Hydrophobic Optimization of Functional Poly(TPAE-co-suberoyl chloride) for Extrahepatic mRNA Delivery following Intravenous Administration

Messenger RNA (mRNA) has generated great attention due to its broad potential therapeutic applications, including vaccines, protein replacement therapy, and immunotherapy. Compared to other nucleic acids (e.g., siRNA and pDNA), there are more opportunities to improve the delivery efficacy of mRNA through systematic optimization. In this report, we studied a high-throughput library of 1200 functional polyesters for systemic mRNA delivery. We focused on the chemical investigation of hydrophobic optimization as a method to adjust mRNA polyplex stability, diameter, pKa, and efficacy. Focusing on a region of the library heatmap (PE4K-A17), we further explored the delivery of luciferase mRNA to IGROV1 ovarian cancer cells in vitro and to C57BL/6 mice in vivo following intravenous administration. PE4K-A17-0.2C8 was identified as an efficacious carrier for delivering mRNA to mouse lungs. The delivery selectivity between organs (lungs versus spleen) was found to be tunable through chemical modification of polyesters (both alkyl chain length and molar ratio in the formulation). Cre recombinase mRNA was delivered to the Lox-stop-lox tdTomato mouse model to study potential application in gene editing. Overall, we identified a series of polymer-mRNA polyplexes stabilized with Pluronic F-127 for safe and effective delivery to mouse lungs and spleens. Structure–activity relationships between alkyl side chains and in vivo delivery were elucidated, which may be informative for the continued development of polymer-based mRNA delivery.

In order to address the issues of low delivery efficacy and toxicity of cationic polymers, various chemical modifications have been explored [63,64]. Extensive research [64] has shown that hydrophobic modifications on polymers such as PEI, chitosan, poly(L-lysine) and poly(2-N-(dimethylaminoethyl) methacrylate) (pDMAMA) can have a significant effect on gene delivery by increasing the physical encapsulation of nucleic acids, enhancing cellular uptake and improving serum stability. We hypothesized that the hydrophobic domains of functional polyester backbones can also modulate mRNA delivery. In this paper, we focus on the hydrophobic side chain modification of polyesters to optimize polymer-based mRNA delivery and establish SAR. Via the high-throughput screening of 1200 functional polyesters, we were able to identify superior polymeric carriers for in vivo mRNA delivery. The delivery selectivity between organs (lungs versus spleen) was found to be tunable through modifying the side chain alkyl chain length and formulation conditions. Cre recombinase mRNA targeting the Lox-stop-lox tdTomato sequence in a mouse model was delivered to establish proof-of-concept gene editing. We also elucidated structure-activity relationships between alkyl side chains and in vivo delivery efficacy. We further demonstrate that hydrophobic modifications of cationic polymers could be highly beneficial for mRNA delivery. This work contributes to the overall body of literature on mRNA delivery carriers and further validates that mRNA therapeutics are an important area of research that may continue to yield next-generation vaccines and therapeutics.

Ethics Statement
All animal experiments were approved by the Institutional Animal Care and Use Committee (IACUC) of the University of Texas Southwestern Medical Center and were consistent with local, state, and federal regulations, as applicable.

Preparation and Characterization of mRNA Nanoparticles
The different molecular weights of ene-bearing polyesters were synthesized according to previously reported protocols [38,39,41,58]. The library of 1200 functional polyesters was synthesized through thiol-ene reaction under UV. For in vitro studies, mRNA NPs were prepared by adding diluted functional polymers (3 g/L in DMSO) into mRNA buffer solution (citric acid/trisodium citrate buffer, pH 4.2, 10 mM) at a polyester/mRNA ratio of 30:1 (wt/wt) and a final mRNA concentration of 1.25 ng/µL. For in vivo studies, 5 wt% Pluronic F-127 was added to the functional polyester DMSO solution, which was then diluted with EtOH (DMSO: EtOH = 1:2, v/v). An mRNA buffer solution (citric acid/trisodium citrate buffer, pH 4.2, 10 mM) was added to the above solution (aqueous: organic = 3:1, v/v) by hand-mixing to form the polyplex nanoparticles. The polyplex nanoparticles were dialyzed against PBS (1X) for 2h before injection to mice by I.V. administration. The size, polydispersity index (PDI), and zeta potential of the polyplex nanoparticles were measured using a Zetasizer Nano ZS (Malvern, He−Ne, λ = 632 nm). mRNA binding was tested Pharmaceutics 2021, 13, 1914 4 of 13 by utilizing the Quant-iT RiboGreen RNA assay kit. The global/apparent LNP pKa was determined by the TNS assay [26,65].

In Vitro Delivery of mRNA Polyplex Nanoparticles
RPMI-1640 medium with 5% FBS and 1% Penicillin/Streptomycin (P/S) was used to culture IGROV1 ovarian cancer cells. IGROV1 cells were seeded into opaque white 96-well plates (with a density of 10,000 cells/well) and incubated for 24 h at 37 • C and 5% CO 2 in a humidified atmosphere. After 24 h, the old medium was replaced with fresh RPMI-1640 medium with 5% FBS and 1% Penicillin/Streptomycin (P/S) (200 µL/well) followed by the addition of 20 µL of mRNA polyplex nanoparticles (25 ng mRNA/well). The final mixture was incubated for 24 h before testing the cell viability and luciferase expression by using ONE-Glo + Tox luciferase assay kits. All transfection assays were performed in triplicate, and the average with standard deviation was reported.
2.5. In Vivo Delivery of mRNA Polyplex Nanoparticles C57BL/6 mice were purchased from Charles-River. For Luc mRNA delivery, polyplex nanoparticles with mRNA were prepared as described above. 200 µL of mRNA polyplex NPs (10 µg of Luc mRNA, 0.5 mg/kg) were administered to C57BL/6 mice (18-24 g) by tail vein injection. After 6 h, D-luciferin (150 mg/kg) was injected via I.P. administration. After 5 min, whole body and ex vivo organs of mice were imaged by an IVIS Lumina imaging system. For the tdTomato mice (Ai9) experiments, 200 µL of mRNA polyplex NPs (10 µg of Cre mRNA, 0.5 mg/kg) was administered to tdTomato mice (18-24 g) by tail vein. After 2 days, the mice were sacrificed, and ex vivo organs of mice were imaged by an IVIS Lumina imaging system. For biodistribution, 200 µL of mRNA polyplex NPs (10 µg of Cy5-mRNA, 0.5 mg/kg) was administered to C57BL/6 mice (18-24 g) by tail vein. After 6 h, the mice were sacrificed, and the organs of mice were imaged ex vivo by an IVIS Lumina imaging system.

Results and Discussion
High-throughput synthesis and screening is an established approach for the discovery of effective carriers for delivery of nucleic acids [33]. Hydrophobic modification plays a key role in improving the efficacy and reducing the toxicity of polymers for nucleic acid delivery. Due to the amphiphilic lipid composition of plasma and endosome membranes, increasing the hydrophobicity of polymer carriers could increase polyplex cellular uptake and endosomal escape [64,66]. For example, the Forrest group reported that acetylated PEI can increase transfection efficiency by up to 58-fold compared to unmodified PEI [67,68]. Few studies have shown that hydrophobic modification can improve mRNA delivery. Here, we built a library of 1200 functional polyesters with different functional groups (alkyl-and amino-) utilizing our previous polycondensation method [58], and used in vitro/in vivo screening to identify vehicles for mRNA delivery. The library design is depicted in Figure 1. As hydrophobic modification can change the delivery efficacy [64,[66][67][68], here, we aimed to expand the chemical diversity of the hydrophobic motif. We used different categories of alkyl thiols, such as linear (SC2 to SC18), branched (SC4-1, SC5-1, and SC8-1), aromatic (SC8-Ph), and hydroxyl group containing (SO6 and SO11), to maximize the diversity. Whitehead et al. [43]. reported that the branched-tail ionizable cationic lipid can enhance the delivery efficacy of mRNA compared to the related linear lipid due to enhanced ionization at endosomal pH. With respect to the ionizable amine-containing side chains, we chose four different amines (A3, A5, A6, and A17), which have been proven effective in the delivery of either siRNA or mRNA [38,39,41]. Based on the chemical structures of these previously identified lead domains, we included a new amine, A21, due to its similarity to A17 and the fact that it is an amino acid (cysteine) derivative, as the amine component. Three different molecular weights of polyesters were chosen as the backbone for the thiol-ene reaction under UV conditions in order to study MW effects. delivery efficacy [64,[66][67][68], here, we aimed to expand the chemical diversity hydrophobic motif. We used different categories of alkyl thiols, such as linear (S SC18), branched (SC4-1, SC5-1, and SC8-1), aromatic (SC8-Ph), and hydroxyl containing (SO6 and SO11), to maximize the diversity. Whitehead et al. [43]. reporte the branched-tail ionizable cationic lipid can enhance the delivery efficacy of m compared to the related linear lipid due to enhanced ionization at endosomal pH respect to the ionizable amine-containing side chains, we chose four different amin A5, A6, and A17), which have been proven effective in the delivery of either siR mRNA [38,39,41]. Based on the chemical structures of these previously identifie domains, we included a new amine, A21, due to its similarity to A17 and the fact th an amino acid (cysteine) derivative, as the amine component. Three different mo weights of polyesters were chosen as the backbone for the thiol-ene reaction und conditions in order to study MW effects. Figure 1. A combinatorial library of functional polyester NPs was screened in IGROV1 cells to optimize mRNA delive materials. A library of 1200 functional polyesters was chemically synthesized for the screening of mRNA delivery. Pol esters were modified with amino thiols (R1SH) and alkyl thiols (R2SH) to generate a combinatorial polymer library. Amin thiols are named A followed by a number; alkyl thiols are named SC or SO followed by the number of carbons. Function polyesters with Mw 4200 g/mol (PE4K), 8300 g/mol (PE8K), and 17,000 g/mol (PE17K) were modified with five amin thiols (A3, A5, A6, A17, and A21) and all 20 alkyl thiols at SC:A molar feed ratios of 1:4, 1:2, 1:1, and 2:1. Functionalize polymers are named by the polyester Mw, amino modification, and the mole fraction of alkyl modification. All function polyesters were examined for in vitro mRNA delivery efficacy. Selected functional polyesters (0.2C4 to 0.2C11; 0.3C5 0.3C9) were examined for in vivo mRNA delivery efficacy.
The results of in vitro studies are shown in Figure 2 (also see Table S1, Supp Information). mRNA polyplexes with lower molecular weight (PE4k) functional p ters were able to deliver luciferase (Luc) mRNA into IGROV1 cells more efficientl the corresponding functional polyesters prepared from higher MW precursor po in general. These mRNA delivery results are in agreement with previous studies related functional polyesters for siRNA delivery, suggesting that a balance betwe polymer MW and hydrophobicity relating to physical chain entanglement and in lecular forces may be important for delivery efficacy [38,[69][70][71]. When further ana the results, the A17 (cysteamine)-modified polyesters again emerged as the most Figure 1. A combinatorial library of functional polyester NPs was screened in IGROV1 cells to optimize mRNA delivery materials. A library of 1200 functional polyesters was chemically synthesized for the screening of mRNA delivery. Polyesters were modified with amino thiols (R 1 SH) and alkyl thiols (R 2 SH) to generate a combinatorial polymer library. Amino thiols are named A followed by a number; alkyl thiols are named SC or SO followed by the number of carbons. Functional polyesters with Mw 4200 g/mol (PE4K), 8300 g/mol (PE8K), and 17,000 g/mol (PE17K) were modified with five amino thiols (A3, A5, A6, A17, and A21) and all 20 alkyl thiols at SC:A molar feed ratios of 1:4, 1:2, 1:1, and 2:1. Functionalized polymers are named by the polyester Mw, amino modification, and the mole fraction of alkyl modification. All functional polyesters were examined for in vitro mRNA delivery efficacy. Selected functional polyesters (0.2C4 to 0.2C11; 0.3C5 to 0.3C9) were examined for in vivo mRNA delivery efficacy.
The results of in vitro studies are shown in Figure 2 (also see Table S1, Supporting Information). mRNA polyplexes with lower molecular weight (PE4k) functional polyesters were able to deliver luciferase (Luc) mRNA into IGROV1 cells more efficiently than the corresponding functional polyesters prepared from higher MW precursor polymers in general. These mRNA delivery results are in agreement with previous studies using related functional polyesters for siRNA delivery, suggesting that a balance between the polymer MW and hydrophobicity relating to physical chain entanglement and intermolecular forces may be important for delivery efficacy [38,[69][70][71]. When further analyzing the results, the A17 (cysteamine)-modified polyesters again emerged as the most active region, which confirmed our earlier results in siRNA and mRNA delivery studies. As the current paper focuses on hydrophobic modifications, it was interesting to identify more effective materials (SC6, SC7, SC8, and SC8-1 modified polyesters) than those that have been previously identified. Notably, one of the high-molecular weight polyesters (PE17K-A17-0.2C8-1) Pharmaceutics 2021, 13,1914 6 of 13 also possessed great in vitro delivery efficacy. These results confirmed that hydrophobic optimization can improve mRNA delivery efficacy of polyplex carriers. With further respect to the hydrophobic domains, the linear alkyl-modified polyesters were slightly superior over branched alkyl-modified polyesters (SC4-1 versus SC4; SC5-1 versus SC5), with the exception of the eight-carbon alkyl-modified ones. These results are in contrast to recent observations of branching in small molecule lipid designs [43]. Alkyl lengths that were too short (SC2) or too long (SC18) did not show in vitro delivery efficacy, which has been previously observed in lipid designs [40,43]. The terminal hydroxyl alkyl-modified polyesters (SO6 and SO11) did not show great delivery efficacy in vitro, which could potentially be due to the increasing hydrophilicity of the extra hydroxyl group destabilizing the mRNA-polyplex self-assembly.
Pharmaceutics 2021, 13, x FOR PEER REVIEW 6 of 14 region, which confirmed our earlier results in siRNA and mRNA delivery studies. As the current paper focuses on hydrophobic modifications, it was interesting to identify more effective materials (SC6, SC7, SC8, and SC8-1 modified polyesters) than those that have been previously identified. Notably, one of the high-molecular weight polyesters (PE17K-A17-0.2C8-1) also possessed great in vitro delivery efficacy. These results confirmed that hydrophobic optimization can improve mRNA delivery efficacy of polyplex carriers. With further respect to the hydrophobic domains, the linear alkyl-modified polyesters were slightly superior over branched alkyl-modified polyesters (SC4-1 versus SC4; SC5-1 versus SC5), with the exception of the eight-carbon alkyl-modified ones. These results are in contrast to recent observations of branching in small molecule lipid designs [43]. Alkyl lengths that were too short (SC2) or too long (SC18) did not show in vitro delivery efficacy, which has been previously observed in lipid designs [40,43]. The terminal hydroxyl alkyl-modified polyesters (SO6 and SO11) did not show great delivery efficacy in vitro, which could potentially be due to the increasing hydrophilicity of the extra hydroxyl group destabilizing the mRNA-polyplex self-assembly.  Based on the in vitro results, we chose the PE4K-A17 sub-group materials to further test the delivery efficacy in vivo. Previously, we identified that the addition of 5 weight% of Pluronic F127 was a crucial surface coating component to stabilize the polyplex nanoparticles for intravenous administration [41]. The in vivo results (Figure 3) demonstrated Pharmaceutics 2021, 13,1914 7 of 13 that luciferase expression changed between organs (lungs and spleen) with the different alkyl chains lengths and molar ratios. When the SC:A molar feed ratio equaled 1:4 (0.2C), eight carbon alkyl chains (SC8) yielded the best performance. Interestingly, when the SC:A molar feed ratio was increased to 1:2 (0.33C), a shorter alkyl chain (six carbon, SC6) showed the highest in vivo efficacy. Overall, PE4K-A17-0.2C8 produced the best mRNA delivery efficacy. Interestingly, the delivery efficacy of linear (SC8) functional polyester was much better than branched (SC8-1) functional polyesters in the lungs, and the organ selectivity was reversed. We concluded that both the alkyl chain length and molar ratio used in the formulation played roles in delivery efficiency and organ selectivity. Short alkyl chains (SC4, SC5) and higher molar feed ratio of alkyl chains (0.33C7 and 0.33C8) favored the spleen, but the overall delivery efficacy was sensitive to these parameters. 0.5C7 and 0.67C7-modified polyesters (PE4K-A17) were unable to successfully deliver mRNA in vivo.
Based on the in vitro results, we chose the PE4K-A17 sub-group materials to further test the delivery efficacy in vivo. Previously, we identified that the addition of 5 weight% of Pluronic F127 was a crucial surface coating component to stabilize the polyplex nanoparticles for intravenous administration [41]. The in vivo results (Figure 3) demonstrated that luciferase expression changed between organs (lungs and spleen) with the different alkyl chains lengths and molar ratios. When the SC:A molar feed ratio equaled 1:4 (0.2C), eight carbon alkyl chains (SC8) yielded the best performance. Interestingly, when the SC:A molar feed ratio was increased to 1:2 (0.33C), a shorter alkyl chain (six carbon, SC6) showed the highest in vivo efficacy. Overall, PE4K-A17-0.2C8 produced the best mRNA delivery efficacy. Interestingly, the delivery efficacy of linear (SC8) functional polyester was much better than branched (SC8-1) functional polyesters in the lungs, and the organ selectivity was reversed. We concluded that both the alkyl chain length and molar ratio used in the formulation played roles in delivery efficiency and organ selectivity. Short alkyl chains (SC4, SC5) and higher molar feed ratio of alkyl chains (0.33C7 and 0.33C8) favored the spleen, but the overall delivery efficacy was sensitive to these parameters. 0.5C7 and 0.67C7-modified polyesters (PE4K-A17) were unable to successfully deliver mRNA in vivo. In our previous report, the chemical properties of functional polyesters could enable selective delivery to patient-matched cancer cells over normal cells [38]. Other reports have further correlated physical properties to in vivo delivery efficacy [43]. Next, we measured the physical properties of nanoparticles to determine SARs (Figures 4 and 5). Most selected polymers were able to bind to mRNA tightly (>80%) and form controlled polyplex nanoparticles with diameters < 150 nm, except for SC4-and SC5-modified polyesters. The short alkyl chains (SC4 and SC5) have less hydrophobicity, causing the nanoparticles to be less stable (large size and large PDI). These poor physical properties may explain the low in vivo delivery efficacy of SC4-and SC5-modified functional polyesters. In our previous report, the chemical properties of functional polyesters could enable selective delivery to patient-matched cancer cells over normal cells [38]. Other reports have further correlated physical properties to in vivo delivery efficacy [43]. Next, we measured the physical properties of nanoparticles to determine SARs (Figures 4 and 5). Most selected polymers were able to bind to mRNA tightly (>80%) and form controlled polyplex nanoparticles with diameters < 150 nm, except for SC4-and SC5-modified polyesters. The short alkyl chains (SC4 and SC5) have less hydrophobicity, causing the nanoparticles to be less stable (large size and large PDI). These poor physical properties may explain the low in vivo delivery efficacy of SC4-and SC5-modified functional polyesters. In Figure 5, the correlations between ex vivo luminescence intensity and the physicochemical properties of mRNA polyplex nanoparticles (0.2C4 to 0.2C11) are plotted. The surface charge of mRNA polyplex nanoparticles showed positive correlations to ex vivo luminescence intensity for both organs (lungs and spleen). PE4K-A17-0.2C6, 0.2C7 and 0.2C8 have a surface charge close to neutral, which may benefit in vivo delivery by improving stability and reducing MPS clearance. Consistent with our own and other studies on polymer-mediated mRNA delivery [41,50,53,55], mRNA translation to protein was mainly observed in the lungs and spleen. However, the biodistribution results tracking Cy5-mRNA showed that most polyplex nanoparticles accumulate in the liver ( Figure S1). This has also been observed for other polymeric mRNA carriers [72]. Therefore, it will be useful in future studies to determine the probable complex mechanism of this behavior, wherein the organ accumulation of mRNA delivery systems including lipid-and polymer-based carriers do not always lead to successful mRNA translation to protein. These observations also offer the opportunity to design liver-targeted mRNA polyplexes in the future, which are currently lacking for polymer-based systems. Although the mechanism remains unclear, PE4K-A17-0.2C8 accumulated in the lungs, which verifies the lung activity and potential superiority of PE4K-A17-0.2C8 polyplex nanoparticles over other tested polymers.
In Figure 5, the correlations between ex vivo luminescence intensity and the physicochemical properties of mRNA polyplex nanoparticles (0.2C4 to 0.2C11) are plotted. The surface charge of mRNA polyplex nanoparticles showed positive correlations to ex vivo luminescence intensity for both organs (lungs and spleen). PE4K-A17-0.2C6, 0.2C7 and 0.2C8 have a surface charge close to neutral, which may benefit in vivo delivery by improving stability and reducing MPS clearance. Consistent with our own and other studies on polymermediated mRNA delivery [41,50,53,55], mRNA translation to protein was mainly observed in the lungs and spleen. However, the biodistribution results tracking Cy5-mRNA showed that most polyplex nanoparticles accumulate in the liver ( Figure S1). This has also been observed for other polymeric mRNA carriers [72]. Therefore, it will be useful in future studies to determine the probable complex mechanism of this behavior, wherein the organ accumulation of mRNA delivery systems including lipid-and polymer-based carriers do not always lead to successful mRNA translation to protein. These observations also offer the opportunity to design liver-targeted mRNA polyplexes in the future, which are currently lacking for polymer-based systems. Although the mechanism remains unclear, PE4K-A17-0.2C8 accumulated in the lungs, which verifies the lung activity and potential superiority of PE4K-A17-0.2C8 polyplex nanoparticles over other tested polymers.  To assess additional applications of this carrier, we utilized a tdTomato mouse model, which contains a Lox-Stop-Lox tdTomato cassette in all cells, to test its gene editing capability via the deployment of Cre recombinase mRNA (Cre mRNA). Following translation of Cre mRNA to Cre protein and deletion the of stop codons, cells will express red fluorescent tdTomato protein and be readily detectable [73][74][75]. We formulated Cre mRNA into nanoparticles and then injected NPs into mice via I.V. administration at a dosage of 0.5 mg/kg ( Figure 6). Clear tdTomato signal throughout the lungs was observed by ex vivo lung imaging. It will be valuable in the future to understand which cell type(s) are transfected in order to match capabilities with therapeutic applications [41,50]. The results indicate that this carrier has potential applications in the deployment of proteins for gene editing for targets in the lungs due to the successful activation of tdTomato [76][77][78]. To assess additional applications of this carrier, we utilized a tdTomato mouse model, which contains a Lox-Stop-Lox tdTomato cassette in all cells, to test its gene editing capability via the deployment of Cre recombinase mRNA (Cre mRNA). Following translation of Cre mRNA to Cre protein and deletion the of stop codons, cells will express red fluorescent tdTomato protein and be readily detectable [73][74][75]. We formulated Cre mRNA into nanoparticles and then injected NPs into mice via I.V. administration at a dosage of 0.5 mg/kg ( Figure 6). Clear tdTomato signal throughout the lungs was observed by ex vivo lung imaging. It will be valuable in the future to understand which cell type(s) are transfected in order to match capabilities with therapeutic applications [41,50]. The results indicate that this carrier has potential applications in the deployment of proteins for gene editing for targets in the lungs due to the successful activation of tdTomato [76][77][78].   To assess additional applications of this carrier, we utilized a tdTomato mouse model, which contains a Lox-Stop-Lox tdTomato cassette in all cells, to test its gene editing capability via the deployment of Cre recombinase mRNA (Cre mRNA). Following translation of Cre mRNA to Cre protein and deletion the of stop codons, cells will express red fluorescent tdTomato protein and be readily detectable [73][74][75]. We formulated Cre mRNA into nanoparticles and then injected NPs into mice via I.V. administration at a dosage of 0.5 mg/kg ( Figure 6). Clear tdTomato signal throughout the lungs was observed by ex vivo lung imaging. It will be valuable in the future to understand which cell type(s) are transfected in order to match capabilities with therapeutic applications [41,50]. The results indicate that this carrier has potential applications in the deployment of proteins for gene editing for targets in the lungs due to the successful activation of tdTomato [76][77][78].

Conclusions
In this paper, we synthesized a combinatorial library of functional polyesters with a focus on hydrophobic optimization to identify efficacious materials for mRNA delivery by high-throughput screening. Following in vitro screening, we further examined a subportion of the library (PE4K-A17), which exhibited high delivery efficacy of Luc mRNA NPs in IGROV1 ovarian cancer cells. The delivery efficacy in vivo was examined by IV injection of formulated mRNA polyplex nanoparticles with 5% (wt/wt) of Pluronic F-127 into mice. PE4K-A17-0.2C8 was identified as the optimal polymeric carrier for the delivery of mRNA into mouse lungs. The delivery selectivity between organs (lungs versus spleen) was found to be tunable through chemical modification of polyesters (both alkyl chain length and molar ratio in formulation). Finally, we employed a tdTomato mouse model to demonstrate that this efficient mRNA delivery system could potentially be used to treat genetic lung diseases.

Supplementary Materials:
The following are available online at https://www.mdpi.com/article/10 .3390/pharmaceutics13111914/s1, Figure S1: Imaging of mice organs after injection of Cy-5 mRNAloaded functional polyesters; Figure S2: Selected NMR spectra of polyester and functional polyester; Figure S3: GPC (THF) curves of polyesters; Table S1: Raw data of in vitro screening of functional polyesters for luciferase mRNA delivery.

Dedication:
The authors dedicate this article to honor Katalin Karikó for her pioneering research in nucleoside modified mRNA. Katalin Karikó's discoveries directly contributed to the development of safe and effective mRNA vaccines against the SARS-CoV-2 virus, which causes the COVID-19 disease. Her discoveries have made a tremendously positive impact on science, health, and human society.

Conflicts of Interest:
The authors declare no conflict of interest.