Recent advances in the application of isoindigo derivatives in materials chemistry

In this review, the data on the application of isoindigo derivatives in the chemistry of functional materials are analyzed and summarized. These bisheterocycles can be used in the creation of organic solar cells, sensors, lithium ion batteries as well as in OFET and OLED technologies. The potentials of the use of polymer structures based on isoindigo as photoactive component in the photoelectrochemical reduction of water, as matrix for MALDI spectrometry and in photothermal cancer therapy are also shown. Data published over the past 5 years, including works published at the beginning of 2021, are given.


Introduction
Among three isomeric bisoxindoles, isoindigo has recently attracted the greatest interest (Scheme 1). The first studies on this class of compounds were related to the field of medicinal chemistry since a number of isoindigo derivatives were found to be highly active against leukemia [1][2][3]. However, to date, the volume of publications on the study of the biological activity of isoindigo derivatives has been steadily decreasing.
At the same time, the unique properties of the isoindigo structure (planarity, stability, a high degree of conjugation, and electron deficiency) began to attract more and more attention of many research groups. In addition, the ease of modification, such as at the endocyclic nitrogen atom as aromatic fragment of isoindigo, makes it possible to fine-tune the electronic properties. These factors led to the beginning of many studies on isoindigo as a platform for the construction of polymeric materials for various purposes.

Review Organic solar cells (OSCs) on the base of isoindigo derivatives
Since the pioneering works on the use of isoindigo derivatives in the design of OSCs [3][4][5], specialists in this field have made significant progress in tuning and improving their properties [6][7][8][9][10][11][12]. The main photophysical characteristics that determine Scheme 2: Isoindigo-based OSCs with the best efficiency. the effectiveness of OSCs are open circuit voltage (V OC ), shortcircuit current (J SC ) and fill factor (FF). In addition, the solubility of isoindigo derivatives in organic solvents is very important since this affects the morphology of thin films of the photovoltaic cells. To date, the maximum efficiency of 12.05% has been shown by an OSC based on a composite of a donor poly-thiophene and an acceptor polymeric dicyanoindanone derivative [13]. Among the derivatives of isoindigo, the leading compounds are polymers 1-3, which were used in the design of OSCs as donor components of the active layer. Their power conversion efficiency (PCE) reached more than 8%. The development of an OSC based on low-molecular-weight derivatives of type 4, containing only one isoindigo fragment, also seems promising (Scheme 2).
One of the areas of research is the design of low-molecularweight structures containing one or two isoindigo fragments in a unified conjugated electronic system. Currently, to improve the key characteristics of OSCs, some directions of studies are related to the design of substituents both on the heterocyclic platform (in position 1 and in the aromatic ring) and in the side chain. In the overwhelming majority of works, studies on the photophysical properties of isoindigo derivatives containing a thiophene fragment in position 6 are described. Thus, the authors of References [14,15] obtained a small number of simple representatives of symmetric dithiophene derivatives of isoindigos 5a-c (Scheme 3). The constructed solar cells with an active layer based on a mixture of compounds 5 (donor) and PC 61 BM (acceptor) in a 1:1 ratio showed the dependence of the Scheme 3: Monoisoindigos with preferred 6,6'-substitution. efficiency on the structure and position of substituents in the aromatic fragment of isoindigo. In the presented series, the system based on compound 5b with an efficiency of 1.25% turned out to be the best.
It was found [16] that 6,6'-substitution of the isoindigo core is preferable due to the possibility of the formation of a quinoid structure after irradiation with sunlight, which facilitates the transport of electrons through the system (Scheme 4). Certain nitrogen heterocycles can be inserted into the substituent chain as an acceptor structural unit (Scheme 5). For exam-ple, an OSC based on a symmetrically substituted isoindigo derivative 4 containing a diketopyrrolopyrrole fragment in a mixture with PC 71 BM showed a record efficiency of 5.86% among oligomeric isoindigo [17]. At the same time, similarly constructed (D-A-D-A) oligomers 6 in the composition with PC 71 BM showed an efficiency of 1.3-1.4% [18].
Another way to design isoindigoid OSCs is the introduction of aromatic substituents of variable nature into the oligomer structure. By the example of pyrene derivatives 7 and 8, the dependence of the binding type of the aromatic fragment to the isoindigo core was revealed. The synthetic procedure for the preparation of these monoisoindigoid derivatives is based on the Suzuki reaction. At the same time, pyrene-1-ylboronic acid and 6,6'-dibromoisoindigo were used to introduce a pyrene fragment directly into the isoindigo nucleus, and to obtain a thiophene analogue, pyrenyl-substituted 2-bromothiophene and 6,6'-bis(4,4,5,5-tetramethyl-1,3,2-dioxaborolan-2-yl)isoindigo were used (Scheme 6). Thus, a photovoltaic cell based on thiophene derivative 7 mixed with PC 71 BM showed an efficiency of 1.88% [19], but if the pyrenyl substituent is bonded directly to the isoindigo core, the efficiency of such an OSC turns out to be significantly lower (0.10%) [20]. One of the highest efficiency values (4.7%) among low-molecular-weight isoindigo derivatives was shown by a two-component OSC based on isoindigo 9a, containing an alkoxylated p-phenylene fragment and PC 71 BM in a ratio of 1:0.7 (w/w), a thin film of which was obtained from chloroform with 0.5 vol % N-methylpyrrolidone (Scheme 7). As the authors believe [21], the addition of this viscous solvent made it possible to provide a better surface morphology of a thin-film layer since without it, the efficiency was almost two times lower (2.8%). Therein, the key role of the structure of the acceptor terminal substituent was also revealed since a similar OSC based on the rhodamine derivative 9b showed an efficiency of only 0.66% (Table 1).
It is important to note that the replacement of the thienylphenylene spacer in structure 9a by the acceptor indan-3-dicyanoethylidene-1-one-2-ylidene fragment in compound 9c led to a decrease in the efficiency to 2.82% [22].
Perylene diimide-derived isoindigo derivative 10 was used as an acceptor in the creation of a nonfullerene OSC with thiophene polymer 11 as a donor component (Scheme 8). The PCE value of such a device turned out to be 2.6%.
Cho et al. constructed a three-component cell in which the active layer consisted of a donor 11 and a polymeric acceptor based on perylene diimide 12 [23]. One of the simplest thiophene derivatives of isoindigo 13 was used here only as an additive (10 wt %), leading to an increase in efficiency from 5.9% to 6.8% (Scheme 9). Using a variety of physical methods, it has been proven that the presence of isoindigo 13 in the three-component mixture provides tighter packing of the thin layer and larger crystalline domains. This, in turn, leads to an increase in the decay time of the exciton and, as a consequence, to a high J SC value.  Thus, in the series of thiophene-centered bisisoindigos 14a-d, the best efficiency values were shown by OSCs containing an odd number of thiophene units (14a: 2.16%; 14c: 2.40%) [24]. A cell based on compound 15b showed a close value of efficiency (2.25%) [25]. At the same time, incorporation of the tetrafluorophenylene fragment into the center of the molecule 14a and the presence of a branched alkyl substituent at the nitrogen atom made it possible to improve the characteristics of the cell [26]. After annealing such an OSC at 80 °C, the efficiency was increased from 3 to 3.18%. It should be noted that in all cases mentioned here, PC 71 BM was used as the acceptor component of the OSC active layer. The photovoltaic characteristics of the OSCs based on compounds of this type are summarized in Table 2.
It has been shown that oligomeric isoindigos that do not contain a thiophene fragment can also be used as donor components of the OSC. The synthesis of such compounds is also based on the Suzuki coupling reaction between alkylated 6,6'-dibromoisoindigos and corresponding arylboronic derivatives, leading to the formation of target molecules in moderate yield (Scheme 11). In these compounds, the triarylamine substituent is linked either directly to the isoindigo core or via a vinylphenylene bridge (see compounds 17a,b) [27,28]. The presence of the latter determines the cell efficiency to be an order of magnitude higher (3.57%) then when using 16a and 16b.
In the chemistry of isoindigo-based materials, the most popular and most studied direction in the creation of OSCs is the use of   polymer structures containing an isoindigo fragment in a monomer unit associated with a different number of thiophene substituents (Scheme 12).
By the example of one of the simplest representatives of this type of polymers, a significant effect of the structure of the substituent at the nitrogen atom of the heterocycle on the OSC efficiency was also shown [29,30]. Thus, fluorine-substituted polymers 18a,b in the composition with PC 61 BM showed a PCE of only 0.9-1.4%, while an OSC based on ethoxylated derivative 19a was characterized by a high short-circuit current (J SC = 13.92 mA/cm 2 ), with a 5-fold better PCE value ( Table 3).
In the course of further studies, the key influence of the nature of both the substituent at the nitrogen atom of isoindigo and at the bithiophene moiety on the OSC efficiency was confirmed. Thus, the introduction of fluorine atoms to thiophene rings in compound 22b leads to an increase in the efficiency from 4.58 to 6.21%. Based on the data of quantum chemical calculations, Park et al. [34] showed that in the fluorinated derivative, the dihedral angle between the thiophene rings is 0.88° (for comparison, in compound 22a it is 17.55°), which provides better planarity of the polymer and, as a consequence, higher velocity transport of electrons under irradiation. Within the framework of this direction, the importance of the method for preparing a thin film of the active layer of OSC was also shown. In reference [35], the OSCs based on a mixture of polymers 23a,b with PC 71 BM and an additive of diphenyl ether (3 vol %) were obtained by spin coating from an o-xylene solution. Therein, the fluorinated analog also turned out to be better in terms of the final value of the efficiency. Dithienosylole polymers 24 can also be included in this structure type. Although the authors of reference [36] do not give the exact values of the molecular weight of the obtained polymers, they draw a conclusion about the influence of the molecular weight on the efficiency of the cells (Table 4).
Thus, when using polymer 24b obtained by the Suzuki reaction with bis(pinacolato)diboron, the OSC efficiency was only 0.99%, while the Stille method gave a polymer 24a characterized by an efficiency of 1.66% (Scheme 14).

Scheme 12:
The simplest examples of polymers with a monothienylisoindigo monomeric unit. Strengthening the donor effect of the monomer unit can be achieved by lengthening the thiophene chain up to three fragments [37][38][39][40][41]. In this case, additional possibilities arise for fine-tuning the properties of polymers due to the introduction of substituents of different structures in each of the thiophene rings. Using the example of OSCs consisting of a mixture of a polymer 25 and PC 71 BM (1:1.5, w/w), the effect of the length of the alkyl radical on the efficiency of such cells was shown [37]. Thus, the hexyl and octyl derivatives 25a,b showed the best PCE values of 5.1 and 5.2%, respectively, which is higher than analogues bearing a longer or branched hydrocarbon chain (Scheme 15 and Table 5).
If the OSC active layer is prepared with the addition of diiodooctane, the PCE of the octyl analogue 25b increases to 6.4% [38]. A slight change in the substituent at the nitrogen atom and the introduction of electron-donor methyl or electronacceptor cyano groups in the thiophene fragment can lead to a sharp deterioration of all characteristics (structure 26: efficiency 1.94%) [39] or to their significant improvement (structure 27, efficiency 8.36%), respectively [40]. As it was found, the OSC based on polymer 27 showed one of the best values Scheme 13: Monothienylisoindigos bearing π-extended electron-donor backbones.
among the described structures of V OC 1.06 V. Others types of polymer structures that have good potential in organic photovoltaics can be found in the form of derivatives 28 and 29,  means of introducing fluorine atoms into the thiophene ring [43]. The use of compound 29c (ratio of monomer units n/m = 2:1) as an acceptor component of the OSC made it possible to achieve one of the highest efficiency values of 7.3%. The problem of the low solubility of such polymers was partially solved by inserting an alkylene spacer between two thiophene fragments in one of the monomer units [44]. Efficiency (3.0-3.7%) and viscosity characteristics provide good prerequisites for the use of this type of polymers in the design of flexible OSCs.
Condensed thienothiophene substituents can also be used as the donor component of the monomeric isoindigo unit (Scheme 17).
The first data on the use of these compounds as donor components of OSCs (mixed with PC 61 BM) showed that the technology of preparing a thin film of the active layer is important to achieve the best efficiency value [45]. Thus, the best results using compound 30 (efficiency 2.24%) were shown by a cell with an active layer of 44 nm obtained by shifting the solution along the substrate at a rate of 0.1 mm/s. Compared to compound 30, OSCs based on more complex condensed analogs 31 containing a heterocyclic fragment showed a 2-times better efficiency (5.6% for difluorothiophene, 5.0% for selenophene) [46].
The effect of the length and branching of the alkyl substituent at the endocyclic nitrogen atom in a series of this type of donor polymers was investigated. The 2-hexyldecyl derivative exhibited the best compatibility with PC 71 BM, which resulted in a high PCE value (6.83%) of the corresponding OSC [47]. This efficiency may be due to the good surface morphology of the composite thin film and, as a consequence, the high shortcircuit current (J SC = 13.55 mA/cm 2 ). It is interesting to note To increase the degree of conjugation in the structure of polymeric isoindigo, an introduction of additional aromatic fragments either into the main monomeric chain (compounds of type 33) [48][49][50] or as a side substituent in a thiophene unit (compounds of type 34) [51][52][53] was proposed. Among a number of compounds 33, the best efficiency (5.29%) was shown by an OSC based on a mixture of PC 71 BM and polymer 33с containing a short n-butyl substituent at the isoindigo nitrogen atoms and the longest and most branched alkyl radical in the p-phenylene fragment (Scheme 18).  (Table 6). Thus, an OSC based on a fluorine-containing polymer showed an efficiency of only 0.93%. This may be due to the low hole conductivity, a decrease in the HOMO level of the polymer, and a narrower band gap of visible light absorption [51].
Within the framework of the study of the prospects for polymer derivatives of isoindigo in organic photovoltaics and avoiding the use of the fullerene components, the concept of creating one-component OSCs appeared [54]. Following this strategy, isoindigo was used as platform for the synthesis of compound 35a, combining acceptor (perylene diimide) and donor (polythiophene) fragments in the structure. Both polymers were ob- However, the OSC of such a cell showed an efficiency of only 1%. Using polymeric isoindigo 35b as an acceptor component, a nonfullerene OSC was also obtained, which showed a record efficiency of 12.03% among the composites based on isoindigo described to date [55].
Polymeric derivatives of isoindigo containing no thiophene units were also used as acceptor components of the OSCs. Moreover, in both of the studies described in recent years, the donor component of the photovoltaic cell was variously substituted polythiophene, while the acceptor component (isoindigo platform) was functionalized with aromatic nitrogen-containing  substituents of various structures (Scheme 20). The design of DPP copolymers of isoindigo 37 seems to be the most promising here [56] since OSCs based on it showed a higher efficiency than with compound 36 (4.2 vs 0.26%) [57].
Considering the indigoid bisheterocycle as an additional photon trap, the substituted isoindigo was introduced as an acceptor substituent in the structure of the polyconjugated thiophene polymer 38 [58]. For this purpose, two indacenothiophene polymers were obtained containing one or two isoindigo fragments (the position of the introduction of the second isoindigo fragment is indicated by an arrow, Scheme 21). However, the efficiency of the cell based on the monoindigo derivative turned out to be slightly higher (2.66 vs 2.50%).

Isoindigo as the basis for organic field-effect transistors (OFET)
In recent years, the interest of researchers in semiconductor materials has covered the field of organic electronics. The advantages of organic oligomeric and polymeric materials for applications in OFET and thin-film transistor (TFT) technologies are due to the ease of their directed chemical modification, mechanical flexibility, the possibility of varying optoelectronic properties, and good solubility in a wide range of solvents [59][60][61]. In this regard, the most studied and promising are π-conjugated polymer structures based on sulfur, oxygen, nitrogen, and selenium heterocyclic compounds [62,63]. One of the systems for creating OFET devices is the isoindigo platform [64][65][66][67][68]. Scheme 22 shows polymeric structures with the best mobility values among isoindigo derivatives that are known to date.
Compounds 39-44 are the simplest representatives of isoindigo derivatives used in the design of OFET devices (Scheme 23). In a series of compounds of this type, the central platform of isoindigo is substituted in positions 6,6' either by a phenyl or by a substituted thiophene fragment. Thus, Ashizawa et al. [69] established the ambipolar character of the conductivity of 6,6'-diphenylisoindigo with μ h /μ e = 0.037 cm 2 ·V −1 ·s −1 / 0.027 cm 2 ·V −1 ·s −1 . Although the obtained values of mobility turned out to be low, this finding could have contributed to the development of this direction by the design of electron-donating aromatic substituents at the isoindigo core. However, as was shown in subsequent works, neither a change in the length and structure of the thiophene chain, nor the presence of an embedded benzothiadiazole fragment led to an improvement in the characteristics of transistors based on compounds 39-43 [70][71][72][73]. These derivatives had only hole-type conductivity in the range μ h = 1.5⋅10 −4 -6⋅10 −6 cm 2 ·V −1 ·s −1 .

Studies of the characteristics of OFETs based on compounds 45
showed almost complete absence of a dependence of the semiconductor properties (μ e = 0.08-0.01 cm 2 ⋅V −1 ⋅s −1 ) on the structure of the alkyl substituent at the nitrogen atom. It was only established that the distancing of the branching position of the alkyl chain affects the ordering of molecules in a thin polymer film after annealing [83]. At the same time, for the example of polymer 45 containing a 4-decyltetradecyl radical, it was shown that the efficiency of an OFET device depends on the method of thin film processing. In contrast to the traditional spin-coating technique, the authors succeeded in obtaining a thin film by immersing a substrate in a polymer solution, followed by slow extraction, accompanied by slow evaporation of the solvent. The device thus obtained showed one of the highest values of hole conductivity of μ e = 8.3 cm 2 ⋅V −1 ⋅s −1 [78]. It was also found that a device based on compound 45 (R = 2-decyltetradecyl) with the addition of iron phthalocyanine showed slightly better mobility. Liu et al. explain this effect by an improvement in the hole-type conductivity and a tight and even packing of the composite in a thin film [80]. At the same time, selenophene analogs generally show lower values of mobility [90]. The introduction of fluorine atoms into the dithienyl fragment (see compound 46), while varying the symmetry of substitution of the 1,1' positions in isoindigo, did not lead to an improvement in the OFET efficiency (maximum μ h = 1.08 cm 2 ⋅V −1 ⋅s −1 ). For comparison, a similar device based on a nonfluorinated analog showed a value of μ h = 2.71 cm 2 ⋅V −1 ⋅s −1 [74]. Continuing the Scheme 20: Isoindigo-based nonthiophene aza aromatic polymers as acceptor components of OSCs.

Scheme 21:
Polymers with isoindigo substituent as side-chain photon trap.
study of the effect of the substituent nature on the OFET efficiency, a number of polymers 47 with varying degree of fluorination of the monomer structural units was obtained [79]. The study showed that the transition from a less fluorinated analogue (two fluorine atoms on dithiophene) to one containing a larger number of fluorine atoms (two fluorine atoms on dithio-phene and two in the 7,7' positions) improves the planarity of the structural units of the polymer and increases the degree of crystallinity, which consequently increases μ e . At the same time, the polymer containing two fluorine atoms on the dithiophene unit and one in position 7 exhibited balanced ambipolar properties, having the currently best ratio of μ h /μ e = 6.41 cm 2 ⋅V −1 ⋅s −1 /6.46 cm 2 ⋅V −1 ⋅s −1 among isoindigoid polymers.
Attempts to improve the efficiency of isoindigo-based OFETs by introducing an ethylene bridge between thiophene fragments in general did not lead to the desired result (Scheme 25).
Thus, devices based on polymers 48 and 49 showed an analogy in the unipolar character of the conductivity with close values of μ h = 0.68-0.83 cm 2 ⋅V −1 ⋅s −1 [87,91]. It should be noted here that more detailed studies on selenium analogs of polymers 48 are promising since the latter showed moderate values of electronic mobility of μ e = 1.28 cm 2 ⋅V −1 ⋅s −1 [89]. It was shown that a sig-Scheme 23: Monoisoindigos as low-molecular-weight semiconductors.

Scheme 25:
Fluorination as a tool to improve isoindigo-based OFET devices.
nificant improvement of the semiconducting properties of an isoindigo polymer can be achieved by "multifluorination", the introduction of fluorine atoms both to the dithiophene fragment and to the 7,7'-positions of isoindigo (compound 50) [88]. As such, the presence of fluorine atoms led to the ambipolarity of the polymer with an effective ratio μ h /μ e = 3.94 cm 2 ⋅V −1 ⋅s −1 / 3.50 cm 2 ⋅V −1 ⋅s −1 .
Recently, diketopyrrolo[3,4-c]pyrrole (DPP) derivatives, which are highly conjugated electron-withdrawing heterocycles with high charge conductivity, broad absorption spectrum, photostability, and thermal stability have attracted considerable interest of researchers in the field of organic electronics [92][93][94]. Isoindigo derivatives have similar characteristics. Taking into account these data, copolymers 51 containing up to 25% DPP units were obtained [95]. Despite the good prerequisites, an OFET based on this copolymer showed only hole-type conductivity with μ h = 1.2⋅10 −3 cm 2 ⋅V −1 ⋅s −1 . Therein, the thermolysis of a thin film of the device at 220 °C, accompanied by the elimination of Boc groups, led to a significant decrease of the OFET performance. For the example of the polymers 52 series, the importance of the spatial arrangement of the isoindigo and DPP fragments relative to each other was demonstrated [96]. Thus, the dihedral angle 179° in a furan polymer determines the conductivity μ h /μ e = 0.01 cm 2 ⋅V −1 ⋅s −1 /1.6⋅10 −3 cm 2 ⋅V −1 ⋅s −1 , while polymers containing thiophene or p-phenylene spacers did not possess conductivity at all due to the lower planarity (dihedral angle 143°, Scheme 26, Table 7). Homopolymers based on isoindigo of various types have also been used in the design of transistors [97][98][99][100]. In order to reduce the influence of factors of conformational and energy disordering inherent in all isoindigo polymers in which aromatic fragments are linked by a single bond, a number of homopolymers 53 was obtained by the aldol polycondensation reaction [97]. These compounds have rigid and almost planar structures with a wide absorption range, high electron affinity, good solubility, and ambient stability (Scheme 27). The study of the transistor characteristics showed that these homopolymers have an electronic type of conductivity, with a maximum value of μ e = 0.03 cm 2 ⋅V −1 ⋅s −1 . The work [98] was also aimed at obtaining OFET devices based on homopolymeric isoindigo. The thieno-based condensed polymers 54 described herein, in which the monomeric isoindigo fragments are linked by a single bond, were obtained in two ways: by Suzuki (40% yield) and Stille (50% yield) coupling reactions. Despite the possibility of rotation of monomeric fragments around a single bond, a transistor based on this polymer showed relatively high values of mobility of μ h /μ e = 0.065 cm 2 ⋅V −1 ⋅s −1 /0.15 cm 2 ⋅V −1 ⋅s −1 . It is also worth presenting data on compounds 55 containing thiophene bridges of various structures between the isoindigo nuclei [99,101]. Therein, the presence of a spacer, in comparison to compounds 54, led to a decrease of the OFET performance (maximum μ h /μ e = 0.037 cm 2 ⋅V −1 ⋅s −1 /0.029 cm 2 ⋅V −1 ⋅s −1 , Table 8).
One of the directions for the design of polymeric isoindigo derivatives to improve the conductive properties is the lengthening of the conjugation chain of both the monomer unit itself and the monomer subunit [102][103][104][105]. Thus, two polymers 56 were obtained in which isoindigo fragments are condensed on the indacenedione scaffold [102]. Despite the presence of an extended π-conjugation system, which determines the ambipolar properties of a transistor based on these polymers, the charge mobility values turned out to be rather low (Scheme 28). The maximum value of μ h /μ e = 0.1 cm 2 ⋅V −1 ⋅s −1 /0.14 cm 2 ⋅V −1 ⋅s − 1 was shown by a polymer containing a bridging ethylene fragment between two thiophene substituents. The lengthening of the conjugation chain within the monomeric unit can be achieved by introducing phenylenequinoxaline [103] or fluorinated phenylenethiophene [104] fragments. Based on compound 57, a flexible OFET with μ e = 0.25 cm 2 ⋅V −1 ⋅s −1 was fabricated on a 3D printer. In contrast to the above, an OFET based on difluorobenzothiadiazole polymer 58 showed hole conductivity with a low charge mobility value of μ h = 0.07 cm 2 ⋅V −1 ⋅s −1 .

Isoindigo-based sensor devices
Isoindigo derivatives have begun to find an application in the design of sensor devices for the detection of simple and complex molecules in various aggregation states. Thus, it was shown that polymer structures based on isoindigo and thiophene 59a,b and 60a,b are able to effectively bind gaseous ammonia molecules (Scheme 29) [106].
Thin films of these polymers are characterized by high sensitivity, reproducibility, and fast response time. Among this series of compounds, polymer 60b, containing a terthiophene oligomeric unit, has the best characteristics. Further studies showed that a polymer composite based on the terthiophene analogue 59a, poly(methyl methacrylate), and polyaniline is capable of detecting vapors of some organic solvents  (chlorobenzene, n-butanol, DMF, isopropanol, and toluene) [107]. Therein, the best sensitivity was found towards n-butanol. The lower limit of detection was 100 ppm with a response time of less than 10 s.
The ability of polymeric isoindigo derivatives to strongly bind to carbon nanotubes due to π-stacking was used to create sensors for the determination of NO 2 in the gaseous state (see polymer 61) and glucose in solution (see polymer 62) [108,109]. The limit of sensitivity of the sensor for nitrogen dioxide was 60 ppm and for glucose 0.026 mM. For the example of the fairly simple arylamine series 63, the possibility of using isoindigo polymer for the detection of explosives (trinitrophenol and trinitrotoluene) in solution was demonstrated (Scheme 30) [110,111].

Miscellaneous applications
Taking into account the high thermal, atmospheric, mechanical, and redox stability of isoindigo polymers, various scientific groups focused their studies on the development of new directions for the practical application of these materials. Thus optical contrast (59% at 1500 nm), and redox stability (<8% after 4000 cycles).
Poly(isoindigothiophene) 65 containing sulfonate groups in the side chain was used as an anionic photoactive polyelectrolyte in a composite with platinum nanoparticles stabilized with poly(acrylic acid) [113]. Such a catalytic system, obtained by layer-by-layer self-assembly with the addition of poly(diallyldimethylammonium chloride) on the indium tin oxide surface, provided hydrogen formation in photoelectrolytic cycles with a Faraday yield of about 45%.
The search for new stable polyfunctional materials for the mass spectrometric determination of low-molecular-weight compounds led the authors of reference [114] to the discovery of new properties of polyisoindigo 66. It was found that this polymer can be used as a two-mode matrix (in positive and negative modes), which is a rarity for the MALDI method. The detection limits were below 164 pmol for reserpine and below 245 pmol for cholic acid. More recently, another new application of polyisoindigos was discovered as a new conductive binder inside electrodes containing silicon nanoparticles coated with a carbon shell (Si@C) for lithium ion batteries [115]. The specific capacity of a battery designed using polyisoindigo 67 (up to 1400 mA⋅h/g) with high stability (up to 500 cycles) indicates a high potential of such structures in the search for alternatives to the existing polymer conductive binder mixed with carbon additives (Scheme 31).
Isoindigo derivatives have begun to find use in biomedical applications. Thus, nanoparticles of isoindigoid polymers have shown good potential as agents for photoacoustic and photothermal cancer therapy [116][117][118][119][120][121]. In this field, a number of condensed derivatives of oligoisoindigo 68-70, triphenylamine-containing monoisoindigo 71, and selenophenevinylene polymer 72 were investigated (Scheme 32). In terms of photothermal conversion (62-71% yield), ribbon-like compounds turned out to be the most effective [120]. At the same time, in vivo experiments have shown the high efficiency of low-molecular-weight isoindigo 71 in oxygen sensitization for cancer therapy [121]. Therein, a high value (84%) of the singlet oxygen quantum yield was obtained.

Conclusion
To summarize, it can be concluded that isoindigo is a promising platform for creating materials for various purposes -from organic solar cells and transistors to materials for biomedical applications. The possibility of easy modification and easy accessibility of the starting reagents for the synthesis of polysubstituted isoindigo derivatives provides the possibility of finetuning the properties and wide design of this bisheterocycle. In particular, to improve the characteristics of organic solar cells and OFET devices based on polymer derivatives of isoindigo, some of the most important factors are the planarity of the monomer unit, the electron donor/acceptor nature, the heterocyclic substituents, and the branching of the alkyl radical at the endocyclic nitrogen atom. Research on methods to obtain polymer isoindigo thin films and the use of additives will, in our opinion, significantly improve the efficiency of materials. In addition, the first work on combining polyaromatic acceptor and heterocyclic donor fragments in one macromolecule on the isoindigo platform showed the possibility of designing onecomponent nonfullerene solar cells. The high stability of polymeric isoindigo in air, at elevated temperature, under redox conditions, under laser irradiation, and the biocompatibility Scheme 32: Mono-, rod-like, and polymeric isoindigos as agents for photoacoustic and photothermal cancer therapy.
make it possible to conclude that the design of these compounds is promising for mass spectrometry, for catalysts for hydrogen production, and for photothermal cancer therapy.