How does A Tiny Terminal Alkynyl End Group Drive Fully Hydrophilic. Homopolymers to Self-Assemble into Multicompartment Vesicles and

Similar documents
supramolecular hyperbranched polymers for controllable self-assembly

A supramolecular approach for fabrication of photo- responsive block-controllable supramolecular polymers

Supporting Information for

Sequential dynamic structuralisation by in situ production of

Supplementary Information

Supporting Information. Vesicles of double hydrophilic pullulan and. poly(acrylamide) block copolymers: A combination

Electronic Supplementary Information (12 pages)

Supporting Information for

A thermally remendable epoxy resin

Red Color CPL Emission of Chiral 1,2-DACH-based Polymers via. Chiral Transfer of the Conjugated Chain Backbone Structure

Supporting Information

A novel smart polymer responsive to CO 2

Block: Synthesis, Aggregation-Induced Emission, Two-Photon. Absorption, Light Refraction, and Explosive Detection

Electronic Supplementary Information

Reactive fluorescent dye functionalized cotton fabric as a Magic Cloth for selective sensing and reversible separation of Cd 2+ in water

Self-assembled ph-responsive Polymeric Micelles for Highly. Efficient, Non-Cytotoxic Delivery of Doxorubicin Chemotherapy

Supporting Information for

Supramolecular complexes of bambusuril with dialkyl phosphates

Electronic Supplementary Information. ligands for efficient organic light-emitting diodes (OLEDs)

Electronic Supplementary Material

Revisiting the complexation between DNA and polyethylenimine when and where S S linked PEI is cleaved inside the cell

Hyperbranched Poly(N-(2-Hydroxypropyl) Methacrylamide) via RAFT Self- Condensing Vinyl Polymerization

Supporting Information

Supporting Information

Antibacterial Coordination Polymer Hydrogels Consisted of Silver(I)-PEGylated Bisimidazolylbenzyl Alcohol

Supporting Information For:

Domino reactions of 2-methyl chromones containing an electron withdrawing group with chromone-fused dienes

Yujuan Zhou, Kecheng Jie and Feihe Huang*

Supplementary Note 1 : Chemical synthesis of (E/Z)-4,8-dimethylnona-2,7-dien-4-ol (4)

Molecular Weight Distribution of Living Chains in Polystyrene Pre-pared by Atom Transfer Radical Polymerization

How to build and race a fast nanocar Synthesis Information

Chia-Shing Wu, Huai-An Lu, Chiao-Pei Chen, Tzung-Fang Guo and Yun Chen*

Supporting Information

Supporting Information

Supporting Information

Supplementary Information. Rational Design of Soluble and Clickable Polymers Prepared by. Conventional Free Radical Polymerization of

Supporting Information

Supporting Information. A rapid and efficient synthetic route to terminal. arylacetylenes by tetrabutylammonium hydroxide- and

Photooxidations of 2-(γ,ε-dihydroxyalkyl) furans in Water: Synthesis of DE-Bicycles of the Pectenotoxins

Significant improvement of dye-sensitized solar cell. performance by a slim phenothiazine based dyes

Supporting Information

SUPPORTING INFORMATION

Supporting Text Synthesis of (2 S ,3 S )-2,3-bis(3-bromophenoxy)butane (3). Synthesis of (2 S ,3 S

Synthesis of fluorophosphonylated acyclic nucleotide analogues via Copper (I)- catalyzed Huisgen 1-3 dipolar cycloaddition

Supramolecular hydrogen-bonded photodriven actuators based on an azobenzenecontaining

Synthesis and Characterization of Well-defined PAA- PEG Multi-responsive Hydrogels by ATRP and Click Chemistry

Supporting Information

Supporting Information. Competitive Interactions of π-π Junctions and their Role on Microphase Separation of Chiral Block Copolymers

Aziridine in Polymers: A Strategy to Functionalize Polymers by Ring- Opening Reaction of Aziridine

Fluorescent Chemosensor for Selective Detection of Ag + in an. Aqueous Medium

Supporting Information. For. Organic Semiconducting Materials from Sulfur-Hetero. Benzo[k]fluoranthene Derivatives: Synthesis, Photophysical

Supporting Information

Aminoacid Based Chiral N-Amidothioureas. Acetate Anion. Binding Induced Chirality Transfer

Appendix A. Supplementary Information. Design, synthesis and photophysical properties of 8-hydroxyquinoline-functionalized

Supporting Information

Self-Assembly and Multi-Stimuli Responsive. Behavior of PAA-b-PAzoMA-b-PNIPAM Triblock. Copolymers

Supplementary Information

Synthesis of Trifluoromethylated Naphthoquinones via Copper-Catalyzed. Cascade Trifluoromethylation/Cyclization of. 2-(3-Arylpropioloyl)benzaldehydes

Biotin-guided anticancer drug delivery with acidity-triggered drug release

Electronic Supplementary Information

A Novel Polytriazole-based Organogel Formed by the Effects. of Copper Ions

Supporting Information

Supporting Information. Reduction- and Thermo-Sensitive Star Polypeptide Micelles. and Hydrogels for On-Demand Drug Delivery

Supporting Information

Supporting Information (SI)

Supporting Information for

Supporting Information

Supporting Information

Organized polymeric submicron particles via selfassembly. and crosslinking of double hydrophilic. poly(ethylene oxide)-b-poly(n-vinylpyrrolidone) in

A Photocleavable Linker for the Chemoselective Functionalization of Biomaterials

Indium Triflate-Assisted Nucleophilic Aromatic Substitution Reactions of. Nitrosobezene-Derived Cycloadducts with Alcohols

Supporting Information. Various Polystyrene Topologies Built from. Tailored Cyclic Polystyrene via CuAAC. Reactions.

Supporting Information

An efficient one pot ipso-nitration: Structural transformation of a dipeptide by N-terminus modification

An unexpected highly selective mononuclear zinc complex for adenosine diphosphate (ADP)

Supporting Information to

A dual redox-responsive supramolecular amphiphile fabricated by selenium-containing pillar[6]arene-based molecular recognition

Regioselective Synthesis of 1,5-Disubstituted 1,2,3-Triazoles by reusable

Efficient Magnesium Catalysts for the Copolymerization of Epoxides and CO 2 ; Using Water to Synthesize Polycarbonate Polyols

Supporting Information

Electronic Supplementary Information

Supplementary Information. Mapping the Transmission Function of Single-Molecule Junctions

Synthetic Studies on Norissolide; Enantioselective Synthesis of the Norrisane Side Chain

Supporting Information

New ratiometric optical oxygen and ph dual sensors with three emission colors for

Supporting Information

Supporting information

Sensitive and reliable detection of glass transition of polymers. by fluorescent probes based on AIE luminogens

Aluminum Foil: A Highly Efficient and Environment- Friendly Tea Bag Style Catalyst with High TON

Supporting Information

Curtius-Like Rearrangement of Iron-Nitrenoid Complex and. Application in Biomimetic Synthesis of Bisindolylmethanes

Supporting Information

Silver-catalyzed decarboxylative acylfluorination of styrenes in aqueous media

Supporting Information

Self-Healing Polymers with PEG Oligomer Side Chains. Based on Multiple H-Bonding and Adhesion Properties

An insulin-sensing sugar-based fluorescent hydrogel

Electronic Supplementary Information

Supporting information

RAFT and Click Chemistry : A Versatile Approach to the Block Copolymer Synthesis

Supporting Information

Transcription:

Electronic Supplementary Material (ESI) for Polymer Chemistry. This journal is The Royal Society of Chemistry 04 Electronic Supplementary Information for How does A Tiny Terminal Alkynyl End Group Drive Fully Hydrophilic Homopolymers to Self-Assemble into Multicompartment Vesicles and Flower-Like Complex Particles? Tingting Liu a, Wei Tian a *, Yunqing Zhu b, Yang Bai a, Hongxia Yan a, and Jianzhong Du b * a The Key Laboratory of Space Applied Physics and Chemistry, Ministry of Education and Shaanxi Key Laboratory of Macromolecular Science and Technology, School of Science, orthwestern Polytechnical University, Xi an, 00, P. R. of China b School of Materials Science and Engineering, Tongji University, 4800 Caoan Road, Shanghai, 0804, China Table of Contents. Synthesis of ATRP initiators. Synthesis of linear homopolymers 3. Synthesis of long chain hyperbranched homopolymer 4. Characterization of homopolymers 5. Self-assembly of homopolymers 6. References

. Synthesis of ATRP initiators Propargyl -bromoisobutyrate (I ), propargyl -bromo--methylpropionamide (I ), and benzyl - bromoisobutyrate (I 5 ) were synthesized according to the references, respectively. [S-S3] The characterization data were listed as following. For I : H MR (CDCl 3,, ppm): 4.8 (H, CH );.53 (H, CH C );.96 (6H, C C(CH 3 ) ). 3 C MR (CDCl 3,, ppm):. ( C C(CH 3 ) );.36 (CH C ); 5.36 (CH C ); 54.9 ( CH ); 53.36 ( C C(CH 3 ) ); 30.65 ( C C(CH 3 ) ). FTIR (KBr) 3404 cm - (, C H); 0 cm - (, C C); 34 cm - (, C ); 54 cm - (, C Br). For I : H MR (CDCl 3,, ppm):.5-6. (H, CH H ); 4.05 (H, CH H );. (H, CH C );.96 (6H, C C(CH 3 ) ). 3 C MR (CDCl 3,, ppm):.8 ( C C(CH 3 ) ); 6.3 (CH C );. (CH C ); 6.3 ( C C(CH 3 ) ); 3.60 ( C C(CH 3 ) ); 30.3 ( CH H ). FTIR (KBr) 340 cm - (, C H); 3 cm - (, C C); 535 cm - (, C Br). For I 5: H MR (CDCl 3,, ppm):.5-.5 (5H, Ph(H) ); 5. (H, Ph CH );.0-.4 (6H, C C(CH 3 ) ). 3 C MR (CDCl 3,, ppm):.48 ( C C(CH 3 ) ); 35.66, 8.60,.9 (Ph ); 65.3 (Ph CH ); 55.8 ( C C(CH 3 ) ); 30.80 ( C C(CH 3 ) ). FTIR (KBr): 333.6 cm - (, Ph(C H)); 9 cm - (, CH ); 34 cm - (, C ); 496.5 cm - (, Ph(C=C)); 596 cm - (, C Br). Dipropargyl -bromo--methylpropionamide (I 3 ) was synthesized by the amidation reaction of Dipropargylamine and -Bromo--methylpropionyl bromide. Dipropargylamine (44 mg, 8 mmol), 4- dimethylaminopyridine (44 mg, mmol), pyridine (59 mg, 9.6 mmol) was dissolved in dried CH Cl (0 ml). After cooling to 0 o C, -bromo--methylpropionyl bromide (. g, 9.6 mmol) was added dropwise to the solution. The mixture was then stirred at room temperature for 4 h. After completion of strring, deionized water (00 ml) was added in the mixture. The organic solution was washed with deionized water three times. After the organic solution was dried with anhydrous sodium sulfate, the CH Cl was removed by rotary evaporator. The crude product was purified by column chromatography (silica gel size: 0-00 m,column diameter: cm,column length: 30 cm) using petroleum ether/ethyl acetate (V/V=/) as elute, yielding dipropargyl--bromo--methylpropionyl bromo amide was yellow liquid. Yields: 66.4%. H MR (CDCl 3,, ppm): 4.0-4.0 (4H, (CH C CH ) );.35-.5 (H, (CH C CH ) );.05-.95 (6H, C C(CH 3 ) ). 3 C MR (CDCl 3,, ppm):

69.36 ( C C(CH 3 ) );.8 ((CH C CH ) );.88 ((CH C CH ) ); 56.4 ( C C(CH 3 ) ); 35.0-38.4 ((CH C CH ) ); 3.4 ( C C(CH 3 ) ). FTIR (KBr): 3 cm - (, C H); cm - (, C C); 59 cm - (, C Br). Electrospray ionization mass spectrometry (CDCl 3, m/z): calcd for C 0 H Br: 4.0; found for [M-H] + : 4.3. Elemental analysis (%): calcd for C 0 H Br: C 49.58, H 4.959, 5.85; found: C 45.56, H 4.56, 5.368. Figure S Electrospray ionization mass spectrum of I 3. The (M-H) + peak was found at m/z = 4.3, which is consistent with the calculated value m/z =4.0.. Synthesis of linear homopolymers Synthesis of homopolymers -3. The typical procedure was as follows. A Schlenk tube was added with IPAM (.83 g, 5 mmol), Me 6 TER (5 mg, 0.5 mmol), CuBr ( mg, 0.5 mmol), I (03 mg, 0.5 mmol) and dry DMF (5 ml) under nitrogen. The mixture was then stirred for 5 min and subjected to three freeze-vacuum-thaw cycles, and then the tube was immersed into an oil bath at 60 o C to perform polymerization. After 4 h, the mixture was diluted with THF and passed though a neutral alumina column. The solid was dissolved in distilled water and dialyzed (molecular weight cut off: 3500) for 5 d. Homopolymer was obtained by lyophilization. Yields: 45.%. H MR (DMS-d 6,, ppm):.50-.04 ( H CH(CH 3 ) ); 4.63 (H, HC C CH ); 3.86 ( H CH(CH 3 ) );.9 ( CH(C) CH );.45 ( CH(C) CH );.5-0.8 ( H CH (CH 3 ) ). 3 C MR (DMS-d 6,, ppm): 5.4 ( C H ); 65.04 (HC C CH C ); 43.09 ( H CH(CH 3 ) ); 3.06 ( CH(C) CH ); 3.69 ( H CH(CH 3 ) ). FTIR (KBr): 34 cm - (, C H); 330 cm - (, H); 4 cm - 3

(, C C); 0 cm - (, C ); 53 cm - (, C Br). Homopolymers including and 3 were synthesized with the similar procedure except for the ratio of IPAM to I. Their polymerization results were shown in Table S. Synthesis of homopolymers 4. The synthesis and purification procedures were similar with homopolymer except that I was used instead of I. Yields: 53.%. H MR (DMS-d 6,, ppm):.5-6.89 ( H CH(CH 3 ) ); 5.56 (H, HC C CH ); 3.8 ( H CH(CH 3 ) );.8 (HC C CH );.9 ( CH(C) CH );.46 ( CH(C) CH );.05 ( H CH(CH 3 ) ). 3 C MR (DMS-d 6,, ppm): 4.8 ( C H CH(CH 3 ) ); 65.04 (CH C CH H C ); 8.8 (CH C CH ); 3.49 (CH C CH ); 43.0 ( H CH(CH 3 ) ); 38.8 ( CH(C) CH ); 35. ( H C C(CH 3 ) ); 3.05 ( CH(C) CH ); 9.9 (CH C CH ); 3.63 ( C H CH(CH 3 ) ). FTIR (KBr): 35 cm - (, C H); 395 cm - (, H); 4 cm - (, C C); 0 cm - (, CH ); 5 cm - (, C Br). Synthesis of homopolymer 5. The synthesis and purification procedures were similar with homopolymer except that I 3 was used instead of I. Yields: 40.4%. H MR (DMS-d 6,, ppm):.5-.0 ( H CH(CH 3 ) ); 4.08 (4H, (CH C CH ) ); 3.94 (H, CH(C) CH Br); 3.9-3.5 ( H CH(CH 3 ) );.6 (H, (CH C CH ) );.8-.5 ( CH(C) CH );.5-. ( CH(C) CH );.5-0.5 ( H CH(CH 3 ) ); 3 C MR (DMS-d 6,, ppm): 3.6 ( C H CH(CH 3 ) ); 4.55 ( H CH(CH 3 ) ); 36.45 ( CH(C) CH ); 33.90 ( CH(C) CH Br); 30.4 ( CH(C) CH );.55 ( H CH(CH 3 ) ); 0.94 (= C C(CH 3 ) ). FTIR (KBr): 3 cm - (, C H); 3308 cm - (, H); cm - (, C C); 646 cm - (, CH ); 50 cm - (, C Br). Synthesis of homopolymer. The synthesis and purification procedures were similar with homopolymer except that I 4 was used instead of I. Yields: 55.%. H MR (DMS-d 6,, ppm):.35 ( C H CH(CH 3 ) ); 4.03 (CH 3 CH ); 3.85 ( H CH(CH 3 ) );.99 ( CH(C) CH );.4 ( CH(C) CH );. ( C C(CH 3 ) );.06 ( H CH(CH 3 ) ). 3 C MR (DMS-d 6,, ppm): 3.86 ( C H CH(CH 3 ) ); 64.03 (CH 3 CH C ); 4.0 ( H CH(CH 3 ) ); 36.9 ( CH(C) CH ); 30.88 ( CH(C) CH ); 5. (CH 3 CH C ); 4.54 (CH 3 CH C );.4 ( H CH(CH 3 ) ). FTIR (KBr): 3490 cm - (, C H); 395 cm - (, H); 698 cm - (, 4

C ); 530 cm - (, C Br). Synthesis of homopolymer 8. The synthesis and purification procedures were similar with homopolymer except that I 5 was used instead of I. Yields: 49.%. H MR (DMS-d 6,, ppm):.36 (5H, Ph(H));.65-6.959 ( C H CH(CH 3 ) ); 5.03(Ph CH ); 3.84 ( H CH(CH 3 ) );.98 ( CH(C) CH );.43 ( CH(C) CH );.05 ( H CH(CH 3 ) ). 3 C MR (DMS-d 6,, ppm): 3.88 ( C H CH(CH 3 ) ); 64.3 (Ph CH C ); 3.40-5.8 (Ph(C)); 66. 3 (Ph CH C ); 4.8 ( H CH(CH 3 ) ); 35. 9 ( CH(C) CH );.80 ( H CH(CH 3 ) ). FTIR (KBr): 933 cm - (, CH ); 09 cm - (, C ); 49 cm - (, Ph(C=C)); 53 cm - (, C Br). Synthesis of homopolymer 9. A mixture of I (03 mg, 0.5 mmol), EGMA 45 (.85 g, 6 mmol) and PMDETA (86 mg, 0.5 mmol) in 5 ml H /methanol (:, v/v) was bubbled with nitrogen gas for 5 min at 0 o C, CuBr (4 mg, 0. mmol) and CuCl (54 mg, 0.4 mmol) was then added. The solution was bubbled with nitrogen gas for 30 min at 0 o C and sealed under atmosphere. The polymerization was conducted at 0 o C for 4 h. It was terminated by exposing to air and diluting with THF. After passing through a neutral alumina column and evaporating most of solvent, the residues were precitated and dried in a vacuum 3 d. Homopolymer 9 was obtained. Yields: 45.%. H MR (DMS-d 6,, ppm): 4. (H, HC C CH ); 4.0 ( C CH CH ); 3.59 ( C CH CH ); 3.5 ( CH CH ); 3.44 (6H, C C(CH 3 ) ); 3.3 ( CH 3 );.5 ( CH C(CH 3 ) ); 0.98-0.9 ( CH C(CH 3 ) ). 3 C MR (DMS-d 6,, ppm):.6 ( C CH CH );.56 ( C CH CH );.8 ( CH CH ); 69.5 ( C CH CH ); 65.34 ( CH C(CH 3 ) ); 59.4 ( CH 3 ); 45.3 ( CH C(CH 3 ) );.56 ( C C(CH 3 ) ). FTIR (KBr): 398 cm - (, C H); 80 cm - (, C ); 30 cm - (, C ); 54 cm - (, C Br). Synthesis of homopolymer 0. The synthesis and purification procedures were similar with homopolymer 9 except that I was used instead of I. Yields: 5.%. H MR (DMS-d 6,, ppm): 4.4 (H, HC C CH ); 4.0 ( C CH CH ); 3.6 ( C CH CH ); 3.5 ( CH CH ); 3.44 ( C C(CH 3 ) ); 3.3( CH 3 );.5 ( CH C(CH 3 ) ); 0.95-0.9 ( CH C(CH 3 ) ). 3 C MR (DMS-d 6,, ppm):.86 ( C CH CH );.58 ( C CH CH );.9 ( CH CH ); 69.85 ( C CH CH ); 65.44 ( CH C(CH 3 ) ); 5

59.35 ( CH 3 ); 46.0 ( CH C(CH 3 ) ). FTIR (KBr): 33 cm - (, C H); 865 cm - (, C ); 8 cm - (, HC ); 530 cm - (, C Br). Synthesis of homopolymer. The synthesis and purification procedures were similar with homopolymer 9 except that I 3 was used instead of I. Yields: 69.%. H MR ( DMS-d 6,, ppm): 5.5 ( CH C(CH 3 ) Br); 4. ((HC C) CH H ); 4.0 ( C CH CH ); 3.4 ( C CH CH ); 3.5 ( CH CH ); 3.4 ( C C(CH 3 ) ); 3.4 ( CH 3 );.3 ((HC C CH ) H );.5-.4 ( CH C(CH 3 ) );.-0.6 ( CH C(CH 3 ) ). 3 C MR (DMSd 6,, ppm):.09 ( C CH CH );.4 ( C CH CH ); 69.8 ( CH CH ); 6.84 ( C CH CH ); 63.9 ( CH C(CH 3 ) ); 58. ( CH 3 ); 44. ( CH C(CH 3 ) ); 6.40 ( C C(CH 3 ) ). FTIR (KBr): 39 cm - (, C H); 8 cm - (, C ); 8 cm - (, HC ); 5 cm - (, C Br). 3. Synthesis of long chain hyperbranched homopolymer Synthesis of 5. To obtain 6, 5 was first synthesized by the azidation of 5. The typical procedure was as follows. 5 (50 mg, 0.03 mmol), a 3 (4 mg, 0.3 mmol) was mixed with DMF ( ml). The mixture was stirred at 50 o C for 48 h. After cooling to room temperature, the mixture was dialyzed (molecular weight cut off: 3500) for 3 d. Homopolymer 5 was obtained by lyophilization. H MR (DMS-d 6,, ppm):.5-.0 ( H CH(CH 3 ) ); 4.08 (4H, (CH C CH ) ); 3.9-3.5 ( H CH(CH 3 ) ); 3.85 (H, CH(C) CH 3 );. (H, (CH C CH ) );.8-.5 ( CH CH );.4 ((CH C CH ) );.5-. ( CH(C) CH );.5-0.5 ( H CH(CH 3 ) ). 3 C MR ( DMS-d 6,, ppm) 3.0 ( C H ); 4.50 ( H CH(CH 3 ) ); 36.0 ( CH(C) CH );.4 ( H CH(CH 3 ) ). FTIR (KBr): 3 cm - (, C H); 3308 cm - (, H); cm - (, C C); 646 cm - (, C H ). Synthesis of LCHBH 6. 5 (88 mg, 0.09 mmol), CuBr (6.6 mg, 0.043 mmol), PMDETA (.6 mg, 0.043 mmol), and DMF (.5 ml) was added into a Schlenk tube. The mixture was then stirred for 5 min and subjected to three freeze-vacuum-thaw cycles, and then the tube was immersed into an oil bath at 00 o C. After 4h, the mixture was diluted with THF and passed though a neutral alumina column. The solid was dissolved in distilled water and dialyzed (molecular weight cut off: 8000~4000) for 5 days. 6

Homopolymer 6 was obtained by lyophilization. Yields: 65.5%. H MR (DMS-d 6,, ppm):.96 (methine proton in,,3-triazole ring);. ( H CH(CH 3 ) ); 5.35 ( CH, protons in,,3- triazole ring); 3.84 ( H CH(CH 3 ) );.4 ((CH C CH ) );.98 ( CH(C) CH );.46 ( CH(C) CH );.05 ( H CH(CH 3 ) ). 3 C MR (DMS-d 6,, ppm): 3.4 ( C H CH(CH 3 ) ); 3.,.06 (C=C, carbons in the,,3-triazole ring); 4.65 ( H CH(CH 3 ) ); 36.49 ( CH(C) CH ); 3.50 ( CH, carbon attached to,,3-the triazole ring); 8.98 ( CH(C) CH );.48 ( H CH(CH 3 ) ). FTIR (KBr): 3308 cm - (, H); 3 cm - (, C H); cm - (, C C); 646 cm - (, HC ). 4. Characterization of homopolymers Table S. Molecular structure parameters of homopolymers Code Sample M a w M a n M w /M a n DP b n HP/HPI c (kda) (kda) (wt%) PIB-PIPAM-Br 5.8 4.. 36.6 PIB-PIPAM-Br. 5.3.35 45.4 3 PIB-PIPAM-Br. 9.9. 85.03 4 PMPA-PIPAM-Br 5.8 4.5.9 38.40 5 DiPMPA-PIPAM-Br 5.3 4.. 34.6 6 DiPMPA m -HBPIPAM- 3 44.3 4.6.04 EIB-PIPAM-Br.5 5.4.38 4.54 8 BIB-PIPAM-Br.8 6.8.4 59. 9 PIB-PEGMA 45 -Br 9.5 6..43 4.3 0 PMPA-PEGMA 45 -Br 9.5 8.5.3 8 0.8 DiPMPA-PEGMA 45 -Br 5. 0..40 0.54 a Molecular weight and molecular weight distributions determined by SEC/MALLS, d Degree of polymerization determined by M n, c The weight fraction of the hydrophobic end group in the whole hydrophilic homopolymer.

Figure S SEC/MALLS curves of homopolymers. (A) homopolymers -4 (in DMF); (B) homopolymers 5, 5 and 6 (in DMF); (C) homopolymers and 8 (in DMF); (D) homopolymers 9- (in THF). 8

8 H 43 8 Br 4.0 n- 5 H 6 8. H 8.0 4.5.9 4.0 4.05 4.00 3.95 DMS.8 (A) 6 5 3 8 4 3 3 4 6 n H 5 3 5 H 6 8 n- 4.4.3...0.9.8..6.5.4 H (B) 6,8 5 3 4 6 n H n 3 5 H (C) 4 8 6 5 4 3 3 0 (ppm) Figure S3 H MR spectra of homopolymers 5 (A), 5 (B) and 6 (C) in DMS-d6. 5. Self-assembly of homopolymers Figure S4 TEM and AFM images of homopolymers 4 and 5 (A-B for TEM and E-F for AFM) aqueous solutions with a concentration of 0. mg/ml at 0 oc; (C-D) Typical magnification images of A-B. 9

0

Figure S5 Relationship between the fluorescence intensity ratio (I 3 /I ) and homopolymer concentration in aqueous solution (Inset: fluorescence emission spectrum of pyrene). A-K represent homopolymers -.

8 0 00 D z (nm) Figure S6 Typical intensity-averaged diameter distributions of the homopolymers and 8 (A and B) aqueous solutions with a concentration of 0. mg/ml at 0 o C Figure S Variation in the transmittance at 550 nm of the homopolymer aqueous solution (A: -3; B: 4-6) with a concentration of 0. mg/ml as a function of temperature.

Figure S8. FTIR-ATR spectra of homopolymers, 3-6 (A-E) solution in THF and their self-assemblies in H with a concentration of 0. mg/ml at 0 o C 3

Scheme S Chemical structure of doxorubicin hydrochloride 6. References [S] Tsarevsky,. V.; Sumerlin, B. S.; Matyjaszewski, K. Macromolecules 005, 38, 3558-356. [S] Song, J.; Lee, E.; Cho, B. K. J. Polym. Sci.: Part A: Polym. Chem. 03, 5, 446-456. [S3] Hovestad,. J.; Koten, G. V.; Bon, S. A. F.; Haddleton, D. M. Macromolecules 000, 33, 4048-405. 4

2024 © sciencedocbox.com Privacy Policy | Terms of Service | Feedback