key: cord-0020503-52tqwnd9 authors: Feng, Qiqi; Wang, Mengyang; Muhtar, Eldar; Wang, Yaonan; Zhu, Haimei title: Nanoparticles of a New Small-Molecule P-Selectin Inhibitor Attenuate Thrombosis, Inflammation, and Tumor Growth in Two Animal Models date: 2021-08-24 journal: Int J Nanomedicine DOI: 10.2147/ijn.s316863 sha: 8a4ca62a849d46b0f324b99f473c4d8d5988efaf doc_id: 20503 cord_uid: 52tqwnd9 PURPOSE: To assess whether the newly designed small-molecule oral P-selectin inhibitor 3S-1,2,3,4-tetrahydro-β-carboline-3-methyl aspartyl ester (THCMA) as a nanomedicine enhances antithrombosis, anti-inflammation, and antitumor activity more than the clinical trial drug PSI-697. METHODS: THCMA was designed as an amphiphile containing pharmacophores of PSI-697. Its nanofeatures were explored with TEM, SEM, Tyndall effect, ζ-potential, FT-ICR-MS, and NOESY 2D (1)H NMR. The P-selectin inhibitory effect of THCMA was demonstrated with molecular docking, ultraviolet (UV) spectra, and competitive ELISA. In vivo and in vitro assays — anti-arterial thrombosis, anti–venous thrombosis, anti-inflammation, antitumor growth, anti–platelet aggregation, rat-tail bleeding time, anticoagulation index, soluble P-selectin (sP-selectin) expression, and serum TNFα expression — were performed to explore bioactivity and potential mechanisms. Water solubility of THCMA was measured using UV-absorption spectra. RESULTS: THCMA self-assembled into nanorings of approximately 100 nm in diameter. Its water solubility was about 1,030-fold that of PSI-697. THCMA exhibited more potent P-selectin inhibitory effect than PSI-697. The oral efficacy of THCMA was 100-fold that of PSI-697 in inhibiting arterial and venous thrombosis and tenfold in inhibiting inflammation. THCMA inhibited thrombosis at a dose that produces no coagulation disorders and no bleeding risk. THCMA exhibited enhanced antitumor activity over PSI-697 without systemic chemotherapy toxicity. THCMA significantly inhibited platelet aggregation in vitro and downregulated the expression levels of serum sP-selectin and TNFα in vivo. CONCLUSION: A new small-molecule P-selectin inhibitor, THCMA, has been successfully designed as a nanomedicine with largely enhanced oral efficacy compared to the clinical trial drug PSI-697, and thus might be developed for the oral treatment of arterial thrombosis, venous thrombosis, inflammation, and cancer-associated thrombosis. P-selectin is an integral membrane protein expressed on activated platelet surfaces and endothelial cell surfaces. 1 Its overexpression occurs not only on the vascular endothelium of tumors but also on lung, ovarian, lymphoma, and breast cancer cells. 2 As an adhesion molecule, P-selectin binds with P-selectin glycoprotein ligand 1 (PSGL1), the cognate ligand expressed on leukocytes, T cells, and myeloid, lymphoid, carcinoma, and dendritic cells. 3, 4 This binding mediates the adhesion of platelets, leukocytes, T cells, endothelial cells, and tumor cells, resulting in inflammation, thrombosis and tumor growth and metastasis. It is evident that inhibiting the binding between P-selectin and PSGL1 sheds light on drug development for treating inflammation, 5 arterial thrombosis, 6 venous thrombosis, 7 tumor growth, 8 tumor metastasis, 8 and cancer-associated thrombosis. [9] [10] [11] Currently, drugs designed for this purpose mainly fall into three types: monoclonal antibodies, including inclacumab 12 and crizanlizumab, 13 glycosulfopeptides mimicking truncated N-terminal PSGL1 monomers like GSnP-6, 14 and small-molecule inhibitors, such as GMI-1070, 15 bimosiamose (TBC1269), 16 and PSI-697. 17 Those drugs, however, are far from satisfying for clinical use. The first two types are considered inadequate to fulfill daily or long-term therapeutic needs. For example, crizanlizumab, the first FDA-approved P-selectin inhibitor for sickle-cell treatment, 18 has the limitations of high manufacturing costs, short shelf life, and intravenous administration. Similarly, GSnP-6 also needs administration through the jugular cannula. 14 The complicated synthesis of GSnP-6 involves multiple chemical and enzymatic steps, making it hard to be manufactured. As for the third type, most of the small-molecule P-selectin inhibitors designed as sialyl Lewis X (sLeX) mimetics have been shown to be therapeutically ineffective because of their low binding affinity to P-selectin. For instance, the potency of P-selectin for the glycomimetic P-selectin inhibitors GMI-1070 and TBC1269 is K d 200 µM and IC 50 70 µM, respectively. 19 GMI-1070 and TBC1269 are also administered by intravenous injection or by inhalation. In contrast, PSI-697 is the only orally effective P-selectin inhibitor in clinical trials. Although it is also limited by its low potency for P-selectin (Kd 200 µM), it is not a sLeX-mimicking small molecule and is able to reduce inflammation and thrombosis in animal models. 20, 21 One negative result for PSI-697 as an antithrombotic drug is that it did not prevent platelet-monocyte aggregation in a phase I trial in healthy smokers, possibly because of the low tested dose and water solubility. 17 The low blocking activity and poor solubility of PSI-697 might be causes of high dose requirements. Nevertheless, PSI-697 is still a significant start for further exploration of oral P-selectin inhibitors. Detailed analyses of the interactions between P-selectin and PSGL1 have revealed that high-affinity binding between P-selectin and PSGL1 attributes to the three sulfated tyrosines Tys46, Tys48, and Tys51 and sLeX oligosaccharide at threonine 57 ( Figure 1A) . 14, [22] [23] [24] Tys48 has been suggested to make a larger contribution to the binding than Tys46 and Tys51. 14 Therefore, the binding site of Tys48 to P-selectin could be a potential drug-design site. We aimed to design a molecule with a binding mode similar to PSI-697 to P-selectin, but with enhanced solubility and activity. To begin with, we docked PSI-697 and its derivative PSI-421 25 to the crystal structure of P-selectin (PDB code 1G1S), finding that they both blocked the interaction of Tys48 of PSGL1 with P-selectin ( Figure 1B) . Moreover, what we have previously tested showed that 1,2,3,4-tetrahydro-β-carboline (THC) derivatives interacted with P-selectin at the Tys48 binding site and downregulated the expression of sPselectin. [26] [27] [28] [29] Therefore, we took THC as a template and designed 3S-THC-3-methyl aspartyl ester (THCMA) as a new small-molecule oral P-selectin inhibitor. THCMA contains two important pharmacophores of PSI-697 that are connected with a linker to produce an amphiphilic molecule. THCMA significantly improved the logP (−2.21) and logS (1.11) values versus the logP (5.88) and logS (−4.74) values of PSI-697, indicating significantly improved solubility and pharmacokinetic properties ( Figure 1C ). For the docking results ( Figure 1D ), the binding site of the carboline moiety of THCMA matched with the modified quinoline moiety of PSI-697 well. Similarly to the functional carboxylate group of PSI-697, the carboxylate group of THCMA interacted with Lys112 of P-selectin. The docked binding free energy of THCMA (−7.45 kcal/mol) was lower than PSI-697 (−7.30 kcal/ mol). We hence hypothesized that THCMA as a new small-molecule oral P-selectin inhibitor would effectively inhibit P-selectin-mediated events, particularly those observed in thrombosis, inflammation, and tumor growth. The conformation of THCMA was energy-minimized with Discovery Studio 2017 following methods in the literature. 32 The THCMA conformation with the lowest energy was docked to the active site of P-selectin and adopted for the construction of self-assembled nanoparticles. To investigate the binding modes of THCMA, PSI-697, and PSI-421 with P-selectin, molecular docking studies Feng et al were carried following methods in the literature. 32 The protein (chain A of PDB 1G1S) was used as the rigid receptor. The size of the grid box was 80×80×80 Å, covering the interaction surface of the ligand in the crystal structure 1G1S. Energy-minimized THCMA, PSI-697, and PSI-421 were treated as flexible ligands. Synthesis of 3S-THC-3-Carboxylic Acid (1) Positive electrospray ionization (ESI) was used to record the FT-ICR-MS spectrum of THCMA. The qCID spectrum of 1,269.56151 m/z was isolated for further analysis. Spectral data were analyzed with the instrument's software. The NOESY 2D 1 H NMR spectrum of THCMA was measured following the instructions for an 800 MHz Bruker spectrometer. The morphology and size of nanoparticles in 0.1 μM THCMA water solution at pH 7 and lyophilized powder were observed as per the literature. 33 Particle Size and ζ-Potential Competitive Binding Assay of THCMA with P-Selectin Against PSGL1 on HL60 The competitive binding assay was modified from a method described in the literature. 34 Rat antimouse IgG antibody (20 ng/mL, 50 μL) was coated onto microtiter plates overnight at 4°C. The plates were washed and blocked for 8 hours at 4° C with 3% BSA. To each well, 50 μL human recombinant P-selectin-IgG chimera protein (200 ng/mL, R&D Systems) was added. The plates were carefully washed three times, and to each well HL60 cells (1,000 cells/well, 100 μL) with NS, PSI-697 (25 μM), and THCMA (25 and 100 μM) were added and allowed to adhere in the presence or absence of compounds for 30 minutes at 37°C. PSI-697 was used as positive control. The plates were placed upside down on centrifuge (1,000 rpm, 3 minutes) to remove nonadherent cells. Adherent cells were quantified by counting the cell numbers under microscopy. The activity of the inhibitors is presented as adherent percentage: (adherent cell numbers in experimental group -aspecific adherent cell numbers) ÷ (adherent cell numbers in blank group -aspecific adherent cell numbers) ×100%. Each experiment had six replicates and was statistically analyzed using a t-test. Antiplatelet Activity of THCMA Observed on AFM Interactions between THCMA and platelets and the effect of THCMA on the aggregation of platelets were observed with AFM of platelets in the presence and absence of THCMA. The images were captured as per the literature. 32 The morphology of platelets at resting state, AA activated state in NS, and AA activated state in the presence of various concentrations of THCMA (final concentrations 10 −5 , 10 −6 , and 10 −7 M) were observed. To determine the inhibitory effect of THCMA and PSI-697 on the aggregation of platelets, an in vitro plateletaggregation assay was performed as per the literature. 31 To evaluate the in vivo anti-arterial thrombosis activity of THCMA, a rat arteriovenous shunt silk-thread model described in the literature was used. 31 CMCNa (0.5%, 3 mL/kg) was given orally to the negative-control group. Aspirin 167 µmol/kg was given orally to the positivecontrol group. PSI-697 5 µmol/kg was given orally to the positive-control group of the P-selectin inhibitor. The three test groups were given 5, 0.5, and 0.05 µmol/kg THCMA orally. To evaluate the in vivo anti-venous thrombosis activity of THCMA, a rat inferior vena cava (IVC) ligation model from the literature was adopted. 35 The negative-control group was given 3 mL/kg 0.5% CMCNa orally. The positive-control group was given 4.87 µmol/kg warfarin orally. The P-selectin inhibitor positive-control group was given 5 µmol/kg of PSI-697 orally. THCMA 5, 0.5, and 0.05 µmol/kg were given orally to the three test groups. To evaluate the in vivo anti-inflammation activity of THCMA, a xylene-induced ear-edema mouse model was used as per the literature. 36 For the negative-control group, a single dose of 10 mL/kg 0.5% CMCNa was given. For the positive-control group, a single dose of 1,110 μmol/kg aspirin was given. For the three test groups, a single dose of 5, 0.5, and 0.05 µmol/kg THCMA was given. Antitumor P-selectin is involved in both tumor growth and metastasis. 8, 37 To evaluate the in vivo antitumor activity of THCMA, a nonmetastatic S180 mouse model was adopted as per the literature. 32 Mice in the assay were given drugs orally for 10 consecutive days and then killed with diethyl ether anesthesia. CMCNa 0.5% was given orally to the mice in the negative-control group. Doxorubicin (Dox) 5 μmol/kg/day was adminstered intraperitoneally to the mice in positive control group, 5 μmol/kg/day PSI-697 was given orally to those in the P-selectin inhibitor positive-control group, and 5 μmol/kg/day THCMA was given orally to the mice in the test group. The body weights of all mice were recorded every day. After death, 1 mL fresh blood was collected for each mouse and tumors and organs dissected and weighed immediately. This assay was performed using a method mentioned in the literature. 38 In our assay, the rats in the negativecontrol group were given 3 mL/kg 0.5% CMCNa orally, those in the positive-control group 4.87 µmol/kg warfarin orally, the P-selectin inhibitor positive-control group 5 µmol/kg of PSI-697 orally, and the test group 5 µmol/kg of THCMA orally. Activated partial thromboplastin time (APTT), thrombin time (TT), prothrombin time (PT), and plasma fibrinogen (Fib) were measured in sera of the IVC-ligation rats used in the anti-venous thrombosis assay according to procedures in the literature. 30 Sera from the anti-inflammation, anti-arterial thrombosis, anti-venous thrombosis, and antitumor assays were collected according to the manufacturer's instructions of rat and mouse ELISA kits. To measure expression levels of P-selectin and TNFα in the serum, the ELISA kits were used as per the literature. 32 Solubility Maximum solubility of THCMA and PSI-697 in water was measured and calculated using standard curves with a Shimadzu UV-2600. Maximum-absorption wavelengths of THCMA and PSI-697 were 362.4 nm and 196.3 nm, respectively. Absorbance of a series of THCMA solutions (1, 577, 789, 394, 197 , and 99 µM) and PSI-697 solutions (54, 18, 6, 2, and 1 µM) were measured. Regression equations were plotted in terms of concentration to absorbance. Saturated THCMA and PSI-697 solutions were prepared and UV absorbance measured to calculate maximum solubility. The poor solubility of PSI-697 might be a cause of the need for high dosage. THCMA was structurally designed as an amphiphilic molecule to improve solubility. The maximum solubility of THCMA and PSI-697 in water was 5,040 µM and 4.89 µM, respectively, THCMA is about 1,030-fold that of PSI-697, which is good for the development of an oral drug. The direct binding interactions of THCMA and PSI-697 with P-selectin were demonstrated with UV spectra in vitro. Figure 2A and C show that P-selectin exhibited absorbance at 280nm, while PSI-697 and THCMA exhibited little absorbance at 280 nm. Figure 2B and D show that both PSI-697 and THCMA concentration-dependently reduced the UV-absorption intensity of P-selectin at 280 nm. THCMA and PSI-697 mixed at both 1:1 ( Figure 2E Figure 2F ) concentration-dependently caused hypochromic effects in P-selectin at 280 nm. These results imply that THCMA binds to P-selectin in a similar way to PSI-697. Protein UV absorbance comes mainly from the aromatic residues tryptophan and tyrosine. 39 The binding site of PSI-697 and THCMA on P-selectin is surrounded by multiple tyrosine residues: Tyr5, Tyr10, Tyr18, Tyr44, Tyr45, Tyr48, Tyr49, and Tyr94 ( Figure 2G ). The hypochromic effect of P-selectin on UV absorbance could have been the influence of the binding of PSI-697 or THCMA. Competitive Binding of THCMA with P-Selectin Against PSGL1 on HL60 The competitive binding ability of THCMA with P-selectin against the natural ligand -PSGL1 expressed on HL60 cells -was tested with ELISA. Representative images of adhered HL60 cells in plates observed under microscopy are shown in Figure 2J -M. Based on spherical cells with smooth edges, the number of adhered HL60 cells in (Figure 2J-M) was 165, 63, 54, and 43, respectively. Figure 2H shows that HL60 cell numbers adhered to the fixed P-selectin on ELISA plates were significantly reduced in the presence of THCMA or PSI-697. The inhibition rates of THCMA and PSI-697 at 25 μM were 67.04% and 59.69%. The inhibition rate of THCMA at 100 μM was significantly increased to 73.41%. The inhibition rate of PSI-697 at 100 μM was not recorded, because of its limited solubility. Analysis of these results shows that the inhibitory effect of THCMA on P-selectin was comparable to PSI-697 at 25 μM, while the inhibitory effect of THCMA on P-selectin was significantly increased at 100 μM. Self-assembly of amphiphiles into nanostructures is driven by various physical interactions, such as hydrophobic effects, intermolecular π-π interactions, electrostatic interactions, van der Waals interactions, and hydrogen bonds. 40, 41 We analyzed the probable self-assembly process of the amphiphilic organic molecule THCMA. FT-ICR MS spectra are useful in exploring the intermolecular association of small molecules. To explore selfassembly, a solution of THCMA in methanol (1 nM) was tested with FT-ICR MS. The relationship between polymers was explored using a qCID spectrum. Figure 3A shows THCMA molecules exhibited as monomers (318.14566), dimers (635.28299 minus H), trimers (952.42258 minus H), and tetramers (1269.56151 minus H). The qCID spectrum of the tetramers (1,269.56151 minus H) showed the trimer, dimer, and monomer peaks. These results show that THCMA monomer can aggregate into dimers, trimers, and tetramers in water. To characterize the molecular assembly pattern of THCMA, the NOESY 2D 1 H NMR spectrum was analyzed, and three interesting cross-peaks are marked with red circles in Figure 3B . These cross-peaks reflect the intermolecular interactions of 3-H and 6-H, 4-H and 6-H, and 10-H and 6-H, and mean that interaction distances between these hydrogens were <5 Å. Based on the interaction information, four energyminimized monomers of THCMA were constructed into a tetramer fulfilling these interaction requirements. The THCMA tetramer presented a ring-shaped conformation of about 2.1 nm in diameter. The top view and side view of the tetramer are shown in Figure 3C . To visualize the nanofeatures of THCMA, TEM and SEM images were captured on 0.1 μM of THCMA solution water solution at pH 7 and its lyophilized powder. TEM showed that THCMA formed tiny nanoparticles of approximately 2-3 nm in diameter, which in turn assembled into pearl necklace-like nanorings in of around 100 nm diameters ( Figure 4A ). Analysis of 400 nanoparticles in the TEM image showed nanoparticle-size distribution of 94.83 ±22.76 nm ( Figure 4B ). The diameter of the tiny nanoparticles in TEM image (2-3 nm) was approximately the diameter of the bilayer formed by two THCMA tetramers. SEM showed that THCMA forms hollow nanorings in diameters of around 100 nm ( Figure 4C ). Analysis of 400 nanoparticles in the SEM image shows a nanoparticle size distribution of in 99.53±23.69nm ( Figure 4D) . A probable self-assembly process is proposed in Figure 4E . The amphiphilic organic molecule THCMA self-assembled as a bilayer nanoring with the lipophilic parts exposed to the aqueous environment ( Figure 4E ). The formation of the THCMA nanostructure is good for drug-delivery efficiency. International Journal of Nanomedicine 2021:16 5784 particle size over 7 days, and ζ-potentials. It can be seen in Figure 5A and F that ultrapure water of various pH exposed to 650 nm laser did not exhibit a Tyndall effect. Figure 5B -E, and 5G-J indicate that the Faraday-Tyndall effect occurred at various concentrations of THCMA solutions (10, 1, 0.1, and 0.01 μM) at both pH 7 and 2. These results imply that THCMA exhibits as nanoparticles at pH 7 and pH 2 (gastric fluid). The ζ-potentials of 10, 1, 0.1 and 0.01 μM THCMA solutions at pH 7 were −11.9mV, −19.1mV, −17.6mV, and Figure 5K-N) . The ζ-potential of pH 7 THCMA water solution at 10 μM was lower than those at 1 μM, 0.1 μM, and 0.01 μM. A possible reason is that higher concentrations of THCMA water solution had more tendency to aggregate and coagulate. Nanoparticle sizes in pH 7 THCMA solutions (10, 1, 0.1, Figure 5O ), while pH 2 THCMA solutions (10, 1, 0.1 and 0.01 μM) also fluctuated (350-650nm over 7 days, Figure 5P ). These results indicate that THCMA solutions maintained more stable nanoparticles in pH 7 than pH 2. Anti-Arterial Thrombosis Activity of THCMA In Vivo THCMA was given orally to rats in the arteriovenous shuntsilk-thread model to evaluate its anti-arterial thrombosis activity. It can be seen in Figure 6A that 5 μmol/kg P-selectin inhibitor PSI-697 effectively inhibited the formation of arterial thrombus in rats. However, THCMA exhibited better oral efficacy than PSI-697 at 100-fold lower dosage. The oral efficacy of THCMA dosedependently increased. The anti-arterial thrombosis activity of 0.05 μmol/kg THCMA shows no significant difference with 167 μmol/kg aspirin (positive control). These results suggested >100-fold improved oral efficacy of THCMA over PSI-697 in inhibiting the formation of arterial thrombus. THCMA was given orally to rats in the IVC-ligation model to evaluate its anti-venous thrombosis activity. It can be seen in Figure 6B that 5 μmol/kg PSI-697 and 0.05 μmol/kg THCMA decreased the venous thrombus weight of rats to a similar level. Oral treatment of 0.5 μmol/kg THCMA showed no significant difference to oral treatment of 4.87 μmol/kg warfarin (positive control) on venous thrombus weight. Moreover, the oral anti-venous thrombosis activity of THCMA was significantly improved with increased dosage. These results suggest that the oral efficacy of THCMA is tenfold that of warfarin and 100-fold that of PSI-697 in inhibiting the formation of venous thrombus. The bleeding risk of THCMA was evaluated by the bleeding time of rat tails. Figure 6C shows that oral treatment of 4.87 μmol/kg warfarin in venous thrombosis assays caused prolonged tail bleeding compared to oral treatment of 3 mL/kg CMCNa in the negative-control group rats, which indicates the bleeding risk of warfarin. On the contrary, oral treatment of 5 μmol/kg THCMA or PSI-697 did not increase bleeding time, which excludes their bleeding risk. To test the influence of THCMA on coagulation function sera of rats from venousthrombosis assays were tested for PT, TT, APTT, and Fib. Figure 6D shows that these values after oral treatment of 5 μmol/kg THCMA or PSI-697 were not significantly different from the negative-control group. However, the rats exhibited unusual APTT values after oral treatment of 5 μmol/kg warfarin. These results suggest that coagulation function was not influenced by oral treatment of 5 μmol/kg THCMA and PSI-697. THCMA was given orally to mice in a xylene-induced earedema model to evaluate its anti-inflammation activity. In the assay, CMCNa was used as blank control and aspirin as positive control. To examine the relationship between anti-inflammation activity and P-selectin inhibition, the anti-inflammation activity of PSI-697 was tested. Figure 7A shows that the inhibition level of THCMA on ear-edema of mice was significantly enhanced with increased dosage. Oral treatment of 0.5 μmol/kg THCMA, 5 μmol/kg PSI-697, and 1,110 μmol/kg aspirin exhibit similar inhibition levels. Oral treatment of 5 μmol/ kg THCMA presented significantly higher antiinflammation activity than 5 μmol/kg PSI-697. THCMA showed tenfold-enhanced anti-inflammation activity compared to PSI-697, and anti-inflammation activity was related to the P-selectin inhibition of THCMA. THCMA was given orally to S180-bearing mice to evaluate its in vivo antitumor activity. Figure 7B shows that tumor weight after oral treatment of 5 μmol/kg/day THCMA was significantly less than with 5 μmol/kg/day PSI-697. There was no significant difference in tumor weight between 5 μmol/kg/day THCMA and 2 μmol/kg/day Dox. These results imply that oral treatment with THCMA and PSI-697 exhibit potential in slowing tumor growth, and THCMA exhibits similar antitumor activity to Dox and better antitumor activity than PSI-697. To evaluate the systemic toxicity of THCMA, body weight and organ:body-weight ratio of S180-bearing https://doi.org/10.2147/IJN.S316863 International Journal of Nanomedicine 2021:16 5788 mice were calculated to evaluate body and organ atrophy. Figure 7C shows that the body weight of mice treated with THCMA was similar to that of CMCNa, while the body weight of mice treated with Dox was significantly less than that of CMCNa. Figure 7D shows that the liver:body-weight ratio and spleen:bodyweight ratio of mice treated with THCMA were similar to that of CMCNa, but significantly higher than that of Dox. These results mean that THCMA does not exhibit systemic toxicity, while Dox does. sP-selectin is the extra membrane domain of P-selectin shed from the plasma membrane. The expression level of sPselectin is considered a biomarker of inflammation, platelet activation, and vascular and thrombotic diseases. [42] [43] [44] To reveal the correlation of THCMA's P-selectin inhibition activity with its antithrombosis, anti-inflammation, and antitumor activity, in vivo expression levels of sP-selectin and TNFα were examined. Figure 8A -D show that expression Feng et al levels of sP-selectin in arterial thrombosis rats, venous thrombosis rats, S180 mice, and ear-edema mice had similar patterns. sP-selectin expression in animals treated with THCMA or PSI-697 were significantly lower than in animals treated with negative or positive control. Expression of sP-selectin was downregulated to a similar extent after treatment with THCMA or PSI-697 in venous thrombosis rats, S180 mice, and ear-edema mice. These results indicated that in vivo antithrombosis, antitumor, and anti-inflammation activity of THCMA and PSI-697 were directly related to their P-selectin inhibition activity. It is worth noting that expression of sP-selectin in arterial thrombosis rats in the THCMA group was significantly lower than the PSI-697 group, which implies that the anti-arterial thrombosis activity was more sensitive to P-selectin inhibition. THCMA exhibited stronger downregulation of sP- selectin than PSI-697. This means that THCMA has more potential in inhibiting arterial thrombosis, which is in accordance to the in vivo data. TNFα levels were significantly decreased in ear-edema mice treated with aspirin and P-selectin inhibitors THCMA and PSI-697, and significantly lower in mice treated with 5 µmol/kg P-selectin inhibitors than mice treated with 1110 µmol/kg aspirin ( Figure 8E ). These results imply that inhibition of P-selectin may also indirectly inhibit inflammation by downregulating the expression of TNFα in mice, which is closely related to inflammation. To further study the mechanism of THCMA inhibiting arterial thrombosis and tumor growth, 2 the antiplatelet activity of THCMA was evaluated in two ways: AFM of platelets in the presence and absence of THCMA and in vitro plateletaggregation assay. Figure 9A shows resting rat platelets on AFM. It can be seen that most platelets were scattered and unaggregated. The curve at the top represents height changes across the surface of the single platelet marked by the red square. The curve is smooth, indicating that the platelet surface is smooth. Figure 9B shows rat platelets activated by AA on AFM. It can be seen that most platelets were aggregated and the surface of the activated platelet was still smooth. Figure 9C -E shows AFM of rat platelets activated by AA in the presence of 10, 1, and 0.1 μM THCMA, respectively. Aggregation of rat platelets was dosedependently inhibited in the presence of THCMA. The height curves at the top of Figure 9C -E show differences of 120.92, 110.97, and 91.98 nm, respectively. These results imply the adhesion of THCMA nanoparticles on the surface of platelets. The anti-platelet aggregation activity of THCMA and PSI-697 were assessed by inhibition rates of platelet aggregation in the presence of THCMA and PSI-697. Figure 9F shows that inhibition was 51.43%, 85.28%, and 91.05% in the presence of 0.5, 5, and 50 μM of THCMA, respectively, and 7.65%, 31.93%, and 60.26% in the presence of 0.5, 5, and 50 μM PSI-697, respectively. These results indicate that THCMA can effectively inhibit platelet aggregation and significantly enhance anti-platelet aggregation activity compared to PSI-697. Several studies have shown that PSI-697 exhibits oral activity for the treatment of atherosclerosis, restenosis and venous thrombosis in animals, 20, 21, [45] [46] [47] while its activity and solubility need improvement. In the present work, we designed a new small-molecule THCMA as a P-selectin inhibitor. THCMA contains two pharmacophores of PSI-697 connected by a linker ( Figure 1C ). Two pharmacophores were designed for oral activity as a P-selectin inhibitor, and connected with a linker to form an amphiphilic molecule for improved solubility as an oral drug and improved drug delivery through self-assembly into nanomedicine. The solubility test showed that the maximum water solubility of THCMA was 1,030-fold that of PSI-697, which is good for the development of an oral drug active in vessels. In silico molecular docking studies suggested that the two pharmacophores of THCMA bound at the Tys48 binding site and interacted with P-selectin in a similar way to PSI-697 ( Figure 1D ). In vitro UV spectra (Figure 2A -D) also showed that THCMA and PSI-697 directly interacted with P-selectin in a similar way, which verifies the rationality of the drug design of THCMA. In vitro competitive binding assays show that THCMA competitively inhibited the binding of P-selectin with ligand PSGL1 ( Figure 2H ). The in vitro inhibitory effect of THCMA on P-selectin 5792 was comparable to PSI-697 at 25 μM, which is in accordance with the results of molecular docking and UV spectra. However, because of its improved solubility, THCMA achieved significantly higher inhibition at 100 μM. In vivo downregulation of sP-selectin levels in arterial thrombosis rats, venous thrombosis rats, S180 mice, and ear-edema mice also support the P-selectin inhibitory effect of THCMA ( Figure 8A-D) . Results from these three experiments confirmed that our aim of designing THCMA as a new small-molecule P-selectin inhibitor had been achieved. Small molecule nanomedicines are directly assembled from pharmaceutical molecules with or without minimum excipients, which can largely improve drug-delivery efficiency and biosafety. 48 TEM and SEM of THCMA ( Figure 4) show that THCMA self-assembled into nanorings about 100 nm in diameter. The Tyndall effect, ζ-potential, and particle-size tests ( Figure 5 ) also confirmed that THCMA functioned as a stable small-molecule nanomedicine at various concentrations in both a neutral environment (pH 7) and an acidic environment like gastric fluid (pH 2). The mechanism of the self-assembly of nanorings was proposed according to the results of FT-ICR-MS, NOESY 2D 1 H NMR ( Figure 3 ) and the morphology of THCMA on TEM and SEM. Amphiphilic organic molecules THCMA self-assembled into a bilayer nanoring with the lipophilic parts exposed to an aqueous environment ( Figure 4E ). The formation of THCMA nanomedicine could help to improve its drug-delivery efficiency. These results indicate that our aim of designing THCMA as an amphiphile to form nanomedicine had been achieved. THCMA Effectively Inhibits Thrombosis, Inflammation, and Tumor Growth P-selectin is considered a promising therapeutic target for antithrombosis and anti-inflammation drugs. The blockade of P-selectin has also been proved to inhibit tumor growth and metastasis in mice. 8 Compared to the oral P-selectin inhibitor PSI-697, the new small-molecule P-selectin inhibitor THCMA exhibited significantly improved anti-arterial thrombus, anti-venous thrombus, anti-inflammation, and antitumor activity. Its oral anti-arterial and anti-venous thrombus activity was >100-fold that of PSI-697 ( Figure 6A and B) , oral anti-inflammation activity greater than tenfold that of PSI-697 ( Figure 7A ), and oral antitumor activity significantly better than PSI-697 ( Figure 7B ). THCMA possesses similar pharmacophores to PSI-697. The improvement in activity could be related to its good solubility. The self-assembly of THCMA into nanomedicine may also have contributed to the largely enhanced in vivo activity by improving drug-delivery efficiency. In vivo results demonstrated that THCMA was highly potent in inhibiting venous thrombosis. Inhibition of venous thrombosis occurred at a dose that produced no significant changes in TT, PT, APTT or Fib and no prolonged tailbleeding time ( Figure 6C and D) . Bleeding and coagulation disorders are the major risks of warfarin. These results suggest that THCMA has the potential to be developed as an alternative to warfarin as an anti-venous thrombosis agent. THCMA nanoparticles were found on platelet surfaces with AFM ( Figure 9C -E). THCMA exhibited significantly enhanced anti-arterial thrombosis activity and anti-platelet aggregation activity over PSI-697 ( Figure 6A and F). The mechanism of THCMA's anti-arterial thrombosis activity could be related to its antiplatelet activity. THCMA exhibited slightly more enhancement of antiinflammation and antitumor activity than PSI-697. The mechanism of the anti-inflammation activity of THCMA could be related to the downregulation of the inflammatory mediator TNFα in animal models ( Figure 8E ). The antitumor activity of THCMA was comparable to Dox. Moreover, THCMA exhibited no systemic toxicity, while Dox does. Venous thromboembolism is the second-most prevalent cause of death in cancer patients. 49 Since THCMA possesses inhibitory effects on both venous thrombosis and tumor proliferation, it has the potential to be developed into a dualfunction drug treating cancer patients associated with venous thrombosis. A new small-molecule P-selectin inhibitor -THCMAwas successfully designed as a nanomedicine, showing largely enhanced solubility and oral efficacy over the clinical trial drug PSI-697. Our results suggest that THCMA selfassembles into nanorings of approximately 100 nm in diameter. THCMA's water solubility was about 1,030-fold that of PSI-697, oral efficacy 100-fold that of PSI-697 in inhibiting arterial and venous thrombosis, and tenfold that of PSI-697 in inhibiting inflammation. Furthermore, unlike warfarin, THCMA inhibited venous thrombosis without coagulation disorders and bleeding risk. More interestingly, THCMA possesses comparable antitumor activity to Dox without causing systemic chemotherapy toxicity. THCMA has the International Journal of Nanomedicine 2021:16 https://doi.org/10.2147/IJN.S316863 DovePress 5793 potential to be developed as a therapeutic agent for the oral treatment of arterial thrombosis, venous thrombosis, inflammation, and cancer-associated thrombosis. 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