A Comprehensive Review on Thiophene Based Chemosensors

The recognition and sensing of various analytes in aqueous and biological systems by using fluorometric or colorimetric chemosensors possessing high selectivity and sensitivity, low cost has gained enormous attention. Furthermore, thiophene derivatives possess exceptional photophysical properties compared to other heterocycles, and therefore they can be employed in chemosensors for analyte detection. In this review, we have tried to explore the design and detection mechanism of various thiophene-based probes, practical applicability, and their advanced models (design guides), which could be thoughtful for the synthesis of new thiophene-based probes. This review provides an insight into the reported chemosensors (2008-2020) for thiophene scaffold as effective emission and absorption-based chemosensors.


Introduction
Over the years, the revolution in industrial and agricultural sectors has brought plenty of new products and services. Along with the production of useful technologies, these advancements utilize more chemicals to meet the requirements of the population. The release of such chemicals into the environment is mainly responsible for destroying the environmental and biotic systems. Many environmental pollutants such as heavy metals and other transition metals enter the environmental systems through natural and anthropogenic activities. These are detrimental to life due to their toxicity. Hence, detection of these metal ions is vital. Therefore, there is a need to develop convenient and realistic techniques for the quick detection of diverse metal ions in biological and ecological environments. The progress of selective optical signaling systems for ion detection is an emerging subject of interest in research from recent years due to the potentiality of such systems in analytical devices. Among the various available analytical tools for ion detection, fluorometric and colorimetric analysis are among the most important and most preferred optical tools that are used for the detection of various ions and molecules in a particular system due to their high selectivity, fast response, better sensitivity, real-time monitoring [1], and bioimaging capability [2,3].
From this point of view, various chemosensors have been researched and reported for the discernment of ions. Chemosensors are molecules that show a slight change in their emission properties in response to their interaction with the binding ions of the surrounding environment [4]. Furthermore, it has been known that two important processes take place during the detection of the analyte. Firstly, being molecule recognition, and the second one being signal transduction. On this basis, chemosensors can be cataloged into a receptor that binds with the analyte of interest, an active unit that changes its properties upon binding to the analyte, and a spacer that can tune the electronic properties between the above two moieties [5].
As a requirement for designing chemosensors to detect specific analytes, three pivotal factors need to be taken into consideration: high selectivity, high sensitivity, and high specificity [5]. Designing an effectual chemosensor possessing both selectivity and sensitivity features for analyte detection is troublesome. Chemosensors are sensitive to changes in the environment [6] and hence they can be generally categorized according to the operating principle of the transducer (Fig. 1) [7].
Optical devices are based on the changes of optical phenomena, such as absorbance, reflectance, luminescence, flourescence which is the outcome of an interaction of the analyte with the receptor of the sensor. Electrochemical devices transform the changes of the electrochemical interaction analyte -electrode into a signal which include voltammetric sensors, potentiometric sensors. Electrical devices sense the change in the electrical properties of the analyte without any electrochemical processes. Few examples are electrolytic conductivity sensors, electric permittivity sensors. Further, magnetic devices rely on the change of paramagnetic properties of a gas which is being analysed. Lastly, thermometric devices are based on the measurement of the heat effects of a specific chemical reaction or adsorption that involves the analyte.
Nevertheless, the detection of analytes or ions through chemosensors is usually attained by the selective coordination to the target analyte resulting in the change in the intensity of fluorescence of the fluorophore with the concentration change of ions [8], via photo-physical mechanisms such as chelation induced enhanced fluorescence (CHEF) [9], photoinduced electron transfer (PET) [10], intramolecular charge transfer (ICT) [11], Foster Resonance Energy Transfer (FRET) [12,13] and various other approaches. These chemosensors provide a highly sensitive, inexpensive, reliable alternative along with simple visualization of analytes without sophisticated instruments [14].
One of the extensively used chemosensors is thiophenebased (thiophene derivatives), and they have been employed as a fluorescence signaling promoter to organic acids, metal ions, and cations [15]. Thiophene is one of the most studied five-membered heterocyclic compounds. It has been observed that five-membered heterocyclic compounds often show strong photoluminescence properties, such as long emission and absorption wavelengths, vast absorption co-efficient, and more fluorescence quantum yield, it is widely used in light-emitting materials [16] and therefore, the thiophene moiety can be employed as a functional group as a part of the chemosensor. Because of its high potential of structural variation, along with the high polarizability of sulfur atoms in the ring results in a stabilization of the conjugated chain, thereby having magnificent electronic and charge-transfer properties [17]. Oligo and polythiophenes have fluorescence frequencies that are tunable over a broad visible range and possess high absorbencies and high fluorescence efficiencies [18] and therefore, they are being employed as fluorometric and colorimetric chemosensors for the detection of proteins.
The main objective of this review is to focus light on the recent progress in the development of thiophene-based chemosensors that have been employed for the detection of cations (Al 3+ , In 3+ , Hg 2+ , Pb 2+ , Cr 3+ , Zn 2+ , etc.) and anions (CN − , F − , I − etc.). The chemical and physical interactions of these sensors with the analytes resulting in changes in the emission intensity and probe color are explored. The practical applications of these probes in the real world are also summarised.

Thiophene Based Chemosensors for Detection of Cations
Thiophene-based chemosensors provide a novel approach with an easy synthetic route and cost-effective technique for selective and quantitative detection of metal ions in biological and environmental systems. The coordination of a cation to a fluorescent chemosensor might enhance the fluorescence emission, called as Chelation Enhanced Fluorescence Effect (CHEF), or quench the fluorescence emission, called as Chelation Enhancement Quenching Effect (CHEQ). These changes in the emission intensity are employed for analyte detection.

Aluminium
Aluminium is the most abundant non-ferrous metal in the earth's crust. Most of the foods and antiperspirants contain aluminium compounds, and hence we are exposed to them daily. However, excessive exposure to Al 3+ to the human body can cause awful illnesses like Parkinson's and Alzheimer's disease [19], threatens aquatic species by clogging the gills due to aluminium accumulation [20], and also affects plant growth and development. Therefore, there is a necessity for the development of chemosensors for the recognition of aluminium ions.
Considering the harmful effects, Jeong et al. designed a multifunctional fluorescent 'turn-on' chemosensor 1 using the thiophene moiety along with the diethyl aminophenol moiety (electron-donor) for the recognition of Al 3+ in a nearperfect aqueous solution. The UV-Vis titration in bis-tris buffer (pH 7.0) revealed that, upon the addition of Al 3+ , the absorption intensity of the peak at 370 nm lessened and the absorption intensity at 420 nm increased, therefore showing high selectivity towards Al 3+ ions. It was also found that the fluorescence intensity of the chemosensor escalated only in the presence of Al 3+ ions. Job's plot analysis showed that there was a 1:1 stoichiometric ratio between Al 3+ and chemosensor, and the better selectivity of the fluorescent chemosensor towards Al 3+ (hard acid) is attributable to the presence of two oxygen atoms (hard base). Furthermore, the binding constant of chemosensor 1 calculated from Benesi-Hildebrand was found to be 7.56 × 10 2 , and the LOD (Limit of Detection) was observed to be 0.41 µM.
Furthermore, evaluation of the feasibility of chemosensor 1 for Al 3+ detection biological systems was carried out by in vitro cell imaging experiments using HeLa cells, and it was found that the fluorescence intensity augmented with the increase of Al 3+ ion concentration in the cells, thereby indicating that the fluorescent chemosensor could be employed as a biocompatible detector in the determination of Al 3+ ions in biological systems. The proposed sensing mechanism for Al 3+ detection was ICT and deprotonation by hydrogen bonding (Scheme 1), as supported by TD-DFT and DFT studies [15].
Manjunath et al. synthesized thiophene appended pyrazoline based 'Turn-off' fluorescent chemosensor 2 and evaluated its sensing properties in HEPES buffer solution at pH 7.2. The UV-Vis absorption band at 358 nm exhibited by the free 2 sensor shifted to 349 nm thereby exhibiting decreased intensity upon the addition of Al 3+ ions only due to the coordination of sensor 2 with Al 3+ ion (Scheme 2). Furthermore, the free sensor 2 showed deep blue fluorescence emission at 447 nm, which was further quenched only in the presence of Al 3+ . The association constant for the binding of Al 3+ ion in 2 was determined to be 1.84 × 10 4 M −1 with 1:1 stoichiometry [21] and the LOD for Al 3+ was 8.92 × 10 −8 M, which was sufficiently lower than the permissible levels of Al 3+ in drinking water as set up by WHO, thereby showing potential to examine drinking water quality.

Indium
Indium is used in biological and diagnostic disciplines, such as in treating cancer or other radiopharmaceuticals, owing to its less toxicity. But compounds of Indium, namely Indium phosphate (IP) and Indium tin oxide (ITO), have been recognized to have potential risk for respiratory diseases. Hence, detecting indium selectively is in high demand. Significantly, few fluorescent chemosensors have been developed to detect indium since inhibition from Al 3+ and Ga 3+ (belonging to the same group of metal ions) occurs. Thus, there is a need to develop selective chemosensors by fluorescent 'turn on' method for differentiating In 3+ from Al 3+ and Ga 3+ ions.
In this regard, Hanna Cho designed the synthesis of 'Turn-on' chemosensor 3 [(Z)-N′-(pyridine-2-ylmethylene)thiophene-2carbohydrazide] by integrating thiophene-2-carbohydrazide with picolinaldehyde. When Cd 2+ , Al 3+ , Cu 2+ , etc., were added to the chemosensor TP in EtOH, there was no significant fluorescent response, except for In 3+ , which showed a fluorescence emission at 460 nm [22] due to the CHEF effect. The distinctive selectivity of probe 3 towards In 3+ is assigned to the size effect and the hard-soft principle, indicating that it could effectively distinguish In 3+ from Al 3+ and Ga 3+ because of their alike properties [23] (Scheme 3). UV-Vis titration showed that the absorption band (exhibited by the free sensor) gradually decreased at 310 nm and a new band at 379 nm emerged due to the presence of In 3+ . The association constant for the 2. (3)−In 3+ complex was determined by Li's equation to be 8.1 × 10 4 M −2 . The LOD was estimated to be 0.61 µM, which was sufficiently lowest amid all the formerly reported chemosensors for In 3+ detection.

Mercury
For decades, heavy metal pollution of the environment has been a significant issue due to its threat to biotic life [24,25].
One of the most hazardous and commonly occurring heavy metal [26] pollution in the aqueous system is mercury pollution since Hg 2+ ions can remain persistent in the aqueous environment and even a minute amount of Hg 2+ ions cause health issues such as respiratory damage, gastrointestinal problems, Minamata disease, and prenatal brain damage. Mercury ion is spectroscopically and magnetically silent (d 10 ) [27] and therefore cannot be rapidly detected by the available detection techniques such as NMR and EPR. Thus, there is an essential need for new chemosensors to detect Hg 2+ ions in the aqueous system.
In this regard, Zhang et al. developed a thiophene-based ratiometric fluorescent chemosensor 4 possessing triphenylamine and benzothiadiazole moieties, since thiophene can outstretch the π conjugation and also stabilize the quinoid structure and contribute in tuning the energy gap of the D − π − A − π − D type of chromophore, and the presence of the π bridge of thiophene could increase the fluorescence resonance wavelength up to 80 nm. UV-Vis absorbance spectra of probe 4 revealed that only Hg 2+ promoted a redshift from 489 nm to 535 nm, accompanied by red to violet color change. Probe 4 exhibited a drop in the fluorescent intensity band centered at 656 nm and an increase in the band Scheme 3 Sensing mechanism of chemosensor 3 towards In 3+ Scheme 4 Sensing mechanism of chemosensor 4 with Hg 2+ centered at 723 nm [28], only in the presence of the Hg 2+ without interference from other competing metal ions. The LOD was determined to be 0.36 µM for Hg 2+ ions. Furthermore, the sensing mechanism was found to be due to the Mercury-promoted desulfurization reaction (Scheme 4).
Over the last few years, the π-conjugated polymer has gained increased attention due to its excellent optical properties and signal amplification because of repeating units. Based on these properties, Liheng et al. synthesized a redemitting 'Turn-on' polymer fluorescent probe 5 occupying thiophene, benzothiazole, and quinoline groups for specific sensing of Hg 2+ ions and evaluated its potential in practical applications (in cosmetics). It was noticeable that only Hg 2+ ions could enhance the fluorescence intensity of the probe in DMSO, which was evident by the color change from blue to red (under UV light) and could be explained based on the PET process [29] (Scheme 5). The binding of probe 5 and Hg 2+ was found to be in a 1:1 stoichiometric ratio, and the response time was quick, being less than 10 s. It was observed that similar fluorescence changes of probe 5 could also be observed with the increase of Hg 2+ ions in cosmetics, thereby making it a valuable tool for the monitoring of Hg 2+ in practical applications.
Nanostructured materials possess unique physical and chemical properties and possess potential applications in catalysis, sensors, and magnetic devices. Considering these into account, Chatteikaewtong et al. synthesized a terthiophene functionalized rhodamine fluorescence resonance energy transfer (FRET)-based chemosensor 6 and probe 6-gold nanocomposite based-chemosensor 7 for Hg 2+ recognition. It was observed that the fluorescence spectra and UV-Vis spectra of probe 6 exhibited a high-fluorescence band at 578 nm and an absorbance intensity of 555 nm, respectively, upon the addition of Hg 2+ ions only, owing to the Hg 2+ induced ring-opening of the spirolactam Rhodamine form (Scheme 6). The absorption spectra of probe 7 exhibited a significant redshift, with the color change from colorless to black, and were credibly due to the aggregation Scheme 5 Plausible sensing mechanism of probe 5 towards Hg 2+ Scheme 6 A suggested mechanism for sensor 6 towards Hg 2+ of gold nanoparticles by Hg 2+ chelation, and was evident by TEM images. A 2:1 binding ratio for the probe 6−Hg 2+ and probe 7−Hg 2+ complex was concluded, and the LOD of probe 7 was calculated to be 0.32 µM which was relatively lower [30] compared to that of probe 6 (LOD=1.34 µM), and the detection time was less than 30 s, thereby exhibiting a high sensitivity towards Hg 2+ ions.
Considering the photophysical properties of thiophene and rhodamine, Ajoy Pal et al. synthesized a thiophene derivatized rhodamine chemosensor 8 [thiophene-2,5-di-(methyl-amino-ethyl rhodamine)] for Hg 2+ detection. The sensor in CH 3 CN exhibited a maximum absorption peak at 557 nm and an ensuing color change to pink in the presence of Hg 2+ only. Further, UV-Vis spectral studies and fluorescence studies were carried out in CH 3 CN/H 2 O mixture to confirm the sensing property of sensor 8 towards Hg 2+ , and it was evident that only Hg 2+ ions imparted an immediate color change from colorless to pink with maximum fluorescence. However, the other tested metal ions exhibited negligible fluorescence enhancement. The absorbance and fluorescence changes could be assigned to the metal ioninduced spiro-ring opening of rhodamine moiety. The LOD and metal ion/ligand binding stoichiometry was 2.2 × 10 −8 M and 1:2 respectively. The interaction between sensor 8 and Hg 2+ was evidenced from ESI-MS analysis, which suggested that sensor 8 selectively binds to the first Hg 2+ ion via one of its 'amino-ethyl-amido' units along with its central sulphur atom, which then promotes a spatial reorientation of the ligand and results in a faster binding of the second Hg 2+ ion (Scheme 7). To examine its reusability, CO 3 2− /HCO 3 − and Scheme 7 Sequential complexation of Hg 2+ ions to sensor 8

Scheme 8
Possible sensing mechanism of sensor 9 towards Hg 2+ CH 3 COO − have been found to induce the reversibility in sensor 8−Hg 2+ complexation and the structural transformation of Rhodamine [31], thereby rendering a reversible dualchannel signaling pattern.
Hanna et al. synthesized cinnamaldehyde-based colorimetric chemosensor 9 and the thiophene derivative (with hydrazide) was introduced to overcome the drawback of the less solubility of cinnamaldehyde in water. It was observed that the absorption band of 390 nm, exhibited by free sensor 9 in bis-tris buffer had a noticeable decrease, and a new broad absorption band of 518 nm emerged with the color change from pale yellow to orange, only upon the inclusion of Hg 2+ ions due to the probe 9-Hg 2+ complex. The spectral response of 9 was noted in a broad pH range of 6-9. The binding constant was determined to be 2 × 10 9 M −2 with 2:1 stoichiometry. The LOD was calculated to be 0.01 µM for Hg 2+ and the sensing properties could be attributed to the ICT mechanism (Scheme 8), supported by DFT calculations [32].
Recently, plenty of chemosensors have been designed to separately detect Hg 2+ and Cu 2+ ions, since Cu 2+ ion interferes with the detection of Hg 2+ ions. Influenced by the difficulties in the selective sensing of Hg 2+ and Cu 2+ ions, Syed et al. developed a thiophene-based probe 10 for multiple metal-ion recognition, past distinct output signals. The naked-eye experiment revealed that the fluorescent green color of the free probe in HEPES buffer switched to blue with Hg 2+ and non-fluorescent with Cu 2+ ions respectively under UV light. The absorption spectra of the free probe 10 displayed a low energy charge transfer at 395 nm and a high energy band at 328 nm, which raised and shrunk only with Hg 2+ and Cu 2+ ions, respectively. Moreover, upon interaction with Hg 2+ , a negligible drop in the relative fluorescence intensity was spotted and upon interaction with Cu 2+ , significant fluorescence quenching was notable, which could be attributed to the CHEF and CHEQ mechanisms, respectively (Scheme 9). By the results, it is noticeable that the fluorescence intensity of the probe 10-Hg 2+ complex was uninfluenced upon interaction with Cu 2+ ions. Likewise, the quenched fluorescence emission of the probe 10-Cu 2+ complex does not get enhanced upon interaction with Hg 2+ , thereby providing a means to detect both ions with higher selectivity and distinct output emission signals. Furthermore, the reversibility studies were performed using EDTA, which suggested a reversible complexation mode between probe 10 and metal ions. The binding constants were 3.1 × 10 5 for Hg 2+ and 1.6 × 10 5 for Cu 2+ , and the binding of the probe to Hg 2+ /Cu 2+ was found to be in a 1:1 stoichiometric ratio. Furthermore, the LOD to detect Hg 2+ and Cu 2+ ions were ascertained to be 28 µM and 7.5 µM respectively [33]. Probe 10 has been reported to have good cell permeability to detect Hg 2+ and Cu 2+ in live cells and protein medium, thereby proving its potential to discern metal ions in the biological system. Besides, a molecular logic gate was also constructed and the probe has been explored as a coding/decoding fluorescent blue ink. Divya Singhal synthesized a chromogenic and fluorogenic thiophene-based schiff base probe 11 [2-((3-methylthiophen-2-yl)methyleneamino)benzenethiol], for selective recognition of Hg 2+ ions. It was seen that the probe showed an immediate color change from light yellow to yellowishorange only for Hg 2+ ions. Furthermore, UV-Vis absorbance and fluorescence studies were investigated in CH 3 OH/H 2 O (v/v 8:2), which revealed that the addition of Hg 2+ displayed a new band at 430 nm in addition to 287 nm and 355 nm absorption bands of the probe, due to the ICT mechanism. The turn-on fluorescence emission, exhibited by probe 11 in response to Hg 2+ ions was seen at 503 nm, which was due to the CHEF mechanism [34] and the probe was free from interference from other tested ions, thereby clearly indicating the selective sensing of Hg 2+ ions and the binding interaction was further confirmed by NMR, Mass spectra, DFT studies, and electrochemical behavior (Scheme 10). The reversibility studies of the sensing mechanism were performed using EDTA, which showed a fluorescence quenching and disappearance of the color of probe 11, in Scheme 9 Plausible sensing mechanism of probe 10 towards Hg 2+ /Cu 2+ contrast to that of probe 11−Hg 2+ sensing mechanism. A 2:1 stoichiometry for probe 11 and Hg 2+ and a detection limit of 20 µM was noted.

Lead
Lead is one of the noxious heavy metals, and its accumulation can result in lead poisoning, consequently leading to retarded brain development and nervous system disorders [35], convulsions, muscle paralysis [36], coma, and death. Very few fluorescent chemosensors have been reported for detecting Pb(II) due to their undesirable property of quenching the fluorescence emission through electron transfer [37] or spin-orbital coupling [38], which is highly disadvantageous for analytical purposes.
Jing Cao et al. synthesized a novel water-soluble thiophene functionalized chemosensor 12 bearing benzo[d]thiazole-2-thio unit for Pb 2+ detection. It was observed that in the HEPES buffer, the probe exhibited an exceptional fluorescence intensity accompanied by a bathochromic shift in the absorption maxima, only in the presence of Pb(II), without any interference from other ions. This could be attributed to the binding pocket (Scheme 11) formed within probe 12, which could be a probable binding site for Pb(II) [39], having a 1:1 binding stoichiometry ratio.

Chromium
Chromium is one of the heavy metals and is widely used in metallurgy and pigments. It plays a role in regulating blood glucose levels [40] and the metabolism of proteins, carbohydrates, and fats in the body. However, chromium is carcinogenic, and its toxicity can result in Haemolysis and kidney failure.
Considering the above issues, Erman synthesized an anthracene appended-thiophene fluorescent probe 13 which possessed a low detection limit and a faster response time for Cr 3+ . It was observed that the free probe in CH 3 CN/H 2 O (v/v 6:4) had diminished fluorescence because of the PET process. However, a new strong emission peak appeared at 500 nm upon the addition of Cr 3+ . The LOD of the probe was calculated to be 0.4 µM, and it had a response time of less than 1 min. Reversibility studies were carried out by employing an excess of EDTA and it was observed that the sensing mechanism was irreversible. Moreover, the sensing mechanism is attributable to the concurrent coordination of Cr 3+ ions with N atom on C=N moiety and S atom in thiophene, which induced the attack of water resulting in the formation of 2-aminoanthracene. To investigate the potential of probe 13 in practical applications, probe (10 µM) in CH 3 CN/HEPES solution (v/v 6:4) at pH 7 was introduced Scheme 10 Possible mode of binding interaction of probe 11 with Hg 2+ Scheme 11 Binding pocket of probe 12 for Pb 2+ onto circular test papers. They did not exhibit emission at 366 nm under UV light in the absence of metal ions, while only Cr 3+ ions exhibited a green emission [41] by a "turnon" response (Scheme 12), thereby making it an efficient tool for Cr 3+ detection.
Conjugated polymers have acquired increased attention, owing to their high sensitivity and ease of measurement and, are therefore used as fluorescent sensors. Previously developed chemosensors have certain limitations, such as low water solubility and low sensitivity. To overcome this drawback, water-soluble π-π conjugated polymers could be employed to produce fluorescence, which is more remarkable compared to that of classic fluorophores. Considering these properties, Marco Laurenti et al. synthesized a watersoluble polythiophene-based fluorescent chemosensor probe 14 [Poly(3-ethoxythiophene-2,5-diyldimercaptosuccinic acid)] possessing chelating properties for the recognition of Pb 2+ and Hg 2+ . The recognition properties of the probe were evaluated by UV-Vis and photoluminescence spectra of an aqueous solution of the probe. Initially, probe 14 exhibits an absorption maximum at 405 nm and 530 nm in the absorption and emission spectra, respectively. However, upon the addition of Pb 2+ and Hg 2+ , fluorescence quenching was noticed. This could be accredited to the conformational change in probe 14, due to the complex formed between the metal ions and the chelating DMSA moiety of the polymer [42].
It has been known that schiff bases easily isomerize in the excited state but incline to display weak fluorescence. To overcome this drawback, thiophene moieties can be incorporated since thiophene exhibits significant optoelectronic properties. One such approach was made by Feyza et al. who designed a thiophene-based schiff base sensor 15 for Cr 3+ detection ions in an aqueous solution. The probe displayed an enhancement in fluorescence intensity with a color change from yellow to Saxon blue upon binding to Cr 3+ , which is accredited to the chelation between Cr 3+ , S, and N atoms (Scheme 13), thereby impeding the PET process. Besides that, the pH effect showed that there was enhanced fluorescence intensity upon increasing the pH, which attained a maximum (at pH 8) and then decreased, since Cr(OH) 3 formation prevented further probe 15-Cr 3+ complex formation. Fluorescence studies showed that the fluorescence intensity of the probe improved with the increase in the amount of Cr 3+ (λ excitation = 320 nm) and Job's plot analysis revealed that probe 15 and Cr 3+ showed 2:1 binding stoichiometry. The association constant was calculated to be 2.8 × 10 4 M −1 and the LOD [43] was found to be 1.5 × 10 −6 M, and th optical behaviour of the probe was beneficial for Cr 3+ detection in waste water.
Recently, a handful of chemosensors have been delineated for the simultaneous detection of both Cr 3+ and Cu 2+ ions. Hence, a novel approach was made by Natarajan et al. who synthesized a triple-action probe 16 [thiophenedicarboxaldehyde-rhodamine-B]. Probe in CH 3 CN/H 2 O (v/v 4:1) displayed a significant color change from light yellow to pink with Cr 3+ and Cu 2+ ions, while the remaining ions did not exhibit any color change, indicating that probe 16 was insensitive towards anions. But only CN − ions displayed a color change when introduced to the probe 16−Cu 2+ solution, and a cascade recognition study confirmed the detection. The sensing property of probe 16 towards Cu 2+ , Cr 3+ , and CN − could be due to the spirolactam ring-opening and spirolactam ring-closing of the rhodamine moiety, respectively (Scheme 14). However, it was concluded that Cr 3+ shows excellent enhancement in fluorescence intensity of probe 16 with 1:2 stoichiometry, due to the spirolactam ring opening [44] of the probe, whereas Cu 2+ with 1:1 stoichiometry shows fluorescence quenching due to its paramagnetic nature. Moreover, the detection limits for Cr 3+ , Scheme 12 Proposed detection mechanism of probe 13 for Cr 3+ Scheme 13 Proposed sensing mechanism of probe 15 to Cr 3+ Cu 2+ , and CN − ions were 2.6 × 10 −6 M, 1.01 × 10 −6 M, and 9.3 × 10 −7 M respectively. The reversibility of the probe was performed by introducing a CN − into the probe 16−Cu 2+ complex, and good reversibility of Cu 2+ detection sensing was observed.

Zinc
Zinc is the third most abundant transition metal found in specific tissues of the body [45,46]. It is responsible for the catalytic activity of few enzymes as well [47,48]. But, excess zinc can lead to its toxicity in the body resulting in the damage of the pancreas and metabolism disturbance, consequently leading to neurodegenerative disorders and arteriosclerosis.
Several chemosensors have been reported to detect Zn 2+ ions, such as 6-methoxy-8-quinolyl-para-toluenesulfonamide (TSQ), Zinquin, but they have limited activity because of their poor selectivity for Zn 2+ ions. Motivated by the demand for low-cost and simple molecules for the selective recognition of Zn 2+ ions, Dulal musib and his colleagues synthesized a novel 'turn-on' thiophene-based fluorescent probe 17 (Schiff-base of 2-aminophenol, thieno[2,3-b] thiophene-2,5-7,5 dicarbaldehyde). The probe showed enhanced fluorescence intensity in the presence of Zn 2+ , due to the aggregation-induced emission of probe 17 and Zn 2+ , whose luminescence was reduced by EDTA. Based on the outcomes, a logic gate was formulated for the selective detection of Zn 2+ ions.
Luminescence behavior in CH 3 CN at room temperature revealed that only Zn 2+ ions exhibited changes in the luminescent properties of the probe, which suggested the Metalto-Ligand charge transfer (MLCT) along with Aggregation induced emission (AIEE) [49,50] (Scheme 15). The AIEE Scheme 14 Proposed sensing mechanism of probe 16 for Cr 3+ and Cu 2+ Scheme 15 Detection mechanism of the fluorescent probe 17 towards Zn 2+ property could be visualized by the appearance of deep yellow from colorless with the increase in H 2 O concentration. It was observed that the addition of EDTA results in a 'turnoff' fluorescence by the formation of a strong Zn 2+ −EDTA complex [8]. Furthermore, fluorescent titrations showed that, upon the addition of Zn 2+ ions, the fluorescence emission band of probe 17 exhibited a redshift of 27 nm and a binding ratio of 1:1 was proposed.
Merlin Mary and Anandaram designed thiopheneappended carbohydrazide probe 18 as a 'turn-on' chemosensor for the detection of Zn 2+ ions. The free probe displayed two distinct absorption peaks at 330 nm and 412 nm in the UV-Vis spectra due to Intra ligand charge transition (ILCT) [51,52]. While, upon the addition of Zn 2+ to the probe in the DMSO/H 2 O mixture (v/v 6:4), a new peak at 445 nm was observed, which proved probe 18−Zn 2+ complex formation (Scheme 16) and was further confirmed by FT-IR studies.
Absorption spectral titration experiments revealed that the redshift could be observed for the probe 18-Zn 2+ complex with 1:1 binding stoichiometry and the LOD was found to be 1.51 × 10 −7 M. Moreover, significant color changes (light yellow to fluorescent yellow) were observed with fluorescence emission occurring at 1890 nm, due to the coordination bond formed between probe 18 and Zn 2+ , and the fluorescence enhancement could be attributed to the CHEF effect of the complex formed [53].
Although many probes have been synthesized for Zn 2+ and Hg 2+ ion recognition, thiophene-carbazole-based probes are utilized rarely. Hence, as a new approach, Ajit et al. incorporated thiophene moieties into the carbazole-based ratiometric probe 19. Distinct UV-Vis spectral behaviors were observed upon sensing of Zn 2+  redshift absorption bands followed by a naked eye visible color change from colorless to pale yellow upon the introduction of Hg 2+ ions. Job's plot indicated the 1:1 stoichiometry of probe 19−Zn 2+ /Hg 2+ complex (Scheme 17), and Zn 2+ binds to probe 19 by at least 1.17-fold stronger than that of Hg 2+ as confirmed by emission studies [54]. For increasing concentrations of Zn 2+ and Hg 2+ , the band at 418 nm gradually decreased and a new band at 520 nm is seen only for Hg 2+ along with a visual fluorescent color change. At the same time, the probe responds to Zn 2+ with distinct emission color change. The LOD for Zn 2+ and Hg 2+ was found to be 3.7 µM and 4.8 µM, respectively. Probe 19 demonstrated fluorescence bioimaging of raw cells, which was evident by the green fluorescence image of the raw cells in the presence of Zn 2+ ions. Therefore, the probe could be used as an intracellular bio probe for dual sensing of ions.
Phenanthroline-based chemosensors, having strong chelating abilities and robust conjugated π-systems, have received enormous attention in recent years. Zhang et al. synthesized a novel phenanthroline-thiophene based chemosensor 20 for Zn 2+ detection. The free sensor in Ethanol/ water (v/v 9:1) exhibits an absorbance band at 282 nm, 359 nm, and 375 nm due to the ICT mechanism. Nevertheless, in the presence of Zn 2+ ions, a new band is observed at 405 nm, accompanied by a red shift band, which is ascribed to LMCT between Zn 2+ and probe 20 and enhanced ICT process, respectively. The fluorescence spectra of the free probe displayed weak fluorescence at 422 nm, whereas this emission band showed a bathochromic shift of 461 nm with an exceptional fluorescence upon the addition of Zn 2+ , which could be attributed to the CHEF effect due to the complexation of the two 5-methylthiophene groups at the 3 & 8 positions of phenanthroline with Zn 2+ (Scheme 18). The binding mode of probe 20-Zn 2+ was proposed to be 1:2 stoichiometry, confirmed by ESI-MS spectra. The probe 20 could also sense ClO 4 − to a certain extent because of competitive coordination to Zn 2+ , thereby showing anionic interference, as evidenced by fluorescence quenching emission. Moreover, the probe could be employed in a broad pH range 2-10, evident by pH-dependent fluorescent [55] changes. Because of good cell permeability and reversible Zn 2+ sensing property of the probe, it could be employed for practical applications such as biosensing of Zn 2+ in living cells.

Copper
Copper is a trace element required by the body for various activities, such as behaving as a catalytic cofactor for diverse metalloenzymes. The deficiency of copper in the body can lead to anemia, impaired organ function, and Menkes disease  [56]. Contrarily, an increase in copper concentration beyond a limit can cause diarrhea, dyslexia, vomiting, headache, Wilson's disease, Alzheimer's, and Parkinson's disease [57][58][59].
Encouraged by sorting out the above problems, Sivalingam et al. synthesized a 'turn-on' thiophene-based schiff base (receptor 21). They evaluated its cation sensing properties in aqueous and biological samples since schiff base-type compounds are effectual metal chelators and could be utilized in fluorescent chemosensors. Receptor 21 could selectively detect Cu 2+ in aqueous samples in the presence of other ions, as evidenced by the color change in the colorimetric analysis and an effective fluorescence response. The UV-Vis absorbance spectra revealed that a new band was obtained at 370 nm with Cu 2+ ions (with the decrease in the band at 448nm exhibited by the receptor). The color and optical changes could be assigned to the coordination bond formed between receptor 21 and Cu 2+ ion by transferring lone pair of electrons of amine and imine into the empty Cu 2+ orbital (Scheme 19). Evaluation of potential applications of the receptor as a bio-probe for Cu 2+ detection in bio-imaging and bio-labeling research was achieved by demonstration of Cu 2+ recognition in living cells, by using E. coli. It was found that receptor 21 could behave as a nanomolar (0.423 nM) Cu 2+ sensor [57] with the binding constant of 4.23 × 10 5 , which closely matched with the results of DFT calculations.
Using the same design guide, Guangijie et al. synthesized a new fluorescent schiff base probe 22 based on naphthalimide and thiophene moiety. The UV-Vis absorbance spectra displayed a drop in the absorption peak at 465 nm upon the addition of Cu 2+ ions to the probe in CH 3 CN/HEPES (v/v 3:2) solution. The binding stoichiometry was determined to be in a 1:1 ratio, supported by ESI-MS spectra and Job's plot. The probe was found to be effective in broad pH range, confirmed by pH-dependent studies. Fluorescence spectroscopic studies showed that probe 22 exhibited a strong fluorescence emission intensity at 575 nm, which quenched Scheme 20 Plausible detection mechanism of probe 22 towards Cu 2+

Scheme 21
Possible mechanism for copper ion binding to probe 23 significantly only upon the inclusion of Cu 2+ ions, which could be due to its paramagnetic nature (Scheme 20). The LOD was determined to be 1.8 µM, and the probe showed an irreversible sensing mechanism upon EDTA addition as it failed to recover its fluorescent intensity. Furthermore, probe 22 could also be employed to detect Cu 2+ ions in live cells [60], evidenced by the significant quenching of the green fluorescence, thereby demonstrating that the probe had the ability of fluorescence imaging in vivo.
Another novel approach was put forward by Ayesha et al., who synthesized a novel pyrrolinone ester derivative-based hydrazone dye 23 and employed it as a multi-functional probe. The fluorescence emission spectra of the probe in EtOH/water (v/v 1:1) displayed a significant quenching only for Cu 2+ ions, thereby showing a 'turn-off' response due to probe 23-Cu interaction [61]. Furthermore, the UV-Vis spectra provided a new characteristic absorbance band at 542 nm with a color change to purple that corresponds to the probe 23−Cu 2+ complex (Scheme 21), and the absorbance band at 485nm (of Free probe) vanished. The detection limit was 0.85 µM, the association constant was reckoned to be 1.67 × 10 4 M −1 , with 1:1 stoichiometry. Reversibility studies were performed using EDTA, which suggested that the binding mode was reversible. Tekuri and Trivedi synthesized a series of thiophene-2-carboxylic acid hydrazide-based chemosensors, among which 24 (Thiophene-2-carboxylic acid (1 H-pyrrol-2ylmethylene)-hydrazide), and 25 (Thiophene-2-carboxylic acid isoquinolin-1-ylmethylene-hydrazide) responded for the detection of Cu 2+ and Cd 2+ ions. Chemosensor 24 displayed a striking yellow color only in the presence of Cu 2+ ions, and chemosensor 25 exhibited a yellow appearance only in the presence of Cd 2+ , as evidenced by the UV-Vis titration study which showed a decrease in the absorbance intensity of 24 at 335 nm and 25 at 320 nm, and a new absorbance band at 402 nm (in 24), 425 nm (in 25) upon titration with Cu 2+ and Cd 2+ ions, respectively. These changes are attributable to the change in structural conformation of chemosensors upon interaction with Cu 2+ and Cd 2+ , thereby demonstrating a coordinative interaction between the oxygen of carbonyl group and imine nitrogen in probe 24, whereas Sulphur and nitrogen in probe 25 respectively (Scheme 22 and 23). It was found that probe 24 and probe 25 exhibited a dynamic linear absorption response range, from 0 to 50 µM for Cu 2+ ions and 0-30 µM for Cd 2+ ions, with the LOD calculated to be 2.8 × 10 −6 M and 2.0 × 10 −7 M for Cu 2+ and Cd 2+ ions respectively [62]. The association constant was determined to be 7.8 × 10 3 M −1 for probe 24−Cu 2+  To detect copper in the aqueous system, Penchang et al. synthesized a thiophene-based colorimetric sensor 26. From the UV-Vis absorption spectra results, it was evident that only Cu 2+ increased the absorption band of the probe by 10 folds and displayed a prominent change in color from colorless to yellow in DMSO/H 2 O (v/v 1:1) solution due to the probe 26-Cu 2+ complex formation; whereas fluorescence quenching was observed due to the paramagnetic nature of Cu 2+ ions. The probe also exhibited anti-interference ability for the detection of Cu 2+ , and the working of the probe was found to be in a broad pH range (6-10). The binding constant was determined to be 6.55 × 10 4 M −1 with 1:1 stoichiometry of probe 26-Cu 2+ complex (Scheme 24) and the LOD was determined to be 0.217 µM. Furthermore, to scrutinize the practical applications of the probe, the TLC-based strip tests were executed by employing Cu 2+ solution in water. After introducing Cu 2+ on the TLC plate (immersed in probe in DMSO/H 2 O), color change from colorless to yellow [63] was noticed under sunlight, implying that probe 26 could function as a suitable tool for selective detection of Cu 2+ ions.
Thuy et al. synthesized thiophene appended anthracenebased fluorescent probe 27 for the detection of CuCl 2 . The probe was able to explicitly identify CuCl 2 from other metals since other metals exhibited intense blue fluorescence emission in the UV-Vis spectra. The fluorescence intensity at 460 nm decreased upon the introduction of 1mM CuCl 2 in DMSO solution, and complete quenching could be observed at 30 mM CuCl 2 , which could be attributed to the overlapping of the fluorescence wavelength of probe 27 and the absorption wavelength of CuCl 2 (Scheme 25). The binding between CuCl 2 and probe 27 was found to be in 1:2 stoichiometry [64] and the binding constant was found to be 0.0895 mM −2 .

Silver
Silver has been valued as a precious metal and has gained immense significance due to its potential applications in medicine, electronics and photography, catalysis, and nanochemistry [65]. Due to its widespread use, it possesses various entry routes into the body, primarily through ingestion [66], inhalation [67], and skin contact. Excessive silver ions Scheme 24 Sensing mechanism of probe 26 towards Cu 2+ Scheme 25 Photo-sensing mechanism of probe 27 towards Cu 2+ can integrate with amine, imidazole, and carboxyl moieties of different metabolites in the cytosol, consequently leading to undesirable effects on humans. Long-term exposure to silver can cause Argyrosis and Argyria [68].
Bhuvanesh et al. synthesized thiophene-based probe 28, which could detect Ag + in aqueous media. There was a substantial fluorescence enhancement of probe in CH 3 OH/ H 2 O (v/v 1:1) solution, indicating the possibility of ICT mechanism due to the coordination of Ag + with probe 28 in 1:1 binding stoichiometry. The pH and time response studies revealed the effectiveness of the probe over a broad pH range and a rapid response time, suggesting that it could be employed for Ag + detection in environmental and biological samples. The interaction is possible through ICT aided by the restricted torsional rotation between the C−C single bond of the probe (Scheme 26), which was confirmed by mass spectra and the LOD was estimated to be 1.28 × 10 −7 M. Moreover, to test and evaluate the potentiality of the probe in the detection of Ag + in biological applications, microscopic images of E. coli cells in the absence and presence of probe 28 and Ag + were compared; and observed that in the presence of Ag + , the probe displayed highly intense red fluorescence due to the probe [28-Ag + ] complex inside the cells, thereby enhancing the fluorescence intensity and it was hereby concluded that the probe could be employed in live-cell fluorescence imaging [69] for Ag + detection. Additionally, it was observed that the probe could also be used for monitoring Ag + ions in natural water samples, thereby paving a way for Ag + detection in both Aqueous and biological samples.
A successful novel approach was made by Xeong et al. who developed a thiophene-functionalized imidazophenazine based self-assembled supramolecular sensor 29 to evaluate the recognition towards Ag + . The sensor reacted with a color change from yellow to light purple upon introducing Ag + ions in DMSO/Water solution, accompanied by a redshift to 376 nm. Moreover from the fluorescence emission spectra, it was also noticed that the fluorescence intensity of the peak at 547 nm abruptly decreased with the addition of the Ag + to the solution, confirming the selective sensing and detection of Ag + ions over other interfering metal ions [70] (Scheme 27). Moreover, the 'on-off' mechanism was evaluated by the addition of I − ions to test the reversibility of the sensing mechanism, and was observed that the sensor could be considered an excellent on-off fluorescence sensor, which was evident by the alternating reviving and quenching processes in the fluorescence emission of the sensor 29-Ag + solution with 2:1 binding stoichiometry.

Scheme 26
Proposed binding mechanism of probe 28 to Ag + Scheme 27 Possible sensing mechanism of probe 29 towards Ag + The LOD was found to be 8.18 × 10 −9 M, which was much lower in comparison to the previously reported chemosensors.

Calcium
Calcium is the fifth most abundant element in the human body and is a significant component of the bone, where it is stored as calcium phosphate. Calcium ions partake in the biochemical and physiological processes of the cells. In contrast to its benefits, excess calcium in the biological system can result in hypercalcemia, leading to abdominal pain, bone weakening, muscle cramps, and other neurological symptoms.
To achieve chemosensors for the selective binding of calcium ions, Rihab et al. synthesized two electroactive tetraalkylated p-phenylenediamine chemosensors (30 and 31) relying on thiophene ligands. The cyclic voltammetry studies revealed that both chemosensors were selectively able to bind Ca 2+ ions over Zn 2+ ions. The free ligand exhibited two peaks, but only one peak was observed at a higher potential upon adding Ca 2+ ions. This could be ascribed to the oxidation of the Calcium complex, which is formed between Ca 2+ and two thiophenyl moieties and the nitrogen atom (Scheme 28). Furthermore, the calcium chelation resulted in a significant change in the transducer by larger anodic potential shifts, and the metal to ligand ratio [71] was found to be 1:2 suggesting a [Ca(L) 2 ] 2+ complex formation. Chemosensor 30, having the replacement of the dimethylamino group with the piperidinyl group, showed high selectivity towards Ca 2+ detection, evidenced by electrochemical studies.

Zirconium
Zirconium is widely used in ceramics, metal alloys, foundry equipment, the chemical processing industry, and electronic devices. Although, their regular use can produce high levels of residual zirconium ions, which consequently results in soil and water contamination. Inhaling zirconium compounds can give rise to pulmonary granulomas, skin and lung granulomas. Accordingly, it is crucial to develop chemosensors having high sensitivity and selectivity for the instantaneous detection of Zr 4+ ions in environmental and biological samples.
In this regard, Ajit et al. synthesized a novel pyridinethiophene appended rhodamine-based probe 32, and the recognition properties of the probe towards different metal ions were evaluated by spectroscopic studies using CH 3 OH/H 2 O (v/v 4:1) mixture. In the absence of metal ions, the solution of the probe was weakly fluorescent and colorless because of the ring-closed spirolactam, which then turned into deep orange upon introduction of Zr 4+ , due to the spirolactam-ring opening and generation of the delocalized xanthene moiety (Scheme 29). Emission and absorption titrations of probe 32 display fragile spectral characteristics in the emission spectrum, whereas the introduction of Zr 4+ ions enhanced the fluorescence intensity significantly with an intense orange fluorescent emission band at 582 nm. Moreover, the sensing mechanism was reversible upon adding EDTA due to the disappearance of the formed complex, and the LOD was calculated to be 16.99 µM.
Additionally, to demonstrate the practical bio-sensing capability of the probe, fluorescence imaging experiments were carried out in vivo in C. albicans cells. Fluorescence imaging was evaluated, which showed that probe 32 alone was non-emissive, but pollen cells loaded with Zr 4+ exhibited red fluorescence from the intracellular area. The evidence of the viability of cells (after loading with probe and Zr 4+ ) throughout the imaging experiment was confirmed by Bright field microscopy [72], indicating that the probe could be used for examining intracellular Zr 4+ in living cells.

Iron
Iron is the most necessary microelement responsible for the proper functioning of physiological processes in living organisms. Iron is an essential constituent of hemoglobin and myoglobin and is also required for growth, neurological development, cellular functioning, and synthesis of some hormones. However, excess Iron can cause Iron poisoning, whose symptoms include diarrhea, vomiting, abdominal pain, and other ill effects on humans.
To develop fluorescent chemosensors to detect Fe 3+ , Kannikanthi et al. synthesized a fluorescent chemosensor 33 [2,5-bis(4-phenylquinazolin-2-yl)thiophene]. The free Scheme 30 A suggested possible mechanism for sensing of Fe 3+ Scheme 31 A proposed binding mechanism for 34 towards Fe 2+ /Ni 2+ /Cu 2+ sensor in CH 3 CN displayed an absorption band at 362 nm, and it exhibited a color change from colorless to greenishyellow, and an occurrence of a new band at 419 nm, only in the presence of Fe 3+ ion. Fluorescence quenching at 427 nm upon the addition of Fe 3+ ions, which could be attributed to the ICT between thiophene and phenylquinazoline units along with the MLCT (Scheme 30) between the sensor and Fe 3+ ion in 1:1 binding mode. The LOD was calculated to be 1.6 × 10 −8 M. Reversibility equips the reusability of the chemosensor in practical applications, and hence reversibility studies were evaluated using EDTA. Upon addition of EDTA to the sensor 33-Fe 3+ complex, the fluorescence of sensor 33 is reimposed, thereby implying that the probe could be employed as a reversible sensor for Fe 3+ ions. Furthermore, to investigate its applications in nanoscale computations, the probe could also be employed to construct an inhibit-type logic function with Fe 3+ and EDTA being the chemical inputs and fluorescence emission [73] outputs at 533 nm.
Considering high photoluminescence properties of 1,3,4-oxadiazole moiety, Lohit Naik et al. synthesized a turn-off fluorescent chemosensor based on thiophene substituted 1,3,4-oxadiazole derivative 34, for the detection of multiple metal ions. The sensitivity of probe 34 in C 2 H 5 OH/ water, CH 3 OH/water, and CH 3 CN/H 2 O mixture (v/v 1:1) at pH 7.2, was investigated by UV-Vis absorbance spectroscopy. It was observed that, in all three mixtures, the absorbance peak and fluorescence emission peak of the probe were seen at 275 nm at 405 nm, respectively. It was observed that in the C 2 H 5 OH /H 2 O mixture, the fluorescence emission quenched to a greater amount upon the addition of Fe 2+ , owing to the paramagnetic nature of Fe 3+ and could be ascribed to the CHEQ mechanism. In CH 3 CN/H 2 O and CH 3 OH/H 2 O mixture, the absorbance peak accounted maximum for Cu 2+ at 225 nm and Ni 2+ at 400 nm, respectively, due to the CHEF mechanism (Scheme 31). The binding of probe and metal ions was in 1:1 stoichiometry and the detection limit for Fe 2+ , Ni 2+ , and Cu 2+ was calculated to be 2.977 × 10 −6 M, 0.895 × 10 −6 M, 0.593 × 10 −6 M, respectively. The detection time was quick [74] (<6.5 min) signifying that probe 34 can be implemented for the rapid detection of multiple metal ions. Owing to the paramagnetic nature of Fe 3+ , earlier reported fluorescent chemosensors functioned through fluorescence quenching mechanism, which was a considerable drawback in case in-situ monitoring and in vivo imaging [75]. As an out-turn, fluorescent and colorimetric probes operating by 'turn-on' response gained an enormous amount of attention. One such representative was the thiophenebased colorimetric sensor 35, developed by Jung et al. for the sequential detection of Fe 3+ / 2+ in a near-perfect aqueous solution. The sensor in bis-tris buffer showed distinct visual color changes from yellow to brown only upon the addition of Fe 3+ / 2+ , with significant spectral changes due to MLCT mechanism (Scheme 32) and a 1:1 metal ion/ligand complexation was proposed. The sensor could sense Fe 3+ at pH range 4-8, which was confirmed by pH-dependent studies, and could be employed as a recyclable sensor to detect Fe 3+ as evidenced by the reversibility studies using EDTA [76]. The LOD for Fe 3+ and Fe 2+ was determined to be 0.51 µM and 1.51 µM, respectively, which was lower than the EPA (Environmental Protection Agency) guideline for drinking water, indicating that sensor 35 could be employed in the real-time monitoring of Fe 3+ in drinking water.
As an innovative approach, Lieu et al. designed an N,Ndithenoyl-rhodamine based probe 36, for Fe 3+ recognition. All the tested cations except Fe 3+ didn't display any change in fluorescence spectra of the probe solution (CH 3 OH/H 2 O v/v 1:1) due to the closed conformation of the rhodamine spirolactam, whereas Fe 3+ ions showed a strong fluorescence band complemented by an immediate color change from colorless to pink, due to the ring-opening reaction of rhodamine spirolactam (Scheme 33). The fluorescence titration revealed that increasing Fe 3+ amount results in an Scheme 34 Detection mechanism of probe 37 for Fe 3+ /Hg 2+ ions Scheme 35 Proposed binding mode of Chemosensor 38 to Co 2+ (2:1) apparent peak at 588 nm, which further increased along with the color change from colorless to pink, suggesting the ring-opening of the rhodamine spirolactam [77] and the increased coordination interactions between Fe 3+ ions and Oxygen and Sulphur on the three amides and thiophene of probe 36 respectively, as confirmed by H-NMR analysis. It was found that the LOD was 3.74 µmol/L, and the binding stoichiometry between the probe 36-Fe 3+ complex was 1:1 ratio. Additionally, the probe could effectively detect Fe 3+ ions in living cells with good membrane permeability and less toxicity.
Very few multifunctional or dual-mode fluorescent chemosensors have been designed for the detection of Fe 3+ and Hg 2+ in aqueous media, and hence in this regard, Tau Sun and his colleagues synthesized an oligothiophene-Schiff based chemosensor 37, which could detect both Hg 2+ and Fe 3+ simultaneously. The fluorescence spectral studies were performed in CH 3 CN/H 2 O (v/v 4:6) since it was found that the probe was partially water-soluble. The usage of organic phase guarantees higher availability of sensor molecules in the medium. The free sensor exhibited weak fluorescence, which could be imputed to the PET process [78]. However, the addition of Fe 3+ /Hg 2+ ions to the sensor solution displayed an exceptional fluorescence enhancement at 520 nm due to the CHEF effect, and the fluorescence intensity increased with an increase in the amount of Fe 3+ /Hg 2+ ions, which could be attributed to the reduced PET process as a result of the complexation of sensor 37 with Fe 3+ /Hg 2+ (Scheme 34). The results obtained from the fluorescence spectra were in conformity with the results of the naked-eye experiment, which displayed the color change from light yellow to fluorescent green in the presence of Fe 3+ and Hg 2+ ions. The LOD for Fe 3+ /Hg 2+ was estimated to be as 3.52 × 10 −8 M and 5.0 × 10 −8 M. Besides, binding interactions studied by NMR, FT-IR spectral analysis, indicated a 1:2 metal/ligand binding stoichiometry and evidenced that phenol Oxygen, aldimine Nitrogen, and thiophene Sulphur of sensor 37 was entailed in the complex formation with Fe 3+ /Hg 2+ . Reversibility studies in EDTA indicated the irreversible binding interaction between the chemosensor and Fe 3+ and reversible interaction with Hg 2+ . Furthermore, the fluorescence intensity of the sensor 37-Fe 3+ /Hg 2+ complex exhibits a 'turn-on' emission in a pH range (4-12) and persists in the 'turn-off' emission in acidic pH (pH < 4), suggesting that the sensor could be employed in a wide pH range, by exhibiting distinct 'on-off' responses.

Scheme 36
Proposed binding mechanism of Chemosensor 38 to Cu 2+ Scheme 37 Plausible sensing mechanism of sensor 39 towards Co 3+

Cobalt
Cobalt is an ultra-trace element in the biological system and is a key constituent of cobalamin, better known as Vitamin B 12 , and is required for the proper metabolism of iron, and plays a crucial role in the hemoglobin synthesis [79]. Nevertheless, high or long-term exposure to cobalt can result in cancer, respiratory disorders, skin problems such as dermatitis, reduced cardiac output.
In this regard, Jung et al. synthesized thiophene-2carbohydrazide based chemosensor 38 and evaluated its sensing properties in aqueous media. The colorimetric detection of the sensor was investigated towards different metal ions at 400 nm in tris-buffer/DMSO (v/v 95:5) mixture. Amidst the tested metal ions, only Co 2+ and Cu 2+ exhibited immediate color change from colorless to yellow, in addition to distinct spectral changes. The UV-Vis titration revealed that the absorption band of chemosensor at 325 nm decreased remarkably, with the appearance of a new band at 400 nm, only for Co 2+ which can be attributed to the co-ordination of chemosensor with Co 2+ in 2:1 stoichiometry, further promoting Ligand to Metal charge transfer (LMCT) (Scheme 35 and 36). The LOD for Co 2+ was calculated to be 0.19 µM and the binding of chemosensor 38 with Co 2+ and Cu 2+ was found to be reversible with a chelating agent such as EDTA. Besides, the Co 2+ −2. (sensor 38) complex can be employed as a colorimetric sensor for CN − , which was evident from a color change of yellow to colorless [80] in the aqueous solution.
Chang et al. developed a thiophene-carboxamide-based colorimetric chemosensor 39 for detecting Cu 2+ and Co 2+ in a near-perfect aqueous solution. The sensor could selectively respond to Cu 2+ and Co 2+ ions by a color change from colorless to yellow at 417 nm. Furthermore, the binding properties of the sensor with Cu 2+ and Co 2+ ions were investigated through UV-Vis titrations, which revealed that the sensor 39-cation complex had 1:1 binding stoichiometry. There was no interference from other ions except Cu 2+ , during Co 2+ detection since Cu 2+ was tightly bonded to the sensor and this interference could be eliminated by adding excessive F − ions, which could be used to distinguish between probe 39-Cu 2+ and probe 39-Co 2+ complex by color change. The LOD for Cu 2+ and Co 2+ was found to be 0.14 µM and 0.88 µM, respectively. The possible mechanism for detecting Co 3+ (oxidation of Co 2+ to Co 3+ by O 2 molecules, based on ESI mass result) and Cu 2+ could be attributed to the ICT and LMCT mechanism (Scheme 37). Furthermore, the binding modes of the sensor to Cu 2+ and Co 2+ were found to be a 1:1 binding stoichiometry [81].

Palladium
Palladium is widely used in industrial processes due to its role as a catalyst in many organic synthesis reactions such as Suzuki coupling, Heck reaction, Wacker process. Although the toxicity of palladium is believed to be low, it coordinates with nucleic acids, proteins, and other macromolecules such as VitB 6 , thereby impeding many cellular functions if accumulated in the body.
Palladium ion has an open-shell electronic configuration and hence could behave as a fluorescence quencher and considering this aspect, Shally et al. designed thiophene appended tetrahydroquinoline-based 'turn-off' chemosensors 40 (with morpholino group) and 41 (with methylthio group). The UV-Vis spectrum shows the absorption peak at 390 nm and 378 nm for free 40 and 41 sensors respectively, but the peak at 390 nm faded and a new peak appeared at 325 nm for 40 whereas, the absorption peak of probe 41 at 378 nm vanished and a new peak was generated at 430 nm, upon the addition of Pd 2+ ions, as evidenced by the color change to yellow from colorless in probe 41 only. In the presence of Pd 2+ ions, both the fluorescence emission intensities of both sensors were significantly quenched, with probe 41 experiencing a more substantial quenching compared to 40. Job's plot suggested stoichiometry binding of both sensors with Pd 2+ ion is in 1:1 ratio. Besides, both were found to behave as bidentate ligands [82], by binding through Sulphur of thiophene and hydroquinoline N-atom to Pd 2+ (Scheme 38), as confirmed by HRMS spectra, NMR spectra, and DFT studies. The LOD of probes 40 and 41 was calculated to be 49 × 10 −9 M and 44 × 10 −9 M. These chemosensors illustrated better efficiency and promising results with a lower LOD.
It has also been observed that thiophene units as spacers in combination with crown ethers exhibit modulatory sensory behavior to obtain selective cationic (Hg 2+ , Pb 2+ , Cu 2+ , Pd 2+ ) chemosensors [83]. One such novel approach was made by Rosa et al. and wherein they synthesized new (oligo) thiophene bipendant-armed ligands and were assessed as chemosensors in the presence of Na + , Ag + , Pd 2+ and Hg 2+ in methane-sulfonic acid by spectrofluorimetric titrations. Compounds bearing bithiophene moiety were found to behave as a palladium chemosensor since enhanced fluorescence intensity was noticed. Subsequent additions of Na + and Pd 2+ gradually enhanced the emission band intensity, which could be attributed to the fact that complexation of Na + at the crown ether occurs, followed by interaction of Pd 2+ with sulphur atoms [84] of the bithiophene unit.

Cyanide
Cyanide ions are one of the most toxic ions because of their excellent binding ability with ferric (Fe 3+ ) ions in heme, which obstructs binding with reduced divalent ferrous (Fe 2+ ) ion and interrupts the electron transfer biological oxidation, causing internal asphyxia. The brain will be first damaged due to the condition of hypoxia, which consequently leads to respiratory problems and death [85]. Cyanide toxicity also induces convulsions, loss of consciousness. Because of its wide application in diverse sectors, developing a simple, quick method for detecting CN − ions is reasonably necessary. Dan Wen synthesized a novel chemosensor 42 for quick detection of cyanide (CN − ) ions. UV-Vis spectral studies confirmed that the absorbance band of 625 nm, exhibited by the sensor in CH 3 CN/H 2 O (v/v 1:1) gradually reduced, and new absorbance bands at 430 nm and 458 nm occurred, with a color change from blue to yellow only for CN − ions, which is attributable to the blocking of ICT between the hemicyanin moiety and sensor 42 due to the nucleophilic attack of CN ─ to indolium group (Scheme 39). Moreover, investigating the practical applications of the probe, it was observed that sensor 42 filter paper could detect CN − , which is evident by the color change from blue to yellow and the LOD was noted to be 0.89 µM [86], implying that the probe could be implemented for the detection of CN − ions.
Min  v 1:9) exhibited selectivity only towards CN − ions with a 1:1 binding stoichiometric ratio, which was evident by the increased fluorescence intensity in the fluorescence spectra. H-NMR spectroscopy studies, corroborated by DFT and TD-DFT results confirmed the mechanism of the sensing process, which displayed the deprotonation [88] of hydroxyl moiety on the phenyl part of the schiff base upon reaction with CN − ions (Scheme 41). Nevertheless, the reversibility studies were carried out in TFA, and the sensing reaction was found to be reversible. The detection limit for CN − ions in an aqueous solution was 0.32 µM, which was relatively lower than in organic media (LOD=1.69 µM). The results indicated that the chemosensor could quickly detect CN − via a di-deprotonation and ICT mechanism in the aqueous solution. Furthermore, the possibility of chemosensor being used in practical applications was evaluated using tap water, and it was observed that chemosensor 44 showed high-intensity green fluorescence on reaction with CN − ions, thereby paving the way for real-time monitoring of anions in aqueous and environmental samples. Moreover, the probe was also explored to be DNA-detection agent due to the intercalation of 44 into duplex DNA.
A ratiometric probe was reported by Ajit Kumar et al. wherein an indole conjugated thiophene-pyridyl-based probe 45 was employed for CN − detection. Fluorescence Titration of the probe with CN − exhibited a blue shift along with fluorescence quenching of the band at 619 nm and the emergence of a new band at 504 nm. The absorbance titrations exhibited spectral changes, with a noticeable color change from dark brown to colorless in the presence of CN − ions and could be assigned to the blocking of ICT due to the adduct formed by the nucleophilic addition of CN − to indolyl cation of probe 45 (Scheme 42); confirmed by TD-DFT calculations [89] and HRMS spectra, with 1:1 stoichiometric ratio between the probe and CN − ions. Furthermore, fluorescence competitive titrations were carried out, which revealed that the probe was highly sensitive towards CN − ions. For the practical application of the probe, the test paper strips based on probe 45 were prepared, which could detect CN − with an immediate color change. It could also be used for biomedical applications for sensing CN − at significantly lower concentrations.
Yan Zhao synthesized an off-on type fluorescent chemosensor 46, which has a triphenyl amine bearing thiophene derivative of benzothiazole as a CN − sensor. The free probe showed a broad absorbance band at 545 nm in PBS buffer in the UV-Vis absorption spectra, which decreased along with the emergence of a new band at 340 nm upon addition of CN − . It was also seen that strong 'turn-on' fluorescence enhancement is notable only for the CN − ions, without any interference by other anions. The Job's plot indicated a 1:1 binding mode between probe and CN − and the LOD for the CN − ions is 4.24 × 10 − 8 M. The fluorescence enhancement is ascribed to the interruption of ICT of the probe [90] due to the attack of CN − ions at the cyano vinyl group (Scheme 43), as corroborated by NMR studies and DFT calculations. Furthermore, probe 46 could be used in real-time monitoring of CN − ions by test strips in aqueous solution, evidenced by the color change from mild violet to light yellow-green fluorescence, under UV light only in the presence of CN − and could also be implemented for fluorescence imaging of live cells.
Numerous sensing mechanisms for CN − have been proposed for fluorescent chemosensors via different mechanisms, with nucleophilic addition being the highly selective mechanism to sense CN − ions. Utilizing this sensing mechanism, Zi Hua et al. synthesized and evaluated the sensing properties of a novel triphenylamine thiophene-based (with dicyanovinyl moieties) probe 47. The free probe exhibited pink non-fluorescent color due to the ICT mechanism [91], which further faded in the presence of CN − ions, accompanied by a fluorescence emission enhancement at 480 nm.

Scheme 44
Proposed sensing mechanism of probe 47 for CN − ions Furthermore, the UV-Vis absorbance spectra revealed that only for CN − , spectral changes and color change of light pink to colorless under naked-eye and bright blue under UV light was observed. The sensing mechanism is attributable to the nucleophilic addition reaction to form probe [47-CN − ] adduct (Scheme 44). Moreover, a low LOD was determined to be 51 nM, which indicates that the probe could be employed to detect low levels of CN − in drinking water, which also met the requirements of WHO for CN − detection. Additionally, probe 47 could be employed in bio-imaging to detect CN − ions in HeLa cells in a concentration-dependent manner, with lower cytotoxicity and good cell permeability.
In recent years, chemosensors relying on copper ion displacement for CN − detection have achieved significant attention. Successful examples are the coumarin-based schiff bases 48 and 49 chemosensors possessing furan and thiophene as the side groups respectively, developed by Kangnan and group. Both the chemosensors showed high affinity towards Cu 2+ ions, which was evident by the spectral changes and fluorescence quenching, indicating the complex formation of 48/49-Cu 2+ and PET processes, respectively. Moreover, probe 48/49-Cu 2+ complex could detect CN − ions, with obvious and immediate color change from red to yellow-green, which is assigned to the strong binding ability of Cu 2+ towards CN − ions, consequently resulting in the Cu 2+ removal from the complex and recovery of the probes, thereby showing the copper displacement mechanism [92] (Scheme 45). The detection limits of probe 48-Cu 2+ and 49-Cu 2+ for CN − were 0.019 µM and 0.02 µM, respectively. The reversibility of these chemosensors was evaluated and was found to exhibit a 'turn on-off' mechanism with the introduction of CN − . Therefore, both probes could be re-used several times for CN − detection.

Fluoride
Fluoride is naturally present in the human body in bones and teeth and drinking water is the primary source of fluoride ions. However, excess fluoride is hazardous and can be detrimental to life by causing severe dental fluorosis or skeletal fluorosis [93]. It is highly beneficial to develop a highly effective chemosensor that can selectively detect F − ions with the naked eye response.
One successful approach was made by Renuga et al. who synthesized fluorescent receptor 50 [2,20 -(1E,10 E)-(thiophene-2,5-diylbis(methan-1-yl-1-ylidene)] for selective detection of F − ions in the presence of competing anions in CH 3 CN. A color change was observed from fluorescent green to orange in the presence of F − ions only, which could be attributed to the H-bonding between the OH − group of receptor 50 and F − ions (Scheme 46). Upon using spectrophotometric techniques, a new red-shifted absorption band centered at 520 nm was observed for an increase in F − ions [94], which could be explained by the Internal Charge Transfer mechanism. The binding constant was calculated as 1.3 × 10 3 and the binding between the receptor and anion was in 1:1 binding stoichiometry. Further, fluorescence spectra displayed that the receptor produced a strong emission band at 510 nm and 545 nm because of its strong fluorescent nature, manifesting that the chemosensor can be utilized to detect F − in the presence of competing anions.
Few Thiophene derivatives have also been reported for the sensing of anions, due to their optical property. For instance, Ufuk Yanar et al. synthesized novel coumarinacetamido thiophene-based colorimetric and fluorometric chemosensor 51 for ratiometric sensing of anions. The chemosensor exhibited visible colorimetric changes (color change from light yellow to deep yellow) and emission quenching in the presence of CN − , F − and AcO − in DMSO. Nevertheless, the probe was more sensitive to CN − than F − and AcO − at the stoichiometric binding ratio of 1:2:5. Molecular orbital analysis was studied, which explained that the fluorescent property and the quenching property of probe 51 were because of the π -π* transition on coumarin and charge transfer transition from donor to acceptor unit, respectively. The mechanism of fluorescence quenching was due to ICT [95] (Scheme 47), which was supported by Computational studies.

Scheme 45
Suggested detection mechanism of probe 49 for CN − ions An innovative approach was made by Neeraj et al. who attempted and succeeded in controlling the selectivity of the sensor by modification of the side groups of the hydrazone Schiff bases of sensors, which were derived from 1,8-naphthalimide and substituted furan/ thiophene ring systems. All four sensors responded selectively to F − and CN − ions with an abrupt color change from yellow to blue. The fluorescent emission intensity was quenched significantly with negligible interferences from other tested anions. It was concluded that a stoichiometric binding ratio of 2:1 exists between probes 52/53 (having thiophene/ furan rings respectively) and F − ions, while 1:1 binding mode exists between probes 54/55 (having furan with -NO 2 and furan with -CH 3 group respectively) with F − and CN − respectively. Sensors 52 and 53 were found to exhibit the lowest detection limit of 0.04 ppm and 0.07 ppm for F − and CN − ions. Moreover, the mechanism of detection was due to the Hydrogen bonding succeeded by deprotonation, resulting in the ICT process. In addition, discriminative detection of anions was performed with Cu 2+ ions, and it was found that sensors 54 and 55 exhibited selective recognition of F − over CN − ions; which was evident by spectral changes and the 'naked eye' color change from bright yellow to dull yellow, whereas yellow to green for sensor 54 and 55 respectively [96]. Only sensors 54 and 55 could effectively detect both F − and CN − , whereas 52/53 was less effective in CN − detection because of the loss of CN − fluorescence by the addition of other anions. The applicability of sensors was examined by test strip experiments, which exhibited significant color changes upon the detection of F − /CN − ions.
Following the same design guide, Siddarth et al. synthesized a new bis Schiff base 56 with dual -NH functionality for F − detection. The chromogenic response of the probe in CH 3 CN solution was found to be selective to F − over other anion analytes, which was evident by the naked-eye color change from colorless to red. The UV-Vis absorbance spectra of the free probe exhibited two peaks at 260 nm and 380 nm, which were then subjected to red-shift along with the occurrence of a new band at 478 upon the addition of F − ions. The sensing mechanism could be assigned to the Hydrogen bonding and deprotonation [97] between probe 56 and F − ions (Scheme 48) with 1:2 stoichiometry, corroborated by H-NMR studies and DFT studies. The LOD was calculated to be 6.9 × 10 −7 M, with a response time of 20 s, thereby meeting the requirements of real-time monitoring of F − ions.
Recently, various AIEE based fluorescent dyes based have been synthesized, since they could be an efficient optical tool exhibiting distinctive properties with promising results, and therefore could be employed in bioimaging, Scheme 46 Probable sensing mechanism of 50 towards F − ions Scheme 47 A suggested mechanism for the detection of anions by 51 organic light-emitting devices, and chemosensors. One such approach was made by Pranjalee et al. who synthesized a pyrene-thiophene-based probe 57 based on the AIEE property for F − detection. The probe exhibited a new peak at 450 nm with a hypochromic shift in the UV spectra, along with the visible color change from colorless to bright yellow upon interaction with F − ions, without the perturbation of detection by other anions. Furthermore, the UV-titration experiments revealed a new peak at 450 nm, which indicates H-bonding between F − and probe 57, thereby inducing the deprotonation of NH group with increasing F − ion concentration, resulting in push-pull effect, further confirmed by NMR and DFT studies. The binding mode was found to be in 1:1 stoichiometry ratio, and the LOD was estimated to be 2.02 × 10 −7 M. The AIEE property of probe 57 was evaluated in the CH 3 CN/H 2 O mixture and could be attributed to the hindered intramolecular rotation and the formation of J-type aggregates [98] (Scheme 49) which suppresses the non-radiative decay of excited state. The potentiality of the sensor to sense F − was also evaluated by test strip experiments. The sensor displayed a visible color change of strips from colorless to yellow (under UV light) upon detection of F − , thereby signifying its potential application for F − recognition.
Presumably, Thienothiophene (TTs) moiety has rarely been employed as a donor group in Donor-Acceptor systems possessing excellent sensing properties. Thienothiophenes is one of the structurally derived thiophene isomers, which has an electron-rich conjugated structure, and is integrated with polymers and other small compounds to enhance their photophysical and electronic properties, thereby upgrading the device performance. In the past few years, thiophenes bearing electron-deficient borane in the main and side chains of oligomers, and polymers have gained significant importance, and representative examples are the chemosensors 58 and 59, possessing conjugated thieno[3,2-b]thiophene and cross-conjugated thieno [2,3-b]thiophene, developed by Gulsen et al. for F − detection. The vital photophysical behaviors of both sensors were due to the ICT mechanism between thienothiophenes and two bulky dimesitylboron units. Sensor 58 exhibited exceptional bathochromic shifts in both absorption and fluorescence spectra as compared to sensor 59. Furthermore, both sensors showed positive emission solvatochromism with an increase in solvent polarity owing to their quadrupolar structures. Among the two sensors, 58 was found to be an efficient blue emitter. The characteristic spectral changes in the absorption and emission spectra and noticeable color change were observed upon binding of only Lewis base F − to the Lewis acid organoboron group [99]. The results concluded that probe 59 responded through turn-on and probe 59 responded through 'turn-off' response, thereby possessing high sensitivity and selectivity toward F − anions without interference from other anions. The high quantum yield, good solvatochromic behavior, and intense interaction with F − anions entitle these compounds to be used as potential luminescent chemosensors.
One more similar approach was made by the same group of researchers Gulsen et al. who synthesized four novel Organoboron copolymers consisting of thienothiophene and selenothiophene analogs with thiophene π-spacer. The sensors 61 and 63 having cross-conjugated selenopheno [2,3b]thiophene and thieno[2,3-b]-thiophene, respectively Scheme 48 Proposed sensing mechanism of probe 56 for F − ions Scheme 49 Proposed detection mechanism of 57 for F − ions exhibited weak spectral changes due to the poor electronic couplings of cross-conjugated donors and mesityl boron acceptor in the polymer chain. In contrast, probes 60 and 62 exhibited strong spectral changes in the UV-Vis absorption spectra. Furthermore, it was found that probe 60 exhibited the lowest bandgap as compared to the other copolymers, and it also exhibited the largest stokes shift [100]. All sensors exhibited a turn-off response accompanied by a color change from yellow to colorless, among which probe 63 showed selective sensitivity of F − because of the presence of less polarizable sulfur atom of thiophene compared to selenium and its cross-conjugated structure. Therefore, these copolymers could be employed as promising candidates for F − detection.

Iodide
Iodine is a trace element, which mainly exists in the form of iodide in the human body, and is involved in biological functions, for instance, thyroid gland function. Apart from that, elemental iodine has been exploited in diverse applications, for instance, in the manufacturing of dyes, synthesis of some organic chemicals, and medicine. On that account, it is crucial to develop sensitive chemosensors to detect I − in food, pharmaceutical products, and biological samples.
Kannikanti et al. synthesized a turn-off fluorescent chemosensor 64 [2,5-bis(4-phenylquinazolin-2-yl) thiophene] for the sensing and detection of I − ions. The recognition of probe towards anions was studied by absorption and emission spectra, which revealed that the spectra remained unaltered until I − ion was added to the CH 3 CN solution of the probe. The absorption of the probe was observed at 291 nm and 362 nm with a color change from colorless to yellow. Correspondingly, the fluorescence emission intensity of the probe quenches upon interaction with I − ion with 2:1 stoichiometry. The LOD for I − was found to be 1.7 × 10 −7 M [73]. Furthermore, to evaluate its potentiality in practical applications, probe 64 was utilized to construct a field test kit for the qualitative analysis of I − in aqueous samples.
Syed et al. synthesized a novel thiophene-based tripodal copper (II) complex receptor 65 to detect halides. It showed distinct color changes in CH 3 CN solution from blue to aqua, lime, turquoise, and greenish-yellow in the presence of F − , Cl − , Br − , I − ions, respectively. The binding properties of the receptor were evaluated by UV-Vis titration experiments, which exhibited a 1:1 stoichiometric complex of receptor 65 with each halide. Furthermore, it was observed that the receptor responded distinctly to different halides concerning the intensity and absorption maximum, due to axial ligation of the respective halide to the coordinatively unsaturated Scheme 50 Proposed halide bound complex Scheme 51 Possible mechanism of probe 67 binding to Bisulphite copper center, resulting in the halide complex formation (Scheme 50). The order of receptor 65 bindings to the halides was observed in the order of F − >Cl − >Br − >I − , which is ascribed to the basicity of the respective halide. Along with this, the effect of solvent polarity on receptor was studied by using CH 3 CN/H 2 O mixture in addition to CH 3 CN, and it was found that the receptor-halide complex showed a weaker binding trend compared to the observed binding trend [101] in pure CH 3 CN, because of increasing solvent polarity.
Conjugated polyelectrolytes have acquired significant attention for many years because of their optical properties and potential applications in optical sensors and biological imaging. They exhibit outstanding characteristics, for instance, their energy transfer which is quite useful as biomarkers by fluorescence quenching and FRET mechanism, high sensitivity, and selectivity by electrostatic binding to target analytes. Moreover, diblocked copolymers of polythiophenes (PT) and Polyflourene (PF) are valuable, versatile materials. One such representative is the conjugated AB diblock copolymer 66 [poly [9,9- The absorbance spectrum of the free sensor exhibited structured emission at 400-500 nm and 520-500 nm due to the PF and PT units, respectively, along with distinct fluorescence emission resulting from incomplete energy transfer between the PF and PT units [102]. The halide sensing of probe 66 was evident by the decrease in fluorescence quenching of the PT unit in the presence of halides, clearly following the quenching order of I − > Br − > Cl − , which could be attributed to heavy atom effects and electron transfer. Nevertheless, the sensor could also be employed for DNA quantification by the formation of nanostructured networks.

Bisulphite
Bisulfites have various applications in wastewater treatment, in the prevention of corrosion, and in DNA sequencing. They also play an essential role in pharmaceuticals, food, and beverage industries since HSO 3 − can hinder oxidation, microbial and enzymatic reactions. However, anthropogenic activities ensue a substantial input to the atmospheric burden of sulfur compounds regionally and globally, which could be threatening to human health and the environment. Sulfur dioxide (SO 2 ) is one such primary air contaminant. When inhaled can be converted into bisulfites and sulfites, thereby causing asthmatic attacks, negatively influencing cardiovascular diseases and lung cancer allergic reactions if inhaled excessively. Therefore, there is a high demand for the development of chemosensors for HSO 3 − detection. having two different end groups being phenyl and thiophene moieties respectively, which were capable of detecting sulphite anions. Both the probes exhibited weak ICT fluorescence, which is obstructed after the nucleophilic sulfite ion attachment to the α, β-unsaturated ketone part of the probe, confirmed by NMR and DFT studies. Subsequently, a blue shift of the absorption and emission spectra of the probes was seen, corresponding to a visible naked eye color change from orange to colorless. Among the two probes, 69 was found to be effective in the selective detection of HSO 3 − by significant quenching due to the presence of the thiophene group (Scheme 52). Nevertheless, the practical application of the probes was illustrated by utilizing a paper test strip method for HSO 3 − detection. It was observed that the paper discolored from orange or yellow to blue [104], confirming its potentiality to detect HSO 3 − in water samples. In this study, a simple replacement of end groups by thiophene surpassed the response time by 1.2 times and the detection limit by 1.5 times.
Encouraged by the need for water-soluble fluorescent chemosensors, Chak Shing et al. synthesized a Thiophenebenzimidazole-based chemosensor 70 to detect S 2− ions in Water. The strong blue fluorescence of the free probe was observed to be quenched due to the formation of the probe 70-Cu 2+ ensemble (Scheme 53). It restored fluorescence by the presence of S 2− anions (4 equivalents) only, exhibiting a 'turn-on' response. The LOD of 71-Cu 2+ towards S 2− was found to be 354 nM. Furthermore, Cytotoxicity studies of live cells revealed that the probe showed low toxicity and could be a potent sensor for detecting S 2− intracellularly [105] with an excellent cell permeability, thereby showing potential applications in biological systems.
Although few sensors have been reported for sulfite anions, dual-channel chemosensors for the detection of hydrogen sulfite are quite limited, and hence as an emerging approach, Xiaohong et al. designed a series of compounds possessing electron-donating thiophene moieties attached to triphenylamine (TPA) with aldehyde groups. Only probe 71, having ethylene dioxy-thiophene and a thiophene group, could exhibit spectral changes in the UV-Vis spectra along with a notable color change from yellow to colorless for HSO 3 − ions. Furthermore, it was found that probe 71 could selectively detect HSO 3 − ions over other anions, which was evident by the color change from yellowish-green to blue, attributable to the nucleophilic addition of the aldehyde to hydrogen sulfite resulting in aldehyde-hydrogen sulfite adduct [106] (Scheme 54), thereby tuning the ICT efficiency, and this mechanism was corroborated by ESI-MS spectra. The detection limit was determined to be low as 0.9 µM, which was indicative of the higher sensitivity of the probe towards HSO 3 − anions.

Hypochlorite
Hypochlorite is widely being used in industries and households as an effective cleaning agent to remove stains and whiten clothes, disinfectants, and air fresheners. One of the most potent oxidizing agents is sodium hypochlorite, which is mainly used as a bactericide to treat drinking water and eliminate foul odors. The residual reactive chlorine formed during the disinfection of water can form disinfection carbohydrazide. An instant 'naked-eye' color change of the probe in Tris-HCl buffer solution, from colorless to pink, and the appearance of red fluorescence (λ excitation = 365 nm) under UV light, upon the addition of ClO − ions was indicative of the ring-opening reaction of the spirolactam of rhodamine (Scheme 55). Besides, a new absorption peak and fluorescence peak at 556 nm and 578 nm emerged, which further suggested that ClO − could persuade a ring-opening reaction of rhodamine moiety, verified by HRMS spectra. Hypochlorite titration experiments were also performed, in which the probe exhibited spectral changes with increasing concentrations of ClO − ions along with deepened color change. It exhibited a fast response time of 10 s with a detection limit of 7 µmol/L. Furthermore, the practical application of the probe was tested for aqueous samples by filter paper strips, which showed a color change upon detection of ClO − ions. It was also observed that probe 72 could be used for fluorescent bioimaging and mitochondrial targeting [107] of HeLa cells, thereby being an effective tool for monitoring ClO − ions.

Thiocyanate
Thiocyanate is pervasive and abundantly found in the extracellular fluids of mammals and enters into the body primarily from the diet. Thiocyanate serves various applications as additives or starting materials for dye synthesis, chemical tracers and finds applications in textiles and manufacturing industries. However, thiocyanate toxicity symptoms have been related to the nervous system, such as motor impairment, anxiety, thyroid gland disorders such as hypothyroidism, skin, and kidneys. Despite the prevailing circumstances, the development of chemosensors for SCN − detection is minimal.
One successful attempt was the probe 73 [4-methyl-2,6-bis((thiophen-2-ylmethylimino)methyl)phenol], developed by Sudipta et al. for SCN − detection. The absorption spectrum of free probe in H 2 O/CH 3 OH (v/v 1:4, HEPES buffer) solution exhibited two intense peaks at 350 nm, and 450 nm, which gradually diminished and increased respectively, upon the addition of SCN − ions and this is attributable to the CH=N isomerization. Furthermore, the fluorescence emission intensity enhanced along with a blue shift upon SCN − addition and the detection of SCN − was not affected by other bio-relevant anions. The SCN − recognition could be ascribed to the Hydrogen bond formation [108] between probe 73 and SCN − ion and 1:1 stoichiometry were proposed. The probe's LOD for SCN − was found to be 0.88 µmol/L with a quick response time (<5 min). Although diverse, efficient colorimetric sensors have been reported for anion detection and sensing, their applicability towards the real specimens or samples, is still limited. In this regard, Sivalingam et al. synthesized a thiophenebased dihydrazone derivative probe 74 to detect anions in an organic and aqueous medium. Among all anions, the probe exhibited strong affinity towards F − , AcO − and H 2 PO 4 − ions in DMSO/H 2 O (v/v 10:0 & v/v 9:1), evident by a visual color change from orange to violet and yellow to brown in aqueous and organic medium, respectively, along with a strong absorption band at 590 nm. Probe 74 gains importance in sensing AcO − in any form such as TBA acetate, transition metal acetate, and sodium acetate in the aqueous medium. The sensing mechanism can be assigned to the hydrogen bond formation between N-H and AcO − ions (Scheme 56) with a 1:1 stoichiometry binding mode [109] for all receptor-anion complex. Ultimately, the probe could qualitatively estimate F − and AcO − in real samples such as commercially available toothpaste and vinegar samples by colorimetric technique.
Oligothiophenes have excellent photophysical properties, such as their intrinsic fluorescence and simplistic polymerization properties, due to which it has received considerable attention. Despite their advantageous properties, small efforts have been put forward for the development of oligothiophene-based fluorescent chemosensors. One such great effort was put forth by Dae et al., who reported efficient turn-on oligothiophenebased fluorescent chemosensors ( 75 and 76) for the detection and sensing of carboxylate anions with a binding mode of 1:1 stoichiometry. Both sensors exhibited fluorescence quenching in CH 3 CN due to the n − π* transition of the trifluoroacetophenone group. In contrast, they exhibited remarkable fluorescence  , among which the selectivity of probe 75 was highest for AcO − , evident by a slight bathochromic shift. The fluorescence enhancement could be accounted for due to Carbonyl adduct formation, supported by H-NMR and F-NMR studies, and the sensing mechanism was through the elimination of n − π* transition and presence of intramolecular Hydrogen bonding [110] (Scheme 57) which enhances the conformational rigidity of the adduct, thereby promoting fluorescence enhancement. Therefore, these highly efficient fluorescence turn-on chemosensors could be further explored in biomolecules for Carboxylate anion detection.
Chemosensors have been a powerful tool pertaining to its ease of use, reliability and practical applicability. High selectivity and sensitivity of the chemosensors is achieved by introducing various moieties to the fluorophore core system. In the current review, we have listed out thiophene based fluorescent and colorimetric chemosensors (Table 1) along with their detection of ions, LOD and their applications.

Conclusions
There is ever-growing research on the design, synthesis, and improvement in the sensitivity and detection of the various ions in the environmental and biological systems. Thiophene-based fluorometric probes have become an essential tool in detecting anions, cations, and neutral molecules because of their significant characteristics such as extended emission and absorption wavelengths, vast absorption co-efficient, and more fluorescence quantum yield. Consideration of the reviewed data shows that thiophene moiety in combination with other heterocycles has achieved significant interest. The sensing of molecules can be done when thiophene is used as a fluorophore moiety or a signaling unit to behave as a fluorescent "Turn off"' or "Turn On" chemosensor, when combined with other heterocycles, during the detection of analytes of interest. Although, the substitution needs to be carefully selected in order to obtain excellent results as well as take the benefit of the optical and chelating properties of the probe. The mechanism of sensing of various cations and anions and the reversibility of the interaction mechanism has also been reviewed.
Author Contribution Rikitha Sharyl Fernandes: Collection of data and drafting the manuscript. Nitinkumar Sudhakar Shetty: Design of the work, drafting and critical review. Priyanka Mahesha: Fine tuning and data analysis. Santhosh Laxman Gaonkar: Data interpretation and review.
Funding Open access funding provided by Manipal Academy of Higher Education, Manipal.

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The authors declare that there is no conflict of interest.
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