Recent Strategies to Develop Conjugated Polymers for Detection and Therapeutics

The infectious diseases resulting from pathogenic microbes are highly contagious and the source of infection is difficult to control, which seriously endangers life and public health safety. Although the emergence of antibiotics has a good therapeutic effect in the early stage, the massive abuse of antibiotics has brought about the evolution of pathogens with drug resistance, which has gradually weakened the lethality and availability of antibiotics. Cancer is a more serious disease than pathogenic bacteria infection, which also threatens human life and health. Traditional treatment methods have limitations such as easy recurrence, poor prognosis, many side effects, and high toxicity. These two issues have led to the exploration and development of novel therapeutic agents (such as conjugated polymers) and therapeutic strategies (such as phototherapy) to avoid the increase of drug resistance and toxic side effects. As a class of organic polymer biological functional materials with excellent photoelectric properties, Conjugated polymers (CPs) have been extensively investigated in biomedical fields, such as the detection and treatment of pathogens and tumors due to their advantages of easy modification and functionalization, good biocompatibility and low cost. A rare comprehensive overview of CPs-based detection and treatment applications has been reported. This paper reviews the design strategies and research status of CPs used in biomedicine in recent years, introduces and discusses the latest progress of their application in the detection and treatment of pathogenic microorganisms and tumors according to different detection or treatment methods, as well as the limitations and potential challenges in prospective exploration.


Introduction
Conjugated polymers (CPs) are a kind of carbon chain skeleton organic macromolecular compound composed of one or more conjugated units connected by covalent bond polymerization, which form a large π-bond.The large π-electron delocalization and the conjugated backbone [1] composed of multiple electron donor-acceptor (D-A) repeating units make CPs have strong light-trapping ability and excellent photophysical properties.Moreover, most CPs have the advantages of low cost [2,3], easy modification and functionalization [4], biological safety [5], and biodegradability [6].They have been widely used in research from photoconducting devices to biological fields.
As is known to all, pathogenic microbes have always constituted a huge threat to global public health [7].Pathogenic infections may lead to serious diseases such as diarrhea, inflammation, and septicemia, which threaten life, [8] and may even cause a potentially large number of deaths each year [9].The early use of antibiotics showed a good bactericidal effect and made a great contribution to solving pathogenic infections, but the abuse and improper use of antibiotics led to the emergence of drug-resistant strains [10] and even the multi-drug resistant super-strains.It is indicated that pathogenic infections, especially Polymers 2023, 15, 3570 2 of 33 those that result from new drug-resistant bacteria, will become the second largest cause of death in the world [11].In addition, the World Health Organization (WHO) has declared that pathogen resistance is one of the top 10 global public health threats that humans will be confronted with [12].Thus, in the face of the above severe crisis, the efficient detection of pathogens and treatment of infections that do not easily cause drug resistance are particularly urgent and crucial.
However, there are still many limitations in the traditional detection methods of pathogenic bacteria and therapeutic materials instead of antibiotics.For example, the method based on microbial culture has a long culture time (48-72 h) and is susceptible to contamination [13].Antibody detection requires a large number of antigens, and the accuracy of the results is unstable, prone to false positives, and takes a long time [14].Multiple polymerase chain reaction (PCR)-based molecular diagnostics and mass spectrometry require a high level of expertise and equipment for testing [15].On the other hand, antimicrobials that replace antibiotics can currently be divided into three categories: natural antimicrobials, inorganic antimicrobials, and organic antimicrobials [16].Natural antimicrobials such as chitosan, bacteriophage [17], catechol [18], sorbic acid, etc., have low bactericidal rates without specificity and cannot be used in a broad spectrum and long term.There is also a type of natural antibacterial peptide molecule, which can be easily removed from the body and cannot be transported to the target with accumulation, resulting in poor bactericidal effect and low utilization [19].Inorganic antimicrobials are mostly materials based on metals such as Cu, Ag, and Zn, which are usually difficult to prepare and have poor biocompatibility.However, organic antimicrobials such as quaternary ammonium salts (QAS) [20] and phenols have problems such as easy hydrolysis, poor heat resistance, and a short validity period.In order to solve these problems, it is also essential to continue to explore antimicrobial materials with excellent antibacterial effects, good biocompatibility, and specificity for their application in practice.Therefore, it is necessary to develop more efficient, simple, cheap, and sensitive biosensing methods and new antibacterial agents with targeted and excellent bactericidal effects to detect and kill pathogens.
Cancer, another disease that is more serious than pathogenic infection, is also a global human public health problem [21] and one of the main causes of death worldwide.According to the estimate of the WHO, nearly 100,000 people will die from cancer in 2020 [22] seriously endangering human life and health.At present, conventional treatment and diagnosis methods for cancer include surgery [23], chemotherapy [24], radiotherapy [25], computed tomography (CT), magnetic resonance imaging (MRI), etc., which have many limitations such as high-risk, easy recurrence, poor prognosis, many side effects, high toxicity, and low resolution [26].In addition, the continuous development of drug resistance seriously limits the therapeutic effect, and the number of cancer patients and deaths continues to rise globally [27].Therefore, there is an urgent necessity for biological materials and therapeutic strategies that can overcome drug resistance, accurately diagnose, have excellent curative effects, and have a good prognosis.
With the progress of scientific research and technology, the emergence of advanced materials with excellent properties has brought hope to solve the above needs and challenges.Among them, CPs have many advantages mentioned above, and most reported CPs for biomedical applications have excellent biocompatibility, such as water-soluble conjugated polyelectrolytes with various backbones, including poly(fluorene-co-phenylene) (PFP), poly(phenylenevinylene) (PPV), poly(phenylene ethynylene) (PPE), polythiophene (PT), and polydiacetylene (PDA) [28] which have great potential as a class of new material to be widely used in biosensing, antibacterial and anticancer fields.such as biosensors, antibacterial and anticancer therapy [29,30].CPs can utilize Förster resonance energy transfer (FRET), signal amplification, and excellent light conversion capabilities for many chemical and biomolecular sensing analyses, as well as cellular and animal-level imaging and therapy [31].Therefore, CPs have been widely used as a probe or a light therapeutic agent based on the conversion of photon energy activated by light into optical signals or therapeutic effects.This process can be explained as shown in Figure 1 [32].As photosensitization agents, CPs can absorb energy to transition from the ground state (S0) to the high-energy and short-lived excited singlet state (Sn) under the excitation of appropriate wavelength of light, then undergo a rapid internal conversion (IC) process to the lowest energy level of the singlet excited state (S1), and finally go through three different energy dissipation paths from the S1 state to S0 including (1) fluorescent emission of radiative transitions, which can be used for fluorescence imaging (FLI) to guide detection, diagnosis and drug administration [33], (2) intersystem crossing (ISC) to a excited triplet state, followed by transferring hydrogen/electron/energy to nearby oxygen/biomolecules to produce cytotoxic reactive oxygen species (ROS) comprised of radicals (type I way) and singlet oxygen (type II way), which can be used in photodynamic (PDT) therapy [34], and (3) heat or sound wave generation through non-radiative decay, which can be used for photothermal (PTT) therapy or photoacoustic imaging (PAI) [35].CPs-based phototherapy overcomes antibiotic resistance and has the advantages of high spatial and temporal accuracy, noninvasiveness, low toxicity, and few side effects, thus showing unlimited biomedical potential in the diagnosis and treatment of pathogens and tumors [36].
Polymers 2023, 15, x FOR PEER REVIEW 3 of 33 optical signals or therapeutic effects.This process can be explained as shown in Figure 1 [32].As photosensitization agents, CPs can absorb energy to transition from the ground state (S0) to the high-energy and short-lived excited singlet state (Sn) under the excitation of appropriate wavelength of light, then undergo a rapid internal conversion (IC) process to the lowest energy level of the singlet excited state (S1), and finally go through three different energy dissipation paths from the S1 state to S0 including (1) fluorescent emission of radiative transitions, which can be used for fluorescence imaging (FLI) to guide detection, diagnosis and drug administration [33], (2) intersystem crossing (ISC) to a excited triplet state, followed by transferring hydrogen/electron/energy to nearby oxygen/biomolecules to produce cytotoxic reactive oxygen species (ROS) comprised of radicals (type I way) and singlet oxygen (type II way), which can be used in photodynamic (PDT) therapy [34], and (3) heat or sound wave generation through non-radiative decay, which can be used for photothermal (PTT) therapy or photoacoustic imaging (PAI) [35].
CPs-based phototherapy overcomes antibiotic resistance and has the advantages of high spatial and temporal accuracy, noninvasiveness, low toxicity, and few side effects, thus showing unlimited biomedical potential in the diagnosis and treatment of pathogens and tumors [36].Herein, the design strategies and research status of CPs in the biomedical field in the recent four years are reviewed, and the research progress of CPs in the detection and treatment of pathogenic microorganisms and cancer by different methods is summarized.(Table 1) It focuses on the application of CPs in pathogen detection by fluorescence and colorimetry, as well as the antibacterial and antitumor application of CPs by phototherapy and many different methods.In addition, the emerging strategy of integrated diagnosis and treatment is also introduced and discussed.In the end, the limitations and potential challenges of CPs in the future development of biomedicine are discussed and prospected.Herein, the design strategies and research status of CPs in the biomedical field in the recent four years are reviewed, and the research progress of CPs in the detection and treatment of pathogenic microorganisms and cancer by different methods is summarized.(Table 1) It focuses on the application of CPs in pathogen detection by fluorescence and colorimetry, as well as the antibacterial and antitumor application of CPs by phototherapy and many different methods.In addition, the emerging strategy of integrated diagnosis and treatment is also introduced and discussed.In the end, the limitations and potential challenges of CPs in the future development of biomedicine are discussed and prospected.

Polyfluorene derivative
Rapid and sensitive identification of bacteria and fungi in mixed pathogenic samples through the different binding force [38] Polythiophene (PT) The modified QAS group increases water solubility and gives a positive charge [39] Colorimetry Discrimination of G − and G + by detecting the color change produced by the reduction of bacterial metabolites. [40] Polydiacetylene (PDA) Treat with hydrochloric acid then react with ammonia gas metabolized by bacteria, and change color with different polymerization degrees by adjusting monomer arrangement. [41] Protease (OmpT) substrate-PT Through the color change of polythiophene with the cleavage of peptide, the unit level E. coli was detected colorimetrically within 10 min [42] Antibacterial therapy The conformational sensitive CP is arranged in a highly ordered conformation to produce more ROS [43] Poly(tetrapheny ethylene) Have AIE characteristics and higher ROS production ability [44] Poly(phenylenevinylene) (PPV) Have a positive charge and excellent PDT effect on S. aureus [45] PTT Purpurin + cucurbituril (CB [8]) Supramolecular polymerization driven by E. coli reduction in situ, the inhibitory effect on E. coli was >99.9% [46] Copolymerization of dithieno [3,2-

Fluorimetry
As fluorescence imaging technology based on fluorescent materials has made great progress in biological detection [66][67][68], the fluorescence detection method has become a routine research technology for pathogen detection due to its advantages of high resolution, short time consuming, excellent specificity, and high sensitivity.Because of the superior photophysical properties of CPs, they are often used as fluorescent probes for the detection of pathogenic microorganisms.
The Gram stain detection method based on common dyes has limitations such as complicated steps and poor fluorescence resulting in inaccurate results.Zhou et al. [37] realized the detection and typing of Gramella based on the fluorescence method by using a conjugated oligomer electrolyte (COE-S6) (Figure 2).It is formed by oligomerization of phenylenevinylene.Incidentally, the conjugated oligomer is a polymer composed of fewer conjugated repeating units, which are contained in a conjugated polymer.In the presence of COE-S6, the fluorescence enhancement of Gram-positive (G + ) bacteria fluid can be visually detected in situ, while the lipopolysaccharide outer membrane of Gram-negative (G − ) Polymers 2023, 15, 3570 6 of 33 bacteria obstructed the embedding of COE-S6, leading to the almost negligible fluorescence intensity changes.In the mixed sample of G − bacteria and G + bacteria, the sensitivity and specificity of COE-S6 against G + bacteria are much higher than that of commercially available probe FM-4-64.This work explored a simple and accurate method for gram bacteria typing based on a conjugated fluorescent probe with membrane specificity.Most of the actual samples that need to be tested and distinguished contain a of microorganisms, so the detection of microorganisms in mixed samples is of gr nificance [69].A lot of efforts are made to develop conjugated polymer-based fluore detection methods to accurately distinguish pathogen species in mixed samples.H et al. [38] designed a water-soluble cationic CP (PFBTM-NMe3 + ) using polyfluorene ative doped with benzothiazole (BT) groups as the main chain (Figure 3).The sid was modified with the targeting group mannose and the QAS group which prov positive charge and improved water solubility.The polymer uses a FRET mechan rapidly distinguish between bacteria and fungi based on differences in the mem composition and surface charge of pathogenic microbes.When the polymer inte with G − bacteria E. coli, G + bacteria S. aureus, and C. albicans, respectively, it sho significant and rapid fluorescence response to E. coli, but a weak response to S. aure almost no response to C. albicans.The reason is that the surface of E. coli has lectin that can bind to mannose and the most negative charges that could absorb pos charged PFBTM-NMe3 + to cause aggregation to exhibit strong FRET and fluore changes.However, S. aureus with less negative charges and C. albicans with the lea ative charges as well as lack of lectins showed weak aggregation fluorescence and gible fluorescence changes, respectively.In addition, in the detection of mixed sam E. coli and C. albicans, PFBTM-NMe3 + showed certain aggregation after binding to and exhibited specific, rapid, and sensitive fluorescence responses.Therefore, throu design of different binding strategies between the synthetic polymer and various gens, it is possible to realize rapid and sensitive fluorescence imaging and identif of bacteria and fungi in mixed pathogen samples, giving new impetus to the rese early clinical diagnosis of bacterial infection.Most of the actual samples that need to be tested and distinguished contain a variety of microorganisms, so the detection of microorganisms in mixed samples is of great significance [69].A lot of efforts are made to develop conjugated polymer-based fluorescence detection methods to accurately distinguish pathogen species in mixed samples.Hussain et al. [38] designed a water-soluble cationic CP (PFBTM-NMe 3 + ) using polyfluorene derivative doped with benzothiazole (BT) groups as the main chain (Figure 3).The side chain was modified with the targeting group mannose and the QAS group which provided a positive charge and improved water solubility.The polymer uses a FRET mechanism to rapidly distinguish between bacteria and fungi based on differences in the membrane composition and surface charge of pathogenic microbes.When the polymer interacted with G − bacteria E. coli, G + bacteria S. aureus, and C. albicans, respectively, it showed a significant and rapid fluorescence response to E. coli, but a weak response to S. aureus and almost no response to C. albicans.The reason is that the surface of E. coli has lectin FimH that can bind to mannose and the most negative charges that could absorb positively charged PFBTM-NMe 3 + to cause aggregation to exhibit strong FRET and fluorescence changes.However, S. aureus with less negative charges and C. albicans with the least negative charges as well as lack of lectins showed weak aggregation fluorescence and negligible fluorescence changes, respectively.In addition, in the detection of mixed samples of E. coli and C. albicans, PFBTM-NMe 3 + showed certain aggregation after binding to E. coli and exhibited specific, rapid, and sensitive fluorescence responses.Therefore, through the design of different binding strategies between the synthetic polymer and various pathogens, it is possible to realize rapid and sensitive fluorescence imaging and identification of bacteria and fungi in mixed pathogen samples, giving new impetus to the research of early clinical diagnosis of bacterial infection.The conjugated polymer polythiophene derivatives with high conjugation and fle ble structure have been explored for fluorescence imaging due to their excellent pho physical properties, but the low solubility limits their applications in diagnosis and th apeutics.Ren et al. [39] solved this problem by modifying QAS groups in the side cha of polythiophene.They polymerized a thiophene monomer (PFPTA) to obtain polym + and the illustration of its selective detection of bacteria in mixed samples.Reprinted with permission from ref. [38].Copyright 2020 American Chemical Society.

023, 15, x FOR PEER REVIEW
The conjugated polymer polythiophene derivatives with high conjugation and flexible structure have been explored for fluorescence imaging due to their excellent photophysical properties, but the low solubility limits their applications in diagnosis and therapeutics.Ren et al. [39] solved this problem by modifying QAS groups in the side chain of polythiophene.They polymerized a thiophene monomer (PFPTA) to obtain polymer PPFPTA, which was then coupled with a propylenediamine derivative followed by quaternizing with 1bromobutane to obtain an active cationic polythiophene derivative (QPDMAPTA) (Figure 4).The conjugated polymer not only increases the solubility but also introduces a positive charge that can bind to the membrane of pathogenic bacteria through hydrophilic and electrostatic interactions.When the G + bacteria (S. aureus, S. epidermidis, and MRSA) and G − bacteria (E. coli and P. aeruginosa) were incubated with QPDMAPTA, green fluorescence was observed in the G + bacteria groups, while the fluorescence of G − bacteria was negligible.This comparison between the presence and absence of fluorescence can be used for the typing detection of Gramella.In addition, after centrifuging and washing the bacteria solution co-cultured with the polymer, it can be observed that the precipitation color changes to a darker yellow or brown in the G + bacteria groups, which can be used to realize the rapid visual observation of the type of Gramella.Therefore, the synthetic QPDMAPTA has a bright prospect in the application of detection and differentiation of G + bacteria, and this work has enabled the potential application of the fluorescence method and rapid visual bacteria typing diagnosis.
PPFPTA, which was then coupled with a propylenediamine derivative followe quaternizing with 1-bromobutane to obtain an active cationic polythiophene deriv (QPDMAPTA) (Figure 4).The conjugated polymer not only increases the solubilit also introduces a positive charge that can bind to the membrane of pathogenic bac through hydrophilic and electrostatic interactions.When the G + bacteria (S. aureus, S dermidis, and MRSA) and G − bacteria (E. coli and P. aeruginosa) were incubated QPDMAPTA, green fluorescence was observed in the G + bacteria groups, while the rescence of G − bacteria was negligible.This comparison between the presence and ab of fluorescence can be used for the typing detection of Gramella.In addition, after ce fuging and washing the bacteria solution co-cultured with the polymer, it can be obse that the precipitation color changes to a darker yellow or brown in the G + bacteria gro which can be used to realize the rapid visual observation of the type of Gramella.T fore, the synthetic QPDMAPTA has a bright prospect in the application of detection differentiation of G + bacteria, and this work has enabled the potential application o fluorescence method and rapid visual bacteria typing diagnosis.

Colorimetry
Colorimetric sensors are widely used for detection due to their superiorities o cost, high sensitivity and specificity, and visibleness (even to the naked eye) [70].The simple to use and do not require professional training and expensive instruments [7 recent years, the emergence of advanced conjugated polymer materials with exce photophysical properties has greatly promoted the development of colorimetric se for the detection of pathogenic bacteria [72].
Wu et al. [40] designed a polythiophene derivative (PPE), a water-soluble ele chromic copolymer, as a novel sensor for active bacterial metabolism.Due to the low dation potential of PPE, it can be doped by oxygen in the natural environment to gen an oxidation state (ox-PPE).ox-PPE could be de-doped by active bacterial metab

Colorimetry
Colorimetric sensors are widely used for detection due to their superiorities of low cost, high sensitivity and specificity, and visibleness (even to the naked eye) [70].They are simple to use and do not require professional training and expensive instruments [71].In recent years, the emergence of advanced conjugated polymer materials with excellent photophysical properties has greatly promoted the development of colorimetric sensors for the detection of pathogenic bacteria [72].
Polymers 2023, 15, 3570 8 of 33 Wu et al. [40] designed a polythiophene derivative (PPE), a water-soluble electrochromic copolymer, as a novel sensor for active bacterial metabolism.Due to the low oxidation potential of PPE, it can be doped by oxygen in the natural environment to generate an oxidation state (ox-PPE).ox-PPE could be de-doped by active bacterial metabolites such as cysteine and glutathione (Figure 5).The reduction process was accompanied by a visual color change of ox-PPE, that formed the blue uncharged conjugated polymer to the purple partially oxidized free radical cationic conjugated polymer (i.e., polaron) and then to the light blue oxidized bicationic conjugated polymer (i.e., bipolaron).The change was measured in a high-throughput manner with a 96-well microplate reader showing a significant change in the absorption spectra.The color change of ox-PPE was observed by controlled addition of cell-free supernatant, while no color change occurred in cell-membrane-bound ox-PPE, demonstrating that the main mechanism of reduction can be attributed to extracellular metabolites, especially with high sensitivity and specificity toward cysteine and glutathione.Additionally, ox-PPE is capable of distinguishing between G − and G + bacteria, as well as discriminating drug-resistant strains, and is used to assess sensitivity to various antibiotics.This simple, economical, high-throughput, and rapid approach opens up a new opportunity for personalized diagnosis and prescribing of infectious diseases.Manikandan et al. [41] synthesized chalcone head group modified polydiacetylene and realized bacterial visual detection by using color transformation of its stimulation response to bacterial metabolite ammonia after hydrochloric acid treatment (Figure 6).Specifically, polydiacetylene (PDA) is a type of CPs synthesized with 1, 3-butanediyne as a monomer that has a unique color and fluorescence transformation, usually appearing blue and changing to red when subjected to external stimuli such as pH, temperature, mechanical strain, and molecular interactions.Only when the yellow chalcone diacetylene film under the action of hydrochloric acid (HCl), by adjusting the electrostatic ion pair interaction between the adjacent chalcone head groups, hydrogen bonding, and intramolecular π-π stacking, effectively promote the appropriate arrangement of the diacetylene unit of Manikandan et al. [41] synthesized chalcone head group modified polydiacetylene and realized bacterial visual detection by using color transformation of its stimulation response to bacterial metabolite ammonia after hydrochloric acid treatment (Figure 6).Specifically, polydiacetylene (PDA) is a type of CPs synthesized with 1, 3-butanediyne as a monomer that has a unique color and fluorescence transformation, usually appearing blue and changing to red when subjected to external stimuli such as pH, temperature, mechanical strain, and molecular interactions.Only when the yellow chalcone diacetylene film under the action of hydrochloric acid (HCl), by adjusting the electrostatic ion pair interaction between the adjacent chalcone head groups, hydrogen bonding, and intramolecular π-π stacking, effectively promote the appropriate arrangement of the diacetylene unit of the monomer (colorless), the diacetylene polymerization forms a conjugate PDA network structure (purple).However, when ammonia is encountered, HCl residues are removed, and the electrostatic interaction between chalcone heads and hydrogen bonds are destroyed, resulting in structural transformation and color changes.In addition, the polymerized membrane treated by HCl has reversible thermochromism in the temperature change of −50 to 20 • C (blue turning purple) and 20 to 50 • C (purple turning orange).First, it is attributed to the strong intramolecular interaction between HCl and chalcone groups, which promotes the flexibility of the structure and can produce different colors even at very low temperatures.At high temperatures, it is mainly due to the release of HCl in the polymer caused by heating, and the structure also changes resulting in color change.Based on the above mechanism, the colorimetric sensing ability of hydrochloric acid-treated chalcone-PDA membrane for ammonia gas was used to achieve high-sensitivity visual detection of bacterial growth and food spoilage under different temperature conditions.Compared with the existing food monitoring technology, the simple synthesis of chalcone-PDAhydrochloric acid film, sensitive color response, and the feasibility of early visual detection of food spoilage over a wide temperature range show significant practical advantages.Sinsinbar et al. [42] reported a color change-based OmpT substrate-polythiophe assay for the detection of E. coli in contaminated water samples (Figure 7).This assay u the cleavage ability of the protease (OmpT) at the double base site of the peptide to bi the substrate peptide of OmpT to polythiophene whose optical properties change with t cleavage of the peptide.E. coli at levels of 1-10 and 10 5 CFU/mL were detected within and 1 h, respectively.By optimizing the carboxylic acid side chain length of carboxyl functional polythiophene and the peptide substrate of OmpT, the detection time for E. c in highly contaminated samples was reduced from the already short 1 h to only 10 m and the colorimetric sensing ability for visual recognition under visible or UV-A light w enhanced.Sinsinbar et al. [42] reported a color change-based OmpT substrate-polythiophene assay for the detection of E. coli in contaminated water samples (Figure 7).This assay uses the cleavage ability of the protease (OmpT) at the double base site of the peptide to bind the substrate peptide of OmpT to polythiophene whose optical properties change with the cleavage of the peptide.E. coli at levels of 1-10 and 10 5 CFU/mL were detected within 5.5 and 1 h, respectively.By optimizing the carboxylic acid side chain length of carboxylate functional polythiophene and the peptide substrate of OmpT, the detection time for E. coli in highly contaminated samples was reduced from the already short 1 h to only 10 min, and the colorimetric sensing ability for visual recognition under visible or UV-A light was enhanced.Sinsinbar et al. [42] reported a color change-based OmpT substrate-polythiophene assay for the detection of E. coli in contaminated water samples (Figure 7).This assay uses the cleavage ability of the protease (OmpT) at the double base site of the peptide to bind the substrate peptide of OmpT to polythiophene whose optical properties change with the cleavage of the peptide.E. coli at levels of 1-10 and 10 5 CFU/mL were detected within 5.5 and 1 h, respectively.By optimizing the carboxylic acid side chain length of carboxylate functional polythiophene and the peptide substrate of OmpT, the detection time for E. coli in highly contaminated samples was reduced from the already short 1 h to only 10 min, and the colorimetric sensing ability for visual recognition under visible or UV-A light was enhanced.Reprinted with permission from ref. [42].Copyright 2022 American Chemical Society.Yuan et al. [43] explored a hybrid biomimetic hydrogel based on spiral polyisocyanate and conformation-sensitive conjugated polythiophene (Figure 8).The hybrid gel uses helical triethylene glycol functionalized polyisocyanate (PIC) as a scaffold to capture and stretch the conformation-sensitive PMNT chains so that the PMNT is arranged into a highly ordered planar conformation.Thus, new absorption bands and redshifts are generated in absorption and emission spectra, respectively.PMNT/PIC hybrid hydrogels exhibit higher ROS production in random conformation than single PMNT and thus have more efficient photodynamic antibacterial activity.PMNT/PIC hybrid hydrogels retain a few of the mechanical properties of natural PIC strain hardening, which is very close to the mechanical properties of biogels such as collagen and fibrin.In addition, the hybrid hydrogels have good biocompatibility, so this PMNT/PIC hybrid material is expected to be used as wound dressings in the treatment of inner infections.Zhou et al.

Conjugated Polymers for Therapeutic Applications
[44] prepared a unique conjugated polymer (PTB-APFB) containing tetra pheny ethylene unit with aggregate induced emission (AIE) (Figure 9).Due to the donor π-acceptor (D-π-A) structure, the polymer has a higher ROS generation capacity than th commercial photosensitizer chlorin e6.In addition, the selective binding of PTB-APFB to pathogenic microbes rather than mammalian cells demonstrated its biocompatibility.In vitro and in vivo experiments further showed that the polymer could efficiently inhibi bacterial reproduction and photodynamic killing under light irradiation, and its recovery rate for bacterial infection is faster than cephalosporin, and could effectively enhance th healing of infected wounds.Based on this, this polymer is expected to be an antibacteria drug for preclinical research and clinical application in the practical application of treating

Zhou et al.
[44] prepared a unique conjugated polymer (PTB-APFB) containing tetrapheny ethylene unit with aggregate induced emission (AIE) (Figure 9).Due to the donor-πacceptor (D-π-A) structure, the polymer has a higher ROS generation capacity than the commercial photosensitizer chlorin e6.In addition, the selective binding of PTB-APFB to pathogenic microbes rather than mammalian cells demonstrated its biocompatibility.In vitro and in vivo experiments further showed that the polymer could efficiently inhibit bacterial reproduction and photodynamic killing under light irradiation, and its recovery rate for bacterial infection is faster than cephalosporin, and could effectively enhance the healing of infected wounds.Based on this, this polymer is expected to be an antibacterial drug for preclinical research and clinical application in the practical application of treating bacterial infections.Zhao et al. [45] developed a 3D printable artificial hydrogel skin patch Gel/Alg/HA-A5G81/PPV comprised of natural biological macromolecules, including gelatin (Gel), alginate (Alg), and hyaluronic acid (HA), and a photoactive cationic conjugated polymer (PPV) (Figure 10).The antibacterial dressing has negligible cytotoxicity, good visible light absorption ability, strong electrostatic adsorption, and excellent adhesion ability so the artificial skin patch has good advantages of PDT against S. aureus infection in vitro and in vivo.In comparison with previously reported hydrogel-based dressings, the skin patch prepared in this work has comprehensive antibacterial ability, tissue regeneration ability, and rich microstructure, and is more suitable for skin equivalent in the event of skin trauma, contributing to the development of regenerative medicine.3.1.2.Photothermal Therapy (PTT) Z. Yin et al. [46] reported a supramolecular polymerization driven by E. coli reduction to prepare a near-infrared (NIR) in situ photothermal antimicrobial agent (Figure 11).The Zhao et al. [45] developed a 3D printable artificial hydrogel skin patch Gel/Alg/HA-A5G81/PPV comprised of natural biological macromolecules, including gelatin (Gel), alginate (Alg), and hyaluronic acid (HA), and a photoactive cationic conjugated polymer (PPV) (Figure 10).The antibacterial dressing has negligible cytotoxicity, good visible light absorption ability, strong electrostatic adsorption, and excellent adhesion ability so the artificial skin patch has good advantages of PDT against S. aureus infection in vitro and in vivo.In comparison with previously reported hydrogel-based dressings, the skin patch prepared in this work has comprehensive antibacterial ability, tissue regeneration ability, and rich microstructure, and is more suitable for skin equivalent in the event of skin trauma, contributing to the development of regenerative medicine.Zhao et al. [45] developed a 3D printable artificial hydrogel skin patch Gel/Alg/HA-A5G81/PPV comprised of natural biological macromolecules, including gelatin (Gel), alginate (Alg), and hyaluronic acid (HA), and a photoactive cationic conjugated polymer (PPV) (Figure 10).The antibacterial dressing has negligible cytotoxicity, good visible light absorption ability, strong electrostatic adsorption, and excellent adhesion ability so the artificial skin patch has good advantages of PDT against S. aureus infection in vitro and in vivo.In comparison with previously reported hydrogel-based dressings, the skin patch prepared in this work has comprehensive antibacterial ability, tissue regeneration ability, and rich microstructure, and is more suitable for skin equivalent in the event of skin trauma, contributing to the development of regenerative medicine.3.1.2.Photothermal Therapy (PTT) Z. Yin et al. [46] reported a supramolecular polymerization driven by E. coli reduction to prepare a near-infrared (NIR) in situ photothermal antimicrobial agent (Figure 11).The Z. Yin et al. [46] reported a supramolecular polymerization driven by E. coli reduction to prepare a near-infrared (NIR) in situ photothermal antimicrobial agent (Figure 11).The antimicrobial agent contains two bifunctional monomers (VDV) of purpurin fragments.When the bifunctional monomer is cultured with cucurbituril (CB [8]), E. coli can reduce the purpurin fragments to purpurin cationic free radicals.A supramolecular polymer (VR-SP) was prepared on the surface of E. coli, which integrated the supramolecular dimer of violet cation radical into the main chain.The NIR photothermal conversion property of the strong free radical supramolecular dimer gives VR-SP photothermal antibacterial ability and further improves the photothermal antibacterial performance through the local enrichment of the supramolecular polymer and enhanced adsorption on the bacterial surface.In addition, only specific bacteria, such as E. coli, have the reducing capability to promote supramolecular polymerization, while many others, such as B. subtilis, P. aeruginosa, and S. aureus, do not possess this capacity.Therefore, under the NIR radiation of 1064 nm, the inhibitory effect of the supramolecular polymer on E. coli was significant (>99.9%), with high specificity.This biodynamic in-situ supramolecular polymerization strategy has great potential for manufacturing intelligent biomedical supramolecular materials with adaptive and programmable properties.Zhang et al. [47] designed and synthesized a cationic conjugated polymer (PDTPBT) based on a D-A structure, which was composed of dithieno[3,2-b:2′,3′-d]pyrrole (DTP) as electron donor and benzothiadiazole as electron acceptor, respectively, which was used for photothermal antimicrobial treatment under NIR light.In PDTPBT polymer (Figure 12), QAS groups are modified on the side chain to improve the water solubility and effectively promote the electrostatic binding with bacteria.PDTPBT has strong NIR absorption performance, good light stability, and high photothermal conversion efficiency (PCE) of up to 71.1%.Therefore, the novel cationic conjugated polymer PDTPBT has good photothermal properties and high antibacterial ability, which gives a viable strategy for the development of organic photothermal agents and the biomedical applications of NIR light sterilization.Zhang et al. [47] designed and synthesized a cationic conjugated polymer (PDTPBT) based on a D-A structure, which was composed of dithieno[3,2-b:2 ,3 -d]pyrrole (DTP) as electron donor and benzothiadiazole as electron acceptor, respectively, which was used for photothermal antimicrobial treatment under NIR light.In PDTPBT polymer (Figure 12), QAS groups are modified on the side chain to improve the water solubility and effectively promote the electrostatic binding with bacteria.PDTPBT has strong NIR absorption performance, good light stability, and high photothermal conversion efficiency (PCE) of up to 71.1%.Therefore, the novel cationic conjugated polymer PDTPBT has good photothermal properties and high antibacterial ability, which gives a viable strategy for the development of organic photothermal agents and the biomedical applications of NIR light sterilization.PTT based on CPs is a promising antimicrobial strategy, but it may still have some disadvantages such as difficult degradation.Zhou et al. [48] designed a biodegradable pseudo-conjugated polymer (pCPs) comprised of a photothermal molecular skeleton and ROS-sensitive thioketone bond (Figure 13).Triphenylphosphine (PPh3) was connected to PCP to form phosphonium-based PCPs (pPCPs), followed by electrostatically combining with hyaluronic acid to obtain pPCP nanoparticles (pPCP-NPs).pPCP-NPs with phosphonium cation can specifically anchor bacterial cell membranes through electrostatic interaction and have a certain destructive effect.In addition, under 1064 nm laser irradiation, pPCP-NPs produces NIR-Ⅱ region (1000-1700 nm) photothermal antibacterial effects, thus killing pathogens continuously.Compared with photothermal agents with excitation wavelength in near-infrared region I (NIR-I: 650-950 nm) and antibacterial agents without quaternary ammonium salt modification, the coordination of NIR-II photothermal agent and the cation of phosphonium salt have better antibacterial effect, the inhibition rate against both of S. aureus and E. coli in vitro is close to 100%, and the repair effect of infection in vivo is also very satisfying.pPCP-NPs can be degraded in vivo by a lot of ROS present at the infection site, which enhances its biosafety.Further metabolomic analysis showed that pPCP-NPs with the aid of NIR light induced bacterial DNA damage and inhibited bacterial carbon/nitrogen utilization and amino acid/nucleotide synthesis.Therefore, the biodegradable pPCP-NPs with photothermal effect and quaternary phosphonium salt anchored bacteriostatic effect propose an alternative way to replace antibiotics.PTT based on CPs is a promising antimicrobial strategy, but it may still have some disadvantages such as difficult degradation.Zhou et al. [48] designed a biodegradable pseudo-conjugated polymer (pCPs) comprised of a photothermal molecular skeleton and ROS-sensitive thioketone bond (Figure 13).Triphenylphosphine (PPh 3 ) was connected to PCP to form phosphonium-based PCPs (pPCPs), followed by electrostatically combining with hyaluronic acid to obtain pPCP nanoparticles (pPCP-NPs).pPCP-NPs with phosphonium cation can specifically anchor bacterial cell membranes through electrostatic interaction and have a certain destructive effect.In addition, under 1064 nm laser irradiation, pPCP-NPs produces NIR-II region (1000-1700 nm) photothermal antibacterial effects, thus killing pathogens continuously.Compared with photothermal agents with excitation wavelength in near-infrared region I (NIR-I: 650-950 nm) and antibacterial agents without quaternary ammonium salt modification, the coordination of NIR-II photothermal agent and the cation of phosphonium salt have better antibacterial effect, the inhibition rate against both of S. aureus and E. coli in vitro is close to 100%, and the repair effect of infection in vivo is also very satisfying.pPCP-NPs can be degraded in vivo by a lot of ROS present at the infection site, which enhances its biosafety.Further metabolomic analysis showed that pPCP-NPs with the aid of NIR light induced bacterial DNA damage and inhibited bacterial carbon/nitrogen utilization and amino acid/nucleotide synthesis.Therefore, the biodegradable pPCP-NPs with photothermal effect and quaternary phosphonium salt anchored bacteriostatic effect propose an alternative way to replace antibiotics.

Synergistic Antibacterial Therapy
The effect of photodynamic or photothermal treatment alone is affected by low oxygen concentration or high temperature, respectively, and the effect of synergistic treatment through multiple methods is much stronger than that of using one method alone [73][74][75].Xiao et al. [49] developed a broad-spectrum polymer antimicrobial agent PEoS-PHMG, which achieves dual-mode antibacterial effects through a combination of photodynamic inactivation and physical damage (Figure 14).A typical commercial cationic antimicrobial agent (PHMG) was selected to be linked in the polymer, which quickly adsorbed to the negatively charged cell surface through electrostatic action and damaged the cell membrane by increasing the permeability of the cell plasma membrane to the site to form local pores for intracellular components leaking and eventually led to physical damage and bacterial death [76,77].This damage is beneficial to avoid causing bacterial drug resistance [78,79].In addition, PHMG also has excellent photodynamic bactericidal ability, with a dual antibacterial mechanism to effectively kill a broad spectrum of bacteria.PHMG is then combined with Eosin-Y (EoS) to obtain polymer P(DMAEMA-co-EoS), followed by copolymerization with 2-(dimethylamino) ethyl methacrylate to obtain a new antibacterial polymer agent PEoS-PHMG.Compared with single PHMG, conjugated functionalized PHMG shows enhanced biocompatibility and good bacterial inhibition.Therefore, functionalized PHMG is a prospective strategy for the exploration of novel polymer photodynamic antimicrobials.

Synergistic Antibacterial Therapy
The effect of photodynamic or photothermal treatment alone is affected by gen concentration or high temperature, respectively, and the effect of synergis ment through multiple methods is much stronger than that of using one meth [73][74][75].Xiao et al. [49] developed a broad-spectrum polymer antimicrobial age PHMG, which achieves dual-mode antibacterial effects through a combination dynamic inactivation and physical damage (Figure 14).A typical commercial cat timicrobial agent (PHMG) was selected to be linked in the polymer, which qu sorbed to the negatively charged cell surface through electrostatic action and d the cell membrane by increasing the permeability of the cell plasma membrane t   15).When ROS is present, protective heat shock proteins at high temperatures are inhibited by biochemical reactions [80,81] in other words, the production of ROS reduces the cell heat tolerance and thus achieves high-temperature sterilization.To adjust the dissipation of excitation energy, excellent synergistic antibacterial phototherapy is achieved.Tph-type photosensitizers have good light collection ability, produce ROS through electron and energy transfer, and generate heat from molecular vibration under light.However, the strong absorption of Tph is mainly at 400-450 nm, and effective photothermal production requires strong absorption in the NIR region.The absorption band of BDP itself is in the visible light range, but the photophysical properties will change greatly after modification.Therefore, combining the modified BDP unit with the Tph derivative to form a high-porosity COF structure that facilitates oxygen infiltration and ROS release enabling excellent Vis-NIR absorption, which in turn generates ROS and heat.Compared with the two mono-molecules, the large redshift absorption band in the NIR region of the composite proves that the NIR absorption is obtained due to the strong charge transfer (CT) interaction of COF.In addition, the composite conjugated polymer has a narrow optical band gap (1.33 eV) and rapid energy and electron transfer, which greatly promotes the ISC process and improves the photothermal conversion efficiency, and the integration of multiple antibacterial mechanisms can shorten the antibacterial time and improve the antibacterial efficiency.By photodynamic and photothermal treatment, Tph-BDP-COF showed highly efficient light-induced synergistic antibacterial properties (97%).These results not only provide inspiration for the design of new synergistic therapy photosensitizers under the guidance of Jablonski, but also provide hope for further exploration of excited state dynamic control of phototherapeutic materials.

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transfer, which greatly promotes the ISC process and improves the photothermal conversion efficiency, and the integration of multiple antibacterial mechanisms can shorten the antibacterial time and improve the antibacterial efficiency.By photodynamic and photothermal treatment, Tph-BDP-COF showed highly efficient light-induced synergistic antibacterial properties (97%).These results not only provide inspiration for the design of new synergistic therapy photosensitizers under the guidance of Jablonski, but also provide hope for further exploration of excited state dynamic control of phototherapeutic materials.In the context of the COVID-19 pandemic, face masks are considered important personal protective equipment to prevent the spread of the viruses.However, pathogens can survive on the fabric of commercial masks for several days, which increases the risk of direct/indirect transmission.Wang et al. [51] developed a novel cationic conjugated microporous polymer (CCMPs) coating containing an extended π-conjugated backbone and a large number of QAS groups with dual-mode antimicrobial activity containing photodynamic sterilization by ROS and contact sterilization by QAS groups (Figure 16).The CCMPs coating can quickly and effectively eradicate 99% of representative microorganisms such as E. coli and S. aureus under sunlight and also guarantees good antibacterial effects in the dark.Moreover, CCMPs coating displays superior durability, reusability, and antimicrobial stability in wet environments.Due to their excellent figurability, CCMPs can be synthesized in situ and coated onto the fibers by simply spraying.Therefore, the strategy offers new thinking for exploring reusable and self-disinfecting antibacterial textiles, especially for use in masks for daily and medical protection to combat pathogens and viruses.In the context of the COVID-19 pandemic, face masks are considered important personal protective equipment to prevent the spread of the viruses.However, pathogens can survive on the fabric of commercial masks for several days, which increases the risk of direct/indirect transmission.Wang et al. [51] developed a novel cationic conjugated microporous polymer (CCMPs) coating containing an extended π-conjugated backbone and a large number of QAS groups with dual-mode antimicrobial activity containing photodynamic sterilization by ROS and contact sterilization by QAS groups (Figure 16).The CCMPs coating can quickly and effectively eradicate 99% of representative microorganisms such as E. coli and S. aureus under sunlight and also guarantees good antibacterial effects in the dark.Moreover, CCMPs coating displays superior durability, reusability, and antimicrobial stability in wet environments.Due to their excellent figurability, CCMPs can be synthesized in situ and coated onto the fibers by simply spraying.Therefore, the strategy offers new thinking for exploring reusable and self-disinfecting antibacterial textiles, especially for use in masks for daily and medical protection to combat pathogens and viruses.

Photodynamic Antitumor Therapy
Huang et al. [52] proposed a photosensitizer (PS) for type I PDT based on a self-degrading CP, which consists of triphenylamine and imidazole units (CP1) (Figure 17).As mentioned in the introduction, the type I photodynamic process mainly produces ROS of free radicals, which is less dependent on oxygen than the type II PDT process which produces ROS of 1 O2, thus alleviating the problem of hypoxic microenvironment in the treatment area [82].Owing to the conjugated backbone and unique AIE properties, the resulting polymer could efficiently produce superoxide free radicals (O2 −• ) via a type I way under light, making it desirable for the treatment of hypoxic tumors.Furthermore, the production of O2 −• from CP1 could further cause the polymers to self-degrade and form nontoxic micromolecules.This not only aids in solving the problem of potential phototoxicity of residual PS, but also improves the metabolism of CPs and decreases the possible biological toxicity of drug accumulation.This self-degrading type I PS can shut down ROS production timely after photodynamic treatment, giving a new insight for balancing photodynamic effects and postoperative safety.

Antitumor Application 3.2.1. Photodynamic Antitumor Therapy
Huang et al. [52] proposed a photosensitizer (PS) for type I PDT based on a selfdegrading CP, which consists of triphenylamine and imidazole units (CP1) (Figure 17).As mentioned in the introduction, the type I photodynamic process mainly produces ROS of free radicals, which is less dependent on oxygen than the type II PDT process which produces ROS of 1 O 2 , thus alleviating the problem of hypoxic microenvironment in the treatment area [82].Owing to the conjugated backbone and unique AIE properties, the resulting polymer could efficiently produce superoxide free radicals (O 2 −• ) via a type I way under light, making it desirable for the treatment of hypoxic tumors.Furthermore, the production of O 2 −• from CP1 could further cause the polymers to self-degrade and form non-toxic micromolecules.This not only aids in solving the problem of potential phototoxicity of residual PS, but also improves the metabolism of CPs and decreases the possible biological toxicity of drug accumulation.This self-degrading type I PS can shut down ROS production timely after photodynamic treatment, giving a new insight for balancing photodynamic effects and postoperative safety.
In the same year, Huang et al. [53] designed a nanoparticle assembled by self-degrading conjugated polyelectrolyte (CP + ) followed by loading immune adjuvant (CpG) to obtain CP + -CpG NPs for the coordination of PDT and immunotherapy (Figure 18).During the PDT process, ROS can cause endoplamic reticulum oxidative stress and lead to immunogenic cell death (ICD).Nevertheless, most PDT-caused ICDs could not generate sufficient anti-tumor immune responses to inhibit tumor metastasis.CP + -CpG NPs could efficiently produce O 2 −• under light irradiation via the type I PDT way which is ideal for combating tumors in hypoxic conditions.Meanwhile, CP + -CpG NPs could be degraded by self-produced O 2 −• , thereby releasing CpG which could further enhance PDT-caused ICD, activate an immune response, and bring about the entire body's immune anti-tumor reactions.The new strategy enhances the effect of PDT and induces immunotherapy, which holds great promise in future cancer treatment.
der light, making it desirable for the treatment of hypoxic tumors.Furthermore, the production of O2 −• from CP1 could further cause the polymers to self-degrade and form nontoxic micromolecules.This not only aids in solving the problem of potential phototoxicity of residual PS, but also improves the metabolism of CPs and decreases the possible biological toxicity of drug accumulation.This self-degrading type I PS can shut down ROS production timely after photodynamic treatment, giving a new insight for balancing photodynamic effects and postoperative safety.In the same year, Huang et al. [53] designed a nanoparticle assembled by self-degra ing conjugated polyelectrolyte (CP + ) followed by loading immune adjuvant (CpG) to o tain CP + -CpG NPs for the coordination of PDT and immunotherapy (Figure 18).Duri the PDT process, ROS can cause endoplamic reticulum oxidative stress and lead to imm nogenic cell death (ICD).Nevertheless, most PDT-caused ICDs could not generate suf cient anti-tumor immune responses to inhibit tumor metastasis.CP + -CpG NPs could ef ciently produce O2 −• under light irradiation via the type I PDT way which is ideal for co bating tumors in hypoxic conditions.Meanwhile, CP + -CpG NPs could be degraded self-produced O2 −• , thereby releasing CpG which could further enhance PDT-caused IC activate an immune response, and bring about the entire body's immune anti-tumor rea tions.The new strategy enhances the effect of PDT and induces immunotherapy, whi holds great promise in future cancer treatment.The effect of PDT is restricted by hypoxic tumors, which are closely associated w tumor vascular abnormalities that promote immune evasion.Thus, tumor vascular stan ardization is considered a prospective method to surmount tumor hypoxia and thus i prove tumor treatment.Wan et al. [54] reported a NIR-II-absorbing biodegradab pseudo-conjugated polymer-based photodynamic material (PSP) to deliver a vascu The effect of PDT is restricted by hypoxic tumors, which are closely associated with tumor vascular abnormalities that promote immune evasion.Thus, tumor vascular standardization is considered a prospective method to surmount tumor hypoxia and thus improve tumor treatment.Wan et al. [54] reported a NIR-II-absorbing biodegradable pseudo-conjugated polymer-based photodynamic material (PSP) to deliver a vascular normalizer (Reg) resulting in nanoparticles (NP-PDT@Reg) (Figure 19).Reg can be effectively released from NP-PDT@Reg under NIR light to improve hypoxia in tumors through vascular standardization, allowing more nanoparticles and oxygen to enter the tumor.In addition, NP-PDT@Reg with the aid of NIR light could further lead to the production of more ROS to eliminate tumor cells and induce ICD to stimulate immune responses for anti-tumor.

Photothermal Antitumor Therapy
Yu et al. [55] synthesized a new series of biodegradable polymers containing a flexible structure with disulfide bonds that can be cleaved by glutathione (GSH) which is the most abundant in animal cells.These biodegradable polymers are prepared through the Stille polymerization of conjugated monomers containing tin (M1) and monomers containing bromine (M2a, M2b, and M3).In such systems, the conjugated part gives the polymers photothermal conversion capability, while the biodegradable non-conjugated part gives the system biosafety.This design strategy provides inspiration for the development of effective photothermal agents (Figure 20).Li et al. [56] reported a porphyrin polymer (P-PPor) with a D-A structure (Figure 21).P-PPor exhibits strong absorption in the NIR-I region and emits significant fluorescence in the NIR-II region with a quantum yield of 2.19%.Because of the hydrophilic PEG chains and hydrophobic alkyls in the conjugated backbone, amphiphilic P-PPor can form well water-dispersed nanoparticles (P-PPor NPs) via self-assembly with improved absorption in the NIR region.In addition, P-PPor NPs displayed quenching fluorescence due to the aggregation-caused quenching (ACQ) effect, and the photothermal effect was produced and remarkably enhanced.Under 808 nm laser irradiation, P-PPor NPs have a high PCE of 66%.The excellent photothermal efficacy of P-PPor NPs was further verified by the 4T1 tumor model.At the same time, in vivo NIR-II fluorescence imaging showed a high distribution of P-PPor NPs at the tumor site.It is indicated that P-PPor NPs can efficiently kill mouse tumor cells under NIR light without obvious side effects.Therefore, P-PPor NPs can be utilized as a promising drug for the photothermal treatment of tumors with high safety and effectiveness.and remarkably enhanced.Under 808 nm laser irradiation, P-PPor NPs have a high PCE of 66%.The excellent photothermal efficacy of P-PPor NPs was further verified by the 4T1 tumor model.At the same time, in vivo NIR-II fluorescence imaging showed a high distribution of P-PPor NPs at the tumor site.It is indicated that P-PPor NPs can efficiently kill mouse tumor cells under NIR light without obvious side effects.Therefore, P-PPor NPs can be utilized as a promising drug for the photothermal treatment of tumors with high safety and effectiveness.Zhang et al. [57] prepared a novel D-A conjugated polymer PDPPDTP based on a pyrrole derivative as the electron-donating unit and a pyrrole-1,4-dione derivative as the electron-accepting unit (Figure 22).The obtained polymer has strong absorption in the NIR-I range and exhibits effective photothermal properties under 808 nm laser irradiation.The biodegradable amphiphilic polymer polyethylene glycol polycaprolactone (PEG-PCL) was utilized to wrap the novel PDPPDTP into nano-micelles.The nano-micelles have excellent biocompatibility and low cytotoxicity, and can efficiently restrain the proliferation of 4T1 cells under 808 nm light irradiation.In addition, in vivo photothermal treatment indicated that nano-micelles loaded PDPPDTP displayed significant tumor growth inhibition in isogenic mouse tumor models, demonstrating its potential as a novel therapeutic drug.Zhang et al. [57] prepared a novel D-A conjugated polymer PDPPDTP based on a pyrrole derivative as the electron-donating unit and a pyrrole-1,4-dione derivative as the electron-accepting unit (Figure 22).The obtained polymer has strong absorption in the NIR-I range and exhibits effective photothermal properties under 808 nm laser irradiation.The biodegradable amphiphilic polymer polyethylene glycol polycaprolactone (PEG-PCL) was utilized to wrap the novel PDPPDTP into nano-micelles.The nano-micelles have excellent biocompatibility and low cytotoxicity, and can efficiently restrain the proliferation of 4T1 cells under 808 nm light irradiation.In addition, in vivo photothermal treatment indicated that nano-micelles loaded PDPPDTP displayed significant tumor growth inhibition in isogenic mouse tumor models, demonstrating its potential as a novel therapeutic drug.

Synergistic Antitumor Therapy
Companion diagnostics (CDx) can provide vital information for precision medicine, but currently, CDx with imaging function is rare and limited to in vitro trials, which cannot accurately assess disease progression and treatment response in real-time.To solve this problem, Wu et al. [58] reported a glucose oxidase (GOx) modified conjugated polymer nanoparticle (PANITG) for acid-activated photoacoustic (PA) imaging CDx and mul-

Synergistic Antitumor Therapy
Companion diagnostics (CDx) can provide vital information for precision medicine, but currently, CDx with imaging function is rare and limited to in vitro trials, which cannot accurately assess disease progression and treatment response in real-time.To solve this problem, Wu et al. [58] reported a glucose oxidase (GOx) modified conjugated polymer nanoparticle (PANITG) for acid-activated photoacoustic (PA) imaging CDx and multistage enhanced synergistic photothermal/starvation treatment of tumors (Figure 23).PANITG is composed of polyaniline (PANI), GOx, and thioketal (TK) linkers that can be cut by H 2 O 2 .PANI synthesized by traditional methods has poor water solubility and poor dedoping resistance in the tumor microenvironment.Therefore, this work adopts the first oxidation of polyaniline.It is then combined with FeCl 3 biomineralized bovine serum albumin complex to form PANI NPs, and GOx is modified on its surface by TK linker.The protonated emerald salt (ES) of PANI NPs has strong absorption in the NIR light region under an acidic environment due to its pH-dependent electrochromic properties.In neutral or alkaline environments, its deprotonated emerald (EB) has low NIR light absorption and can be used as a PA imaging "switch" to distinguish between diseased and normal tissue.PANI NPs can also produce a photothermal effect, and local hyperthermia can lead to tumor ablation.Activated PTT can avoid non-specific overheating of surrounding normal tissues during phototherapy.However, the pH changes in the tumor microenvironment were relatively weak compared with normal tissues (H 2 O 2 content increased ≈ 0.1 × 10 −6 M, pH decreased to pH = 6.5-6.8),so the photothermal treatment effect of PANI NPs alone was limited.When PANITG combined with GOx catalyzes glucose oxidation, it can not only compete with cancer cells for glucose demand, but also induce cancer starvation therapy.At the same time, the oxidation reaction product glutamic acid enhances the acidity of the tumor microenvironment, and the oxidation product H 2 O 2 can cut the TK linker and release GOx.The enhanced acidic environment enhances the catalytic activity of free GOx, further enhancing the acidity of the tumor environment and the consumption of glucose, and the reduction of pH enhances the effect of PA, PTT, and starvation therapy.Compared with free GOx, the activity of GOx on PANITG is inhibited, so it does not cause toxicity to normal cells.Only in the tumor microenvironment does H 2 O 2 release TK linker after cutting to restore its catalytic glucose oxidation activity, and further realizes starvation therapy to kill tumor cells.Therefore, PANITG has good tumor treatment selectivity and biocompatibility.In vivo anti-tumor experiments showed that PANITG achieved tumor ablation in mice for 14 days under NIR light, but had no effect on normal tissue.Overall, in vivo PAI and photothermal therapeutics are stimulated by the acidic microenvironment in tumors and self-enhanced by the reaction of GOx with glucose.Meanwhile, the photothermal effect will improve GOx activity, and this multi-stage enhanced therapeutic effect effectively promotes cancer management.In addition, the signal brightness of PANITG in vivo PAI shows the pH of the tumor, which correlates with the efficacy of PTT, and the catalytic activity of GOx at various stages, thus revealing pH-activated/enhanced PTT and GOx-mediated starvation therapy progression, enabling reactivable real-time CDx.
Conductive polymers have strong NIR absorption and have received extensive attention to developing smart nanoplatform for anti-tumor therapy, especially photothermal chemotherapy.Nevertheless, due to the non-degradability of conductive polymers, their long-term biosafety in vivo is unknown, which hinders their clinical application.Liu et al. [59] synthesized a polypyrrole derivative that is degradable by H 2 O 2 -triggering, and the corresponding nanoparticles are prepared with the stabilization of polyacrylic acid (PAA) to obtain PAA@PPyCOOH which has good dispersibility, biocompatibility and high PCE (56%) (Figure 24).Subsequently, nanoparticles (PAA@PPyCOOH@DOX) were formed with the addition of doxorubicin (DOX) for precise synergistic chemo-PTT.PAA@PPyCOOH@DOX releases DOX in the acidic and H 2 O 2 overexpressed microenvironment in dual response, resulting in an excellent chemical photothermal treatment effect.PAA@PPyCOOH could be degraded through the ring-opening reaction of the pyrrolo-3carboxyl unit in the presence of H 2 O 2 .When nanoparticles are selectively decomposed by excess H 2 O 2 in tumors, their decomposition products can be eliminated through urine and feces.The anti-tumor results of chemotherapy-PTT in vivo showed that tumor growth was significantly restrained, and no obvious side effects were found, which has great clinical application potential.
PANITG achieved tumor ablation in mice for 14 days under NIR light, but had no effect on normal tissue.Overall, in vivo PAI and photothermal therapeutics are stimulated by the acidic microenvironment in tumors and self-enhanced by the reaction of GOx with glucose.Meanwhile, the photothermal effect will improve GOx activity, and this multistage enhanced therapeutic effect effectively promotes cancer management.In addition, the signal brightness of PANITG in vivo PAI shows the pH of the tumor, which correlates with the efficacy of PTT, and the catalytic activity of GOx at various stages, thus revealing pH-activated/enhanced PTT and GOx-mediated starvation therapy progression, enabling reactivable real-time CDx.Conductive polymers have strong NIR absorption and have received extensive attention to developing smart nanoplatform for anti-tumor therapy, especially photothermal chemotherapy.Nevertheless, due to the non-degradability of conductive polymers, their long-term biosafety in vivo is unknown, which hinders their clinical application.Liu et al. [59] synthesized a polypyrrole derivative that is degradable by H2O2-triggering, and the corresponding nanoparticles are prepared with the stabilization of polyacrylic acid (PAA) to obtain PAA@PPyCOOH which has good dispersibility, biocompatibility and high PCE (56%) (Figure 24).Subsequently, nanoparticles (PAA@PPyCOOH@DOX) were Low-temperature PTT overcomes the disadvantages of traditional PTT such as poor heat tolerance, and the expression of heat shock proteins (HSPs) can significantly affect the treatment effect of PTT.Therefore, preventing the repair of heat shock proteins and reducing the damage of nearby normal cells is the key to improving the efficiency of lowtemperature PTT.Ma et al. [60] developed a self-assembled nanobomb based on NIR-II polymer PBPTV and carbon monoxide (CO) carrier polymer mPEG(CO) (Figure 25).The smart nano-bomb could explode in the tumor microenvironment with overexpression of H 2 O 2 and release CO into tumor cells, thus efficiently inhibiting the expression of HSPs and improving the anti-tumor effects of low-temperature PTT.This method provides an ideal strategy for the development of tumor hypothermia therapy and exhibits great potential in clinical practice.
fect.PAA@PPyCOOH could be degraded through the ring-opening reaction of the rolo-3-carboxyl unit in the presence of H2O2.When nanoparticles are selectively dec posed by excess H2O2 in tumors, their decomposition products can be eliminated thro urine and feces.The anti-tumor results of chemotherapy-PTT in vivo showed that tu growth was significantly restrained, and no obvious side effects were found, which great clinical application potential.Low-temperature PTT overcomes the disadvantages of traditional PTT such as heat tolerance, and the expression of heat shock proteins (HSPs) can significantly a the treatment effect of PTT.Therefore, preventing the repair of heat shock proteins reducing the damage of nearby normal cells is the key to improving the efficiency of

Detection and Treatment of Pathogenic Microorganisms
The effective integration of precise tracking and on-demand sterilization for control of pathogenic bacteria is of great significance to be explored.Ye et al. [61] re a stimulus-responsive nanoprobe PDANSs-FAM-Apt for the detection of S. aureu single-cell level and direct photothermal killing of S. aureus and its biofilm und light (Figure 26).Polydopamine nanospheres (PDANSs), which are used for FRET tors due to their wide absorption bands, are connected to the S. aureus aptamer m with the FRET donor 6-carboxyfluorescein (FAM-Apt) via π-π stacking interaction tain probe PDANSs-FAM-Apt, and the fluorescence of the donor is quenched.Ho in the presence of S. aureus that specifically absorbs the aptamer, the π-π accumul reduced, and the FRET between PDANSs and FAM-Apt is broken, followed by th rescence recovery of FAM-Apt to realize the sensitive detection of S. aureus.Subseq the nanosphere size is adjusted to maximize the FRET efficiency according to the d ence of FRET efficiency on the size of PDANSs, thus maximizing the sensitivity probe.The results showed that the probe displayed significant fluorescence enhan (261 times) for S. aureus, and the detection limit was 1.0 CFU/mL, enabling the de of pathogens at the single-cell level and ultra-low background fluorescence imag addition, due to the high photothermal conversion efficiency of PDANSs, the pr hibits high photothermal bactericidal performance under NIR light irradiation an strong killing ability against S. aureus and its biofilm under the guidance of imagin work emphasizes the versatility of the combination of stimulus-response fluoresce aging and NIR light-activated photothermal antibacterial activity, which can be u  The effective integration of precise tracking and on-demand sterilization for source control of pathogenic bacteria is of great significance to be explored.Ye et al. [61] reported a stimulus-responsive nanoprobe PDANSs-FAM-Apt for the detection of S. aureus at the single-cell level and direct photothermal killing of S. aureus and its biofilm under NIR light (Figure 26).Polydopamine nanospheres (PDANSs), which are used for FRET receptors due to their wide absorption bands, are connected to the S. aureus aptamer modified with the FRET donor 6-carboxyfluorescein (FAM-Apt) via π-π stacking interactions to obtain probe PDANSs-FAM-Apt, and the fluorescence of the donor is quenched.However, in the presence of S. aureus that specifically absorbs the aptamer, the π-π accumulation is reduced, and the FRET between PDANSs and FAM-Apt is broken, followed by the fluorescence recovery of FAM-Apt to realize the sensitive detection of S. aureus.Subsequently, the nanosphere size is adjusted to maximize the FRET efficiency according to the dependence of FRET efficiency on the size of PDANSs, thus maximizing the sensitivity of the probe.The results showed that the probe displayed significant fluorescence enhancement (261 times) for S. aureus, and the detection limit was 1.0 CFU/mL, enabling the detection of pathogens at the single-cell level and ultra-low background fluorescence imaging.In addition, due to the high photothermal conversion efficiency of PDANSs, the probe exhibits high photothermal bactericidal performance under NIR light irradiation and has a strong killing ability against S. aureus and its biofilm under the guidance of imaging.This work emphasizes the versatility of the combination of stimulus-response fluorescence imaging and NIR light-activated photothermal antibacterial activity, which can be used for pathogen monitoring and source control, opening up a practical anti-fouling pathway for the elimination of bacteria and destruction of bacterial biofilms.
pathogen monitoring and source control, opening up a practical anti-fouling pathway for the elimination of bacteria and destruction of bacterial biofilms.Su et al. [62] synthesized a series of functional conjugated polymer poly(phenyleneethynylene) (PPE) derivatives containing diethylamino-substituted tetraphenylethene units, with typical AIE properties (Figure 27).PPE nanoparticles based on hydrophobic structure have good cellular uptake capacity and can clearly and sensitively observe the presence of bacteria through fluorescence and Raman signals, respectively.After functionalization, the obtained cationic PPE can preferentially image bacteria rather than mammalian cells and has excellent photodynamic inactivation ability toward G + bacteria and drug-resistant bacteria.This report gives a viable strategy for the exploration of functional CPs with multimodal imaging capabilities and photodynamic antimicrobial capabilities.It is important to develop an effective integrated treatment system that simultaneously possesses the functions of real-time monitoring of wound status and the timely treatment of wound infections.Wan et al. [63] used the biological microenvironment for the first time to successfully in situ synthesize conjugated polymers in artificial hydrogels, realizing real-time monitoring and bacterial inhibition of wound infection (Figure 28).The conjugated polymer hydrogel consists of an easily polymerized aniline dimer derivative (SPA), which is skillfully polymerized in situ in calcium alginate (CA) hydrogel to form Su et al. [62] synthesized a series of functional conjugated polymer poly(phenyleneethynylene) (PPE) derivatives containing diethylamino-substituted tetraphenylethene units, with typical AIE properties (Figure 27).PPE nanoparticles based on hydrophobic structure have good cellular uptake capacity and can clearly and sensitively observe the presence of bacteria through fluorescence and Raman signals, respectively.After functionalization, the obtained cationic PPE can preferentially image bacteria rather than mammalian cells and has excellent photodynamic inactivation ability toward G + bacteria and drug-resistant bacteria.This report gives a viable strategy for the exploration of functional CPs with multimodal imaging capabilities and photodynamic antimicrobial capabilities.Su et al. [62] synthesized a series of functional conjuga nyleneethynylene) (PPE) derivatives containing diethylam phenylethene units, with typical AIE properties (Figure 27).PPE hydrophobic structure have good cellular uptake capacity and ca observe the presence of bacteria through fluorescence and Ram After functionalization, the obtained cationic PPE can preferentia than mammalian cells and has excellent photodynamic inactivatio teria and drug-resistant bacteria.This report gives a viable strate functional CPs with multimodal imaging capabilities and photody pabilities.It is important to develop an effective integrated treatment system that simultaneously possesses the functions of real-time monitoring of wound status and the timely treatment of wound infections.Wan et al. [63] used the biological microenvironment for the first time to successfully in situ synthesize conjugated polymers in artificial hydrogels, realizing realtime monitoring and bacterial inhibition of wound infection (Figure 28).The conjugated polymer hydrogel consists of an easily polymerized aniline dimer derivative (SPA), which is skillfully polymerized in situ in calcium alginate (CA) hydrogel to form PSPA. The PSPA that preloads horseradish peroxidase (HRP) could catalyze  In the process of tumor imaging-guided PDT, how to achieve both strong fluores cence and high ROS production efficiency under light excitation is the key to realizing the integration of diagnosis and treatment.Therefore, it is a challenge to construct a single

Detection and Treatment of Tumor
In the process of tumor imaging-guided PDT, how to achieve both strong fluorescence and high ROS production efficiency under light excitation is the key to realizing the integration of diagnosis and treatment.Therefore, it is a challenge to construct a single photosensitizer integrating the advantages of high quantum yield, efficient singlet oxygen production, stable red-light emission, excellent photostability, and low dark toxicity.Zhao et al. [64] designed an efficient D-A system with superior imaging and photodynamic therapeutic capabilities by combining an active polymer (J71) with a hydrophobic conjugated polymer (ADS2008P) to prepare the multifunctional nanoparticles (ADS2008P/J71 NPs) (Figure 29).Through the FRET from ADS2008P to J71, the singlet oxygen production yield of the nanoparticles is increased to 0.704 accompanied by a high fluorescence efficiency.In addition, as a new photosensitizer, J71 is a two-dimensional conjugated polymer, which has good photostability compared with traditional porphyrin photosensitizers.The results of in vivo and in vitro experiments show that the system has excellent fluorescence imaging ability and significant anti-tumor capacity, indicating that the system has great application prospects in imaging-guided PDT.Li et al.
[65] synthesized a series of D-A-type semiconductor polymers (SPs), using a precise double-acceptor strategy to fully utilize intramolecular motion to induce photothermal effects by adjusting the molar ratio of two acceptors with different electron affinity and π electron delocalization degree (Figure 30).The best polymer SP4 has good NIR-II absorption, a high extinction coefficient, and excellent photothermal conversion properties.As a result, SP4 NPs have unprecedented performance in 1064 nm laser-stimulated PAI-guided PTT to accurately diagnose and completely eliminate the tumor.This work integrates ultra-long excitation wavelength, high extinction coefficient, and excellent photothermal conversion capability into a single photothermal agent, which enriches the database of NIR-II absorbing SPs and offers further exploration strategy of multifunctional PTA design for the photothermal treatment of cancer.

Conclusions and Prospects
Due to the excellent photoelectric properties, good biocompatibility, and dation of CPs with π-conjugated system, functional CPs can meet the fluores imetric detection of pathogens and fluorescence/photoacoustic imaging of tum dition, under the activation of the appropriate wavelength of light, CPs can b produce ROS and heat that can oxidize and kill cells through different dissip ways.These two processes correspond to PDT and PTT, respectively.With the of drug-resistant bacteria, the antibiotic era will be replaced, and at the same microbials and treatments that can avoid resistance will become urgent.Th ingenious design strategies summarized and discussed above can meet the a needs of phototherapy only by using PDT or PTT.For example, adding the can improve the water solubility of CPs and their ability to combine w membrane by carrying positive charges, and it also can make CPs biodeg introducing chemical bonds such as thioketone bond and disulfide bond sensitive to a specific environment.Therefore, CPs are one of the most poten biochemical materials to replace antibiotics in biomedicine.How antibacterial/anti-tumor activity of CPs will be limited by the hypoxia enviro

Conclusions and Prospects
Due to the excellent photoelectric properties, good biocompatibility, and easy degradation of CPs with π-conjugated system, functional CPs can meet the fluorescence/colorimetric detection of pathogens and fluorescence/photoacoustic imaging of tumors.In addition, under the activation of the appropriate wavelength of light, CPs can be excited to produce ROS and heat that can oxidize and kill cells through different dissipation pathways.These two processes correspond to PDT and PTT, respectively.With the emergence of drugresistant bacteria, the antibiotic era will be replaced, and at the same time, antimicrobials and treatments that can avoid resistance will become urgent.The CPs with ingenious design strategies summarized and discussed above can meet the antibacterial needs of phototherapy only by using PDT or PTT.For example, adding the QAS group can improve the water solubility of CPs and their ability to combine with the cell membrane by carrying positive charges, and it also can make CPs biodegradable by introducing chemical bonds such as thioketone bond and disulfide bond which are sensitive to a specific environment.Therefore, CPs are one of the most potential organic biochemical materials to replace antibiotics in biomedicine.However, the antibacterial/anti-tumor activity of CPs will be limited by the hypoxia environment and heat shock protein when PDT or PTT is used alone.For this reason, many studies now combine different treatment methods to achieve synergis-tic antibacterial or anti-tumor effects and give full play to the therapeutic effect of each functional unit of the material to meet the needs of targeted and efficient multi-purpose.
Furthermore, with the continuous development of the application of CP materials, existing research results have put forward a comprehensive strategy to coordinate the sensing/imaging of pathogens and tumors with the treatment process.This design idea can put the theoretical assumption of instant detection and timely treatment into practice and is expected to dynamically guide the treatment process through imaging and sensing methods, which plays a strong role in promoting the application of CPs in the biomedical field, making CPs be a multi-purpose material with further research prospects.
Although much progress has been made, there are still some limitations and potential challenges for CPs-based detection and treatment.For example, the relationship between the structure/size and functionality of CPs needs further exploration to clarify the correlation between them.Secondly, the strategy of designing CPs that can control the molecular weight within the absorption and metabolism range of the human body or be degradable, and at the same time have the ability of efficient diagnosis and treatment is still worthy of attention and research.In addition, there are many subjects that need to be studied and experimented before it is put into clinical use.Among them, biological safety, such as the exploration of the transportation, distribution, and metabolism of most water-soluble CPs in the body, the in-depth understanding of the metabolic mechanism, and the long-term safety and toxicity in the body need further evaluation.In a word, it is still a challenge to transform biomedical applications based on CPs (such as detection imaging, drug delivery detection, and phototherapy) into clinical applications, and it takes a long way to go and a certain time to realize.

Figure 2 .
Figure 2. Chemical structures of fluorescent probes and the (A) spectra and (B) visual color d results of S. aureus and P. aeruginosa.Reprinted with permission from ref. [37].Copyrig Wiley-VCH GmbH.

Figure 2 .
Figure 2. Chemical structures of fluorescent probes and the (A) spectra and (B) visual color detection results of S. aureus and P. aeruginosa.Reprinted with permission from ref. [37].Copyright 2020 Wiley-VCH GmbH.

33 E
. coli and C. albicans, PFBTM-NMe3 showed certain aggregation after binding to E. c and exhibited specific, rapid, and sensitive fluorescence responses.Therefore, through t design of different binding strategies between the synthetic polymer and various path gens, it is possible to realize rapid and sensitive fluorescence imaging and identificati of bacteria and fungi in mixed pathogen samples, giving new impetus to the research early clinical diagnosis of bacterial infection.

Figure 3 .
Figure3.The structure of PFBTM-NMe3 + and the illustration of its selective detection of bacteria mixed samples.Reprinted with permission from ref.[38].Copyright 2020 American Chemical So ety.

Figure 3 .
Figure 3.The structure of PFBTM-NMe 3 + and the illustration of its selective detection of bacteria

Figure 5 .
Figure 5. PPE in different oxidation states for detection.(a) The illustrated structures, (b) the spectra and (c) visual color detection of different oxidation states.Reprinted with permission from ref. [40].Copyright 2020 Wiley-VCH GmbH.

Figure 5 .
Figure 5. PPE in different oxidation states for detection.(a) The illustrated structures, (b) the spectra and (c) visual color detection of different oxidation states.Reprinted with permission from ref. [40].Copyright 2020 Wiley-VCH GmbH.

Figure 6 .
Figure 6.The reaction of PDA with metabolized ammonia gas for visual bacterial detection [41].

Figure 6 .
Figure 6.The reaction of PDA with metabolized ammonia gas for visual bacterial detection [41].

33 Figure 6 .
Figure 6.The reaction of PDA with metabolized ammonia gas for visual bacterial detection [41].

Figure 10 .
Figure 10.The structure of PPV, HA, and HA-A5G81 for accelerating wound repair and combating bacterial infection [45].

Figure 10 .
Figure 10.The structure of PPV, HA, and HA-A5G81 for accelerating wound repair and combating bacterial infection [45].

Figure 10 .
Figure 10.The structure of PPV, HA, and HA-A5G81 for accelerating wound repair and combating bacterial infection [45].

Polymers 2023 ,
15,  x FOR PEER REVIEW 12 of 33 of violet cation radical into the main chain.The NIR photothermal conversion property of the strong free radical supramolecular dimer gives VR-SP photothermal antibacterial ability and further improves the photothermal antibacterial performance through the local enrichment of the supramolecular polymer and enhanced adsorption on the bacterial surface.In addition, only specific bacteria, such as E. coli, have the reducing capability to promote supramolecular polymerization, while many others, such as B. subtilis, P. aeruginosa, and S. aureus, do not possess this capacity.Therefore, under the NIR radiation of 1064 nm, the inhibitory effect of the supramolecular polymer on E. coli was significant (>99.9%), with high specificity.This biodynamic in-situ supramolecular polymerization strategy has great potential for manufacturing intelligent biomedical supramolecular materials with adaptive and programmable properties.

Figure 11 .
Figure 11.Illustration of the (a) supramolecular polymerization of VDV and CB[8] and (b) PTT based on in situ supramolecular polymerization driven by E. coli.This figure has been published in CCS Chemistry (2021) ; [Supramolecular Polymerization Powered by Escherichia coli: Fabricating a Near-Infrared Photothermal Antibacterial Agent in Situ] is available online at [https://doi.org/10.31635/ccschem.021.202101490].Copyright 2021 Chinese Chemical Society.

Figure 11 .
Figure 11.Illustration of the (a) supramolecular polymerization of VDV and CB [8] and (b) PTT based on in situ supramolecular polymerization driven by E. coli.This figure has been published in CCS Chemistry (2021); [Supramolecular Polymerization Powered by Escherichia coli: Fabricating a Near-Infrared Photothermal Antibacterial Agent in Situ] is available online at [https://doi.org/10.31635/ccschem.021.202101490].Copyright 2021 Chinese Chemical Society.

Figure 13 .
Figure 13.Schematic diagram of (A) the synthesis of pPCPs and (B) pPCP-NPs for pho antibacterial treatment.Reprinted with permission from ref. [48].Copyright 2022 The Au

Figure 14 .
Figure 14.The schematic diagram of PEoS-PHMG (a) synthesis for (b) dual-mode inhibition of bacteria through synergistic PDT.Reprinted with permission from ref. [49].Copyright 2020 Published by Elsevier B.V. on behalf of the Chinese Chemical Society and Institute of Materia Medica, Chinese Academy of Medical Sciences.Zhao et al. [50] synthesized a covalent organic framework (Tph-BDP-COF) containing porphyrin (Tph) and borodipyrrole (BDP) derivatives based on the combined antibacterial strategy of PDT and PTT (Figure15).When ROS is present, protective heat shock proteins at high temperatures are inhibited by biochemical reactions[80,81] in other words, the production of ROS reduces the cell heat tolerance and thus achieves high-temperature sterilization.To adjust the dissipation of excitation energy, excellent synergistic antibacterial phototherapy is achieved.Tph-type photosensitizers have good light collection ability, produce ROS through electron and energy transfer, and generate heat from molecular vibration under light.However, the strong absorption of Tph is mainly at 400-450 nm,

Figure 17 .Figure 17 .
Figure 17.(A) The treatment time statistics of commercial photosensitizers.(B) The illustrated cascade reaction of O 2 −• in PDT.(C) The structure of CP1 and (D) the schematic diagram of O 2 −• generated by CP1 before and after degradation.Reprinted with permission from ref. [52].Copyright 2021 The Authors.

Figure 18 .
Figure 18.The illustrated preparation of CP + -CpG NPs and the synergy of PDT and immunoth apy.Reprinted with permission from ref. [53].Copyright 2022 Published by Elsevier B.V.

Figure 18 .
Figure 18.The illustrated preparation of CP + -CpG NPs and the synergy of PDT and immunotherapy.Reprinted with permission from ref. [53].Copyright 2022 Published by Elsevier B.V.
Furthermore, Reg could reprogram tumor-associated macrophages (TAM) from the pro-tumor M2 phenotype to the tumor-killing M1 phenotype, hence leading to a changeover of the tumor microenvironment that is immunosuppressive.The investigation gives insight into the exploration of promising nanomaterials to conquer the shortcomings of photodynamic immunotherapy.olymers 2023, 15, x FOR PEER REVIEW 19 of 33normalizer (Reg) resulting in nanoparticles (NP-PDT@Reg) (Figure19).Reg can be effectively released from NP-PDT@Reg under NIR light to improve hypoxia in tumors through vascular standardization, allowing more nanoparticles and oxygen to enter the tumor.In addition, NP-PDT@Reg with the aid of NIR light could further lead to the production of more ROS to eliminate tumor cells and induce ICD to stimulate immune responses for anti-tumor.Furthermore, Reg could reprogram tumor-associated macrophages (TAM) from the pro-tumor M2 phenotype to the tumor-killing M1 phenotype, hence leading to a changeover of the tumor microenvironment that is immunosuppressive.The investigation gives insight into the exploration of promising nanomaterials to conquer the shortcomings of photodynamic immunotherapy.

s 20 Figure 20 .
Figure 20.Synthesis of biodegradable PTA and its application in PTT anti-tumor schematic diag Reprinted with permission from ref. [55].Copyright 2021 Wiley-VCH GmbH.

Figure 20 .
Figure 20.Synthesis of biodegradable PTA and its application in PTT anti-tumor schematic diagram.Reprinted with permission from ref. [55].Copyright 2021 Wiley-VCH GmbH.

Figure 21 .
Figure 21.Synthesis of P-PPor NPs and schematic diagram of photothermal anti-tumor application.Reprinted with permission from ref. [56].Copyright 2021 Published by Elsevier Ltd.

Figure 21 .
Figure 21.Synthesis of P-PPor NPs and schematic diagram of photothermal anti-tumor application.Reprinted with permission from ref. [56].Copyright 2021 Published by Elsevier Ltd.

3. 3 .
Integration of Diagnosis and Treatment Based on CPs 3.3.1.Detection and Treatment of Pathogenic Microorganisms

Figure 26 .
Figure 26.Schematic diagram of nano-probe PDANSs-FAM-Apt used for the imaging-guided photothermal killing of S. aureus.Reprinted with permission from ref. [61].Copyright 2020 American Chemical Society.

Figure 26 .
Figure 26.Schematic diagram of nano-probe PDANSs-FAM-Apt used for the imaging-guided photothermal killing of S. aureus.Reprinted with permission from ref. [61].Copyright 2020 American Chemical Society.
H 2 O 2 overexpressed in infected wounds to produce •OH, which leads to oxidative killing bacteria.The NIR absorption of PSPA enables the real-time monitoring of H 2 O 2 with the naked eye and photoacoustic signals and has a photothermal inhibition effect on bacteria mediated by NIR light.In addition, combined with the sustained chemokinetic activity of •OH, in vivo treatment demonstrated a wound healing rate of 99.03% on day 11.Thus, this study provides inspiration for manipulating in situ biosynthesis of functional CPs in artificial hydrogels to solve multiple problems in wound treatment.olymers 2023, 15, x FOR PEER REVIEW 26 of 33 PSPA.The PSPA that preloads horseradish peroxidase (HRP) could catalyze H2O2 over expressed in infected wounds to produce •OH, which leads to oxidative killing bacteria The NIR absorption of PSPA enables the real-time monitoring of H2O2 with the naked eye and photoacoustic signals and has a photothermal inhibition effect on bacteria mediated by NIR light.In addition, combined with the sustained chemokinetic activity of •OH, in vivo treatment demonstrated a wound healing rate of 99.03% on day 11.Thus, this study provides inspiration for manipulating in situ biosynthesis of functional CPs in artificia hydrogels to solve multiple problems in wound treatment.

Figure 28 .
Figure 28.Schematic diagram of in-situ polymerization of H2O2-activated SPA in hydrogel for real time monitoring and treatment of wound infection.Reprinted with permission from ref. [63].Cop yright 2022 Elsevier Ltd.

Figure 28 .
Figure 28.Schematic diagram of in-situ polymerization of H 2 O 2 -activated SPA in hydrogel for real-time monitoring and treatment of wound infection.Reprinted with permission from ref. [63].Copyright 2022 Elsevier Ltd.

Polymers 2023 ,
15,  x FOR PEER REVIEW 27 of33 polymer, which has good photostability compared with traditional porphyrin photosensitizers.The results of in vivo and in vitro experiments show that the system has excellent fluorescence imaging ability and significant anti-tumor capacity, indicating that the system has great application prospects in imaging-guided PDT.

Figure 29 .Figure 30 .
Figure 29.Illustrated preparation of ADS2008P/J71 NPs for imaging-guided PDT.Reprinted with permission from ref. [64].Copyright 2022 Elsevier B.V.Li et al.[65] synthesized a series of D-A-type semiconductor polymers (SPs), using a precise double-acceptor strategy to fully utilize intramolecular motion to induce photothermal effects by adjusting the molar ratio of two acceptors with different electron affinity and π electron delocalization degree (Figure30).The best polymer SP4 has good NIR-II absorption, a high extinction coefficient, and excellent photothermal conversion properties.As a result, SP4 NPs have unprecedented performance in 1064 nm laser-stimulated PAI-guided PTT to accurately diagnose and completely eliminate the tumor.This work integrates ultra-long excitation wavelength, high extinction coefficient, and excellent photothermal conversion capability into a single photothermal agent, which enriches the database of

Table 1 .
Overview of the application of CPs in the biomedical field.