; p < 0.01) 5 h after dosing: vehicle, 36.99 ± 0.08°C; 0.1 mg/kg, 37.31 ± 0.08°C (p < 0.05); 1 mg/kg, 37.63 ± 0.08°C (p < 0.01); 10 mg/kg, 37.92 ± 0.08°C (p < 0.01). The concentration of AMG8163 in the plasma collected at the end of the experiment (24 h after dosing) was 1.6 ± 0.5, 15.8 ± 10.5, and 81.3 ± 52 ng/ml for the 0.1, 1, and 10 mg/kg doses, respectively. Plasma concentrations of AMG8163 measured in several other studies also indicate that as little as 33.8 ± 6.8 ng/ml was sufficient to trigger hyperthermia in rats [minimal effective concentration (MEC) of 33.8 ± 6.8 ng/ml]. In general, hyperthermia did not persist or correlate with plasma half-life or concentration of TRPV1 antagonists, indicating the “transient nature” of the hyperthermic effect. For example, the plasma concentration of AMG8163 at 24 h in rats treated with 10 mg/kg was 81.3 ± 52 ng/ml, which is approximately threefold higher than the MEC to induce hyperthermia. However, there was no significant difference in body temperature between vehicle- and AMG8163-administered rats at 12 h (F _(3,18) = 2.22; p > 0.05) or at 16 h and beyond (F _(3,18) = 0.28–2.27; p > 0.05). The transient nature of the TRPV1-induced hyperthermia suggests a physiological tolerance that develops from the involvement of thermoeffector mechanisms, which bring body temperature toward the normal range once TRPV1 antagonists induce hyperthermia.

JYL1421 does not cause transient hyperthermia in rats and potentiates pH 5 activation of rat TRPV1

Because JYL1421 (also known as SC0030) was suggested to be a peripherally restricted TRPV1 antagonist in rats (Suh et al., 2003; Wang et al., 2003), we evaluated the effects of JYL1421 on capsaicin-induced flinch behavior and body temperature in rats under the same conditions used for the AMG compounds. First, we evaluated JYL1421 in the capsaicin-induced flinch model at doses up to a maximum of 30 mg/kg (Fig. 3 a). JYL1421 showed 100% inhibition of capsaicin-induced flinch behavior in rats at 30 mg/kg (F _(5,42) = 4.4; p < 0.01; n = 8), indicating complete on-target coverage at the 30 mg/kg dose. Next, we evaluated the effects of JYL1421 (up to a maximum dose of 100 mg/kg) on body temperature in rats and found that it did not cause hyperthermia at any of the tested doses (Fig. 3 b). An ANOVA test 10 min after dosing showed a significant difference (F _(4,30) = 2.91), although all subsequent Dunnett's multiple comparisons to the vehicle-treated group were nonsignificant (p > 0.05). The highest temperature seen at any dose or time point was 37.51 ± 0.09°C (n = 7) in the 30 mg/kg dose group 30 min after dosing, which was neither significantly different from the highest temperature seen in the vehicle group of 37.35 ± 0.13°C (n = 7) 20 min after dosing (t = 1.04; p > 0.05) nor significantly different from the vehicle group temperature at the same 30 min time point (37.32 ± 0.10°C; n = 7; t = 1.44; p > 0.05). Brain and plasma concentrations determined in rats indicated that JYL1421 was peripherally restricted with a brain/plasma ratio ranging between 0.05 and 0.07. The plasma concentrations achieved at the 10 and 30 mg/kg doses, in both the capsaicin-induced flinch and telemetry experiments, were comparable.

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Figure 3.

JYL1421 blocks capsaicin-induced flinch behavior in rats but does not induce body temperature changes. a , JYL1421 blocks capsaicin-induced flinch in rats. Different doses (3–30 mg/kg) of JYL1421 were administered orally to rats 60 min before capsaicin challenge. The number (No.) of flinches in the first minute was counted and plotted against the dose of JYL1421. A 100% inhibition of capsaicin-induced flinch was observed at 30 mg/kg JYL1421 (F _(3,27) = 10.68; n = 8; p < 0.05 only for 30 mg/kg). Plasma concentrations of JYL1421 at 10 and 30 mg/kg were 2546 ± 600 and 14182 ± 3953 ng/ml, respectively. v/c, vehicle/capsaicin; D/R, dose response. b , Body temperature of vehicle (veh) or different doses (range, 3–100 mg/kg) of JYL1421-administered (orally) rats. No significant change in body temperature was observed at all doses tested (p > 0.05 for all Dunnett's multiple comparisons at each time point). Plasma concentrations of JYL1421 at 10, 30, and 100 mg/kg were 2725 ± 3329, 3876 ± 1448, 7867 ± 3570 ng/ml, respectively. c , Capsaicin (0.5 μm)-induced or heat (45°C)-induced ⁴⁵Ca²⁺ uptake into CHO cells stably expressing rat TRPV1 in the absence (100%) or presence of different concentrations of JYL1421. Note that JYL1421 fully blocks capsaicin (red) and partially blocks heat (blue) activation. d , Low pH (proton)-induced ⁴⁵Ca²⁺ uptake into CHO cells expressing rat TRPV1 in the absence (100%) or presence of different concentrations of JYL1421. JYL1421 shows partial inhibition of pH 5.5-induced ⁴⁵Ca²⁺ uptake at the highest concentration tested (4 μm). Note the potentiation of pH 5-induced ⁴⁵Ca²⁺ uptake above 100% by JYL1421 at concentrations >30 nm. max, Maximum. Error bars indicate SEM.

Among the three peripherally restricted TRPV1 antagonists studied here, AMG3731 and AMG1629 caused hyperthermia in rats, whereas JYL1421 did not. Hence, we evaluated the pharmacology of JYL1421 in agonist-induced ⁴⁵Ca²⁺ uptake assays under the same assay conditions used for testing of AMG3731 and AMG1629 (Fig. 3 c,d). JYL1421 acted as a full antagonist of capsaicin activation (IC₅₀ = 8 nm) and as a partial antagonist of heat activation (maximal inhibition of 60% at 4 μm) of rat TRPV1 (Fig. 3 c). In agreement with previous findings (Wang et al., 2003), JYL1421 partially blocked pH 5.5 activation in CHO cells expressing rat TRPV1 (Fig. 3 d). Surprisingly, JYL1421 potentiated pH 5 activation in a concentration-dependent manner, as measured by the pH 5-induced ⁴⁵Ca²⁺ uptake into CHO cells expressing rat TRPV1 (Fig. 3 d). Under the same assay conditions, AMG3731 and AMG1629 completely and potently blocked both pH 5 and pH 5.5 activation of rat TRPV1 (Table 2). We confirmed JYL1421 potentiation of pH 5 activation multiple times (n = 8), and the maximal potentiation ranged from 124 to 254% (average, 203 ± 41%) relative to pH 5 activation alone (Fig. 3 d and data not shown). JYL1421 by itself did not induce ⁴⁵Ca²⁺ uptake into CHO cells expressing the rat TRPV1 receptor at physiological pH (pH 7.2), indicating that it is not a partial agonist.

JYL1421 blocks dog and cynomolgus monkey TRPV1 activation and causes hyperthermia in both species

Because two peripherally restricted TRPV1 antagonists (AMG3731 and AMG1629) caused hyperthermia in rats, we hypothesized that potentiation of pH 5 activation of rat TRPV1 by JYL1421 was responsible for the lack of hyperthermia in rats. We predicted that if JYL1421 blocks capsaicin and heat activation but does not potentiate pH 5 activation of TRPV1 from any species, it would cause hyperthermia in that species. To test this hypothesis, we evaluated the effect of JYL1421 on dog and cynomolgus monkey TRPV1 activation and body temperature in both species. First, we cloned and characterized TRPV1 cDNA from a dog [genomic sequencing followed by reverse transcriptase (RT)-PCR] and monkey (RT-PCR followed by mutagenesis of 11 residues in human TRPV1 to those that are present in cynomolgus monkey). HEK293 cells transiently transfected with dog TRPV1 and CHO cells stably expressing monkey TRPV1 were activated by capsaicin with EC₅₀ values comparable to rat and human TRPV1 (EC₅₀ values were 112 ± 10, 94 ± 11, 69 ± 8, and 47 ± 7 nm for rat, dog, monkey, and human TRPV1, respectively). Similarly, protons and heat also activated both dog and monkey TRPV1 (Fig. 4 and data not shown). Next, we evaluated the ability of JYL1421 to block dog and monkey TRPV1 activation in agonist-induced ⁴⁵Ca²⁺ uptake assays. JYL1421 acted as a full antagonist of capsaicin activation (Fig. 4 a,b) and as a partial to full antagonist of heat (Fig. 4 a,b) and proton (Fig. 4 c,d) activation of both dog and monkey TRPV1. Importantly, JYL1421 did not potentiate pH 5 activation of either dog or monkey TRPV1 (Fig. 4 c,d).

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Figure 4.

JYL1421 blocks capsaicin, heat, and proton activation of dog and cynomolgus monkey TRPV1 and causes hyperthermia in both species. a , Capsaicin (0.5 μm)-induced or heat (45°C)-induced ⁴⁵Ca²⁺ uptake into HEK293 cells transiently expressing dog TRPV1 in the absence (100%) or presence of different concentrations of JYL1421. Note that JYL1421 fully blocks capsaicin (red) and partially blocks heat (blue) activation. b , Capsaicin (0.5 μm)-induced or heat (45°C)-induced ⁴⁵Ca²⁺ uptake into CHO cells stably expressing cynomolgus monkey TRPV1 in the absence (100%) or presence of different concentrations of JYL1421. Note that JYL1421 fully blocks capsaicin (red) and heat (blue) activation. c , Low pH (proton)-induced ⁴⁵Ca²⁺ uptake into HEK293 cells transiently expressing dog TRPV1 in the absence (100%) or presence of different concentrations of JYL1421. JYL1421 shows partial inhibition of pH 5.5-induced ⁴⁵Ca²⁺ uptake. d , Low pH (proton)-induced ⁴⁵Ca²⁺ uptake into CHO cells expressing cynomolgus monkey TRPV1 in the absence (100%) or presence of different concentrations of JYL1421. JYL1421 shows full block of pH 5.5 activation (green) and partially blocks pH 5 activation (brown). e , Time course of body temperature of dogs administered with either vehicle or 30 mg/kg JYL1421. JYL1421 caused a significant increase in body temperature compared with vehicle treatment from 1 to 5 h after administration (t = 3.01–8.94; p < 0.05). f , Time course of body temperature of cynomolgus monkeys administered with either vehicle or 100 mg/kg JYL1421. JYL1421 caused a significant increase in body temperature compared vehicle treatment from 1 to 17 h after administration (t = 2.98–8.66; p < 0.05). max, Maximum; Veh, vehicle. Error bars indicate SEM.

Because JYL1421 blocks capsaicin, heat, and proton activation of dog and monkey TRPV1, which is similar to the antagonism profile of other peripherally restricted TRPV1 antagonists studied here (AMG3731 and AMG1629), we predicted that it would cause hyperthermia in dogs and monkeys. To test that, JYL1421 was administered orally to both dogs (30 mg/kg) and monkeys (100 mg/kg) implanted with radiotelemetry probes, and their body temperatures were recorded for 24 h (Fig. 4 e,f).

In dogs, resting body temperatures of the JYL1421- and vehicle-treated groups at −1 and 0 h were not significantly different (JYL1421, 38.01 ± 0.22°C and 38.65 ± 0.14°C, n = 3; vehicle, 37.41 ± 0.38°C and 37.81 ± 0.27°C, n = 3; t = 1.38 and t = 2.77; p > 0.05). Beginning at the first time point (1 h) after dosing, body temperature in the JYL1421-administered group rose to 38.94 ± 0.22°C (n = 3), which was significantly greater than that in the vehicle group (37.03 ± 0.62°C; n = 3; t = 3.01; p < 0.05). The two groups remained significantly different from each other (t = 3.01–8.94; p < 0.05–0.001) until 6 h after administration, when the temperature of the JYL1421 group dropped to 38.54 ± 0.32°C (n = 3 and the temperature of the vehicle group was 37.72 ± 0.33°C (n = 3; t = 1.79; p > 0.05). At 7 and 8 h, the two groups were significantly different (all respectively, t = 7.23 and 3.25; n = 3; p < 0.05). At 9 and 10 h, the groups were not significantly different (t = 1.56 and 1.18; n = 3; p > 0.05). At 11 and 12 h, the groups were again significantly different (t = 11.21, n = 3, p < 0.001; and t = 5.50, n = 2, p < 0.05). From 13 to 20 h (t test could not be done at hour 14 because of both dogs in the JYL1421 group having temperatures of 37.70°C), the two groups were not significantly different (t = 0.37–1.72; n = 2–3; p > 0.05). Mean serum concentrations (n = 3) in the JYL1421-treated group were 5860, 4620, 1680, and 97.8 ng/ml at 2, 4, 8, and 24 h after administration, respectively.

In monkeys, resting body temperatures of the JYL1421 and vehicle groups were not significantly different (JYL1421: 38.26 ± 0.06°C, n = 3; vehicle: 38.05 ± 0.12°C, n = 3; t = 0.18; p > 0.05). During hours 1–17, the JYL1421-treated group had a significantly higher body temperature than the vehicle group (t = 2.98–8.66; n = 3; p < 0.05–0.01), with a maximum temperature of 39.40 ± 0.05°C (n = 3) at 3 h and 39.40 ± 0.03°C (n = 3) at 5 h, whereas the maximum mean temperature (n = 3) in the vehicle-treated group was 38.74 ± 0.08°C (at 9 h). During hours 18–24, mean body temperature in the JYL1421-treated group was significantly greater than in the vehicle-treated group (t = 3.95–6.78; n = 3; p < 0.05–0.01), except at 18 h (t = 1.93; n = 3; p < 0.05) and 22 h (t = 2.65; n = 3; p > 0.05). Mean serum concentrations (n = 3) in the JYL1421-treated group were 3761, 4236, 2570, and 712 ng/ml at 2, 4, 8, and 24 h after administration, respectively.

Notably, no JYL1421-related clinical observations or alterations in food consumption, body weight, motor activity, or cardiovascular parameters were observed in dogs or monkeys. In summary, JYL1421 caused transient hyperthermia in both dogs (increase of ∼1.8°C) and monkeys (increase of 0.5–1°C), confirming that blocking TRPV1 activation (and not potentiating pH 5 activation) results in hyperthermia.