A Review on the Synthesis of Fluorescent Five- and Six-Membered Ring Azaheterocycles

Abstract

Azaheterocycles rings with five and six members are important tools for the obtaining of fluorescent materials and fluorescent sensors. The relevant advances in the synthesis of azaheterocyclic derivatives and their optical properties investigation, particularly in the last ten years, was our main objective on this review. The review is organized according to the size of the azaheterocycle ring, 5-, 6-membered and fused ring azaheterocycles, as well as our recent contribution on this research field. In each case, the reaction pathways with reaction condition and obtained yield, and evaluation of the optical properties of the obtained products were briefly presented.

1. Introduction

The synthesis of fluorescent azaheterocycles continues to arouse strong interest due to their great potential for application as sensors and biosensors, luminophores on in the construction of Organic Light-Emitting Diode (OLED) devices, laser and other semiconductor devices [1,2,3,4], as well as to their potential biological properties as antimicrobial [5], antifungal [6], anticancer [7,8], antituberculosis [9,10] antioxidant [11] and anti-HIV [12] agents.

The advantages of the azaheterocyclic fluorophores, such as small size, enriched photostability, a wide and tunable spectral range, and, frequently, high brightness, are the reason why these fluorophores are preferred and used in various medical application. Probe structure can be modified to adjust excitation and emission wavelengths, target-binding affinity, chemical reactivity, and subcellular localization [13,14,15,16].

In this review, we try to present an overview of the newest research in the synthesis of fluorescent azaheterocyclic derivatives, from the literature reported during the last ten years. The methodology adopted for literature search and selection was to access the Reaxys database for “fluorescence”, “azaheterocycles” and “fluorescent azaheterocycles” keywords. The obtained results, as well as the references cited, were selected to be included in the present review if they present the synthesis of fluorescent azaheterocycles, and the fluorescent properties of these compounds were evaluated.

The present review was organized taking into account the size of the azaheterocycle, the nature of the cycle (monocycle and fused polycycles), as well as our contribution in this research field.

2. Synthesis and Fluorescent Properties of Five- and Six-Membered Ring Azaheterocycles

2.1. Five Membered Ring Azaheterocycles

Five membered ring azaheterocycles, such as pyrroles, diazoles, triazoles, tetrazoles and their fused derivatives, are privileged scaffolds posing a wide range of biological activities and diverse applications in organic electronics [17,18,19,20,21,22,23,24,25]. Due to these properties, many researchers were focused on the obtaining of new compounds with such skeleton.

Martínez-Lara et al. [26] developed a new obtaining methodology of two different angular indolocarbazole moieties by using two sequential gold- and molybdenum-catalysis to obtain new indolo [2,3-c]carbazoles as potential luminophores with application in OLED devices.

A selection of 1,1-bis(indol-3-yl)-3-alkyn-2-ols 3, was readily prepared through the alkylation of the indole derivatives 1 with methyl or phenyl glyoxal, followed by a standard Sonogashira-type reaction with 2-nitroaryl iodides. Next, these compounds underwent a cyclization reaction, promoted by NaAuCl₄, affording the corresponding carbazoles 4 (see Scheme 1).

Without further purification, the crude carbazoles were directly subjected to Mo-catalyzed Cadogan reaction delivering the desired indolocarbazoles 5. All indolocarbazoles were obtained in high yields. The authors [26] used microwave irradiation for the synthesis of the indolocarbazole derivatives 4 and 5, and obtained final products in much shorter time and with better yields (see Scheme 2).

To obtain a perspective on the effect that the C-7 substituent of the indolocarbazole skeleton (methyl in 5aa, and phenyl in 5ba) the photoluminescent properties of two selected compounds, 5aa and 5ba in DMSO were investigated

Table 1. Fluorescent properties of the selected 5aa and 5ba in DMSO.

Compound	λabs (nm)	εmax (L·mol−1·cm−1)	λem (nm)	Φfl (%)	τ (ns)	kf (107·s−1)	Knr (107·s−1)
5aa	338	20,700 ± 300	407	72 ± 4	7.4 ± 0.1	9.54 ± 0.10	3.89 ± 0.04
	351	23,700 ± 300
	377	6900 ± 200
	397	8200 ± 200
5ba	342	16,700 ± 200	424	69 ± 2	6.4 ± 0.1	10.77 ± 0.05	4.84 ± 0.02
	354	20,000 ± 200
	384	6500 ± 100
	402	7500 ± 100

Maximum absorption wavelength (λ_abs), molar absorptivity at the absorption maximum wavelength (ε_max), maximum emission wavelength (λ_em), fluorescence quantum yield (Φ_fl), average lifetime (τ), and fluorescence (k_f) amd non-radiative (k_nr) rate constants.

.

The phenyl-substituted 5ba indolo[2,3-c]carbazole shows a wider absorption wavelength range than methylsubstituted 5aa indolo[2,3-c]carbazole and both show fluorescence quantum yields around 70% in DMSO, double as the Φ_fl of some similar compounds from the literature. These compounds are potentially useful for optoelectronic applications due to their high extinction coefficient and fluorescence quantum yields.

By combining 2H-imiazole 1-oxides 7a–l with pentafluorophenyl lithium 8 made in situ from pentafluorobenzene 6 and n-BuLi, Moseev et al. [27] were able to create novel pentafluoroaryl-modified derivatives of 2H-imidazole type 10a–l and 11a–l, as is presented in Scheme 3. Pentafluorophenyllithium 8 first attacks the imidazole-N-oxide 7a–l, resulting in the unstable σ^H-adduct 9 that can be converted into the product either by “addition-elimination” (Path A), leading to the formation of compounds 10a–l, or by “addition–oxidation” (Path B), leading to the creation of compounds 11a–l containing N-oxide group.

As possible applications, the authors claim that the push-pull fluorophore systems containing both electron-donating (EDG) and electron-withdrawing (EWG) groups in the vicinal position could be used as push–pull fluorophore systems. The obtained molecule types 10 and 11 have undergone a photophysical study to determine the potential practical uses in the construction of photoactive materials. The authors results are shown in

Table 2. The photophysical properties for the obtained molecules 10 and 11.

Compound	λabs (nm) a	λem (nm) b	Φfl (%) c	Compound	λabs (nm) a	λem (nm) b	Φfl (%) c
10a	259	316	<0.1	11a	281	316	<0.1
10b	266	316	<0.1	11b	278	317	<0.1
10c	263	317	<0.1	11c	279	316	<0.1
10d	272	316	<0.1	11d	282	316	<0.1
10e	272	317	<0.1	11e	283	316	<0.1
10f	261, 302	333, 420 (br)	<0.1	11f	297	322	<0.1
10g	304	333, 420 (br)	<0.1	11g	297	321	<0.1
10h	272	316	0.6	11h	272	317	<0.1
10i	305	331, 475 (br)	0.1	11i	298	320	<0.1
10j	305	335, 464 (br)	0.2	11j	297	325	<0.1
10k	277	317, 352 (br)	<0.1	11k	288	317	<0.1
10l	256	316	1.9	11l	277	317	<0.1

^a Absorption maxima in MeOH. ^b Emission maxima in MeOH. ^c Absolute fluorescence quantum yields in MeOH, br-broad peak.

.

The authors concluded that the presence of EWG in the para-position of the phenyl group improved the fluorescence quantum yield of the produced fluorophores by measuring the quantum yield of polyfluorinated-2Himidazole derivatives 10 and 11.

The phenomenon of intramolecular charge transfer (ICT) in polar protonic solvents (MeOH and EtOH) has been shown for several compounds, and connections between “structure-photophysical characteristics” have been found. The characteristics of the investigated photophysical properties allow them to adjust the structures of the photoactive molecules, which opens the possibility of using the synthesized push-pull systems in the development of difficult fluorometric molecular sensors.

Pu et al. [28] synthesized antipyrine-containing diarylethenes derivatives 14 in their attempt to obtain novel multi-controllable photochromic and fluorescent derivatives (see Scheme 4).

It was determined that 14o had an absolute fluorescence quantum yield of 1.4%. UV light (297 nm) irradiation caused the photocyclization reaction, which resulted in the synthesis of 14c with a quantum yield of 0.8%. As a result, the emission strength of 14o abruptly reduced, and the fluorescence changed from bright orange to darkness. Conversely, by exposing 14o with appropriate visible light, the fluorescence may be recovered.

At 580 nm, the isomer 14o showed high brightly orange fluorescence. The emission strength of 14o reduced to 18% with the addition of 5.0 equiv of tetrabutylammonium hydroxide, and the color changed noticeably from bright orange to blackness as a result of the creation of deprotonated 14o’. The fluorescence could return to its initial form upon neutralization with 2.0 equiv of HCl. Similar to this, the stimulation of TBAH/HCl in acetonitrile could reversibly alter the fluorescence of 14c. When irradiated to UV/vis light, the fluorescence alterations between 14o’ and 14c’ was irreversible. The fluorescence of 14o’ stayed unaltered when irradiated to UV light, however when exposed to visible light (λ > 500 nm), the fluorescence of 14c’ might return to that of 14o’, as may be observed in Scheme 5. The results obtained by the authors shown that the base could suppress the photochromism of diarylethene with an antipyrine unit’s and acid could restore it.

In order to examine the fluorescence variations of 14o, 5.0 equiv of several metal ions, including Al³⁺, Zn²⁺, Ni²⁺, K⁺, Cd²⁺, Ca²⁺, Cu²⁺, Ba²⁺, Pb²⁺, Cr³⁺, Co²⁺, Sr²⁺, Mg²⁺, Mn²⁺, Hg²⁺ and Fe³⁺, were added. The authors pointed out that the addition of Al³⁺ was the only metal ion that significantly affected the fluorescence of 14o; other metal ions had a negligible effect. As a result of this study, the diarylethene with an antipyrine unit type 14o demonstrated special base-gated photochromic properties and could be used as a highly selective naked-eye chemosensor for Al³⁺ detection.

2.2. Six Membered Ring Azaheterocycles

Electron-deficient six membered ring azaheterocycles, such as azines and diazines, are strongly desired and studied due to their potential biological activities and also to their potential applications in organic electronics [29,30,31,32,33].

Motivated by the small size and high quantum yield (Φ = 60%) of the unsubstituted pyridin-2-amine, being a potential scaffold for a fluorescent probe, Li et al. [34], in their research for new multisubstituted aminopyridines, used the Rh-catalyzed coupling of vinyl azide with isonitrile to form a vinyl carbodiimide intermediate, which followed a tandem cyclization with an alkyne to the desired amine.

The reactions were carried “one-pot”, using vinyl azide 15 and isonitrile 16, Rh-catalyst, proper ligand and 1,4-dioxane as solvent, under N₂ atmosphere and at room temperature in the first stage, then after the vinyl azide spot disappeared on TLC, NH₄Cl, NaHCO₃, and alkyne were added, and the mixture was heated to 120 °C for 8 h (see Scheme 6).

For quantitative fluorescent detection, the solution of aminopyridine was then diluted to 10 μM. The measured parameters are presented in

Table 3. Fluorescent properties of aminopyridines.

Compound	Yield [%]	λabs [nm]	λex [nm]	λem [nm]	Φfl [%]
	71	270	390	480	34
18	24	270	390	480	31
19	65	270	390	480	44
20	52	270	390	485	31
21	60	270	390	485	27
22	52	270	390	485	32
23	53	270	390	485	22
24	17	258	345	455	2
25	67	270	390	480	35
26	57	270	390	480	30

λ_abs-absorption maxima in ethanol (longest wavelength transition), λ_ex-excitation wavelenght, λ_em-maxima of the corrected emission spectra in ethanol, Φ_fl-the fluorescence quantum yield, external standard: 9,10-diphenylanthracene (Φ = 95%, in cyclohexane).

.

Compound 17 was derivatized in order to observe the variation of the photoluminescent properties, as is presented in Scheme 7.

Thus, when the tertiary butyl group was cleaved using CF₃COOH the obtained compound 27 showed no fluorescence. When the ester groups were hydrolyzed to carboxylic acid, the obtained compound 28 still had a good fluorescence (Φ = 31%). When compound 35 was reduced with LiAlH₄ a high fluorescent (Φ = 81%) alcohol 29 was obtained in excellent yield, but the λ_em was reduced to 400 nm.

The same authors [34], in order to apply the newly synthesized compound as fluorescent probe, used the click reaction to bind the fluorescent aminopyridine scaffold to biomolecules conjugated with alkynyl group (see Scheme 8). Firstly, they synthesized a Boc-NH protected compound 30 accordingly to the above-described method from corresponding starting materials, then the azido substituted derivative 31 was obtained via a Sandmeyer reaction. Finally, the azide 31 react easily with phenylacetylene or propynol (by using catalytic amounts of Cu(II)) to obtain the desired triazole products 32 or 33.

The authors successfully applied this “click-and-probing” experiment to bovine serum albumin (BSA) conjugated with a terminal alkyne, demonstrating the biochemical application of this probe and of the fluorescent multisubstituted aminopyridines for detection and analysis.

Piloto et al. [35] studied the use of acridine azaheterocycle as a photochemically removable protecting group for the carboxylic group of amino acids involved in neurotransmision. In this respect, a series of amino acids 34 (glycine, alanine, glutamic acid, β-alanine and γ-aminobutyric acid) protected on amino group with tert-butoxycarbonyl, was treated with 9-bromomethylacridine 35, the corresponding heterocyclic ester 36 being obtained (see Scheme 9). The coupling reaction requires potassium fluoride as base and N,N-dimethylformamide as solvent, and take place at room temperature.

UV/Vis absorption and emission spectra for the ester conjugates 36a–e were measured on degassed 10⁻⁵ M solutions in two solvent systems: absolute ethanol, and a methanol–HEPES buffer (80:20), the measured parameters are presented in

Table 4. Yields, UV/VIS and fluorescence data for esters 36a–e in absolute ethanol and a methanol-HEPES buffer (80:20) solution.

Compound		Yield [%]	EtOH					MeOH-HEPES (80:20)
			λabs [nm]	log ε	λem [nm]	Φfl [%]	Δλ [nm]	λabs [nm]	log ε	λem [nm]	Φfl [%]	Δλ [nm]
36a	Boc-Gly-OAcm	69	360	3.90	435	9	75	362	3.48	423	12	61
36b	Boc-Ala-OAcm	93	361	3.93	411	11	50	360	3.69	412	15	52
36c	Boc-Glu-OAcm	19	361	4.04	433	8	72	362	3.57	433	11	71
36d	Boc-β-Ala-OAcm	72	361	3.91	412	11	51	361	3.79	417	14	56
36e	Boc-GABA-OAcm	49	361	3.97	424	4	63	360	3.94	424	11	64

λ_abs-the maximum wavelength of absorption spectra, log ε-logarithm of the molar absorption coefficient λ_em-the maximum wavelength of photoluminescence spectra, Φ_fl-photoluminescence quantum yield, calculated using 9,10-diphenylanthracene as a standard (Φ_fl = 0.95 in ethanol), Δλ-Stokes’ shifts (Δλ = λ_em − λ_abs).

.

Due to the heterocyclic chromophore, the absorption maximum of compounds showed no influence of amino acid residue. Ester derivatives 36a–e displayed emission maxima between 411–435 nm in both solvents, with moderate Stokes’ shifts (50–75 nm). These esters exhibited higher fluorescence quantum yields in a methanol–HEPES buffer solvent system.

The deprotection of the carboxylic group from the corresponding fluorescent derivatives in methanol-HEPES buffer (80:20) solutions was achieved by irradiation. The best results on photorelease of these amino acids from were obtained on irradiation at 350 nm. This ability of acridinyl methyl ester make them a suitable option for the photochemical release of functional molecules bearing a carboxylic acid group in organic synthesis and in cellular applications.

In order to obtain new luminogens for sensing strong acids Tang et al. [36] used Suzsuki cross-coupling reaction. The luminogens consist of one pyridine, 1,3-diazine, 1,4-diazine, 1,2-diazine and phthalazine moieties as the central cores and two AIE-active tetraphenylethene units in the lateral sides. Aggregation induced emission (AIE) effect exhibiting high emission in concentrated solution or even in the solid state, hold great promise for a luminogen in practical applications.

PY-TPE 39b, PYM-TPE 39c, PYA-TPE 39d, PYD-TPE 39e and PTZ-TPE 39f were easily synthesized by 4-(1,2,2-triphenylvinyl) phenyl boronic acid 37 reaction with 2,5-dibromopyridine 38b, 2,5-dibromopyrimidine 38c, 2,5-dibromopyrazine 38d, 3,6-dibromopyridazine 38e, 1,4-dibromophthalazine 38f under Suzuki cross-coupling in high yields (see Scheme 10). For comparison, an analogue molecule BZ-TPE 38a fused with phenyl unit was also prepared.

The photophysical properties of the luminogens were studied by UV-vis and fluorescence spectroscopies in CH₃CN, and are presented in

Table 5. Photophysical data for the as-prepared luminogens.

Compound	UV-Vis Absorption		Fluorescence
	λabs [nm]	log ε	λem [nm]	Φfl [%]	τ [ns]	kf 107 [s−1]	knf 107 [s−1]
39a BZ-TPE	332	4.43	480	53.7	3.5	15.3	13.2
39b PY-TPE	340	4.57	481	42.6	3.3	12.1	16.3
39c PYM-TPE	346	4.42	482	31.2	3.0	10.4	22.9
39d PYA-TPE	363	4.51	484	14.6	2.0	7.3	42.7
39e PYD-TPE	343	4.24	450	0.6	1.3	0.46	76.2
39f PTZ-TPE	323	4.45	480	1.6	1.7	0.94	57.8

λ_abs-the maximum wavelength of absorption spectra recorded in CH₃CN (10⁻⁵ M), log ε-logarithm of the molar absorption coefficient λ_em-the maximum wavelength of photoluminescence spectra measured in CH₃CN-water (1:9), Φ_fl-photoluminescence quantum yield, τ-fluorescence lifetime, k_f-radiation rate constant (k_f = Φ_fl/τ), k_nf-non-radiative rate constant (k_nf = kf (1 − Φ_fl)/Φ_fl).

. These luminogens show a colorless character in common organic solvents, making them good candidates for colorimetric or fluorometric detection with less self-absorption disturbance. All compounds show very weak fluorescence emission in CH₃CN, caused by non-radiative fashion arising from the rotation of tetraphenylethene units.

The emission spectra (in CH₃CN–water) were recorded in order to determine the AIE effect in aggregate states of the as-prepared luminogens. Benzyl-, pyridine-, pyrimidine- and pyrazine-tetraphenylethenes (39a–d) exhibited high fluorescence quantum yields in aggregate states due to a typical AIE effect. 1,2-Diazine-tetraphenylethenes (pyridazine-39e and phthalazine-39f) have strong yellow fluorescence emission under protonation enabling AIE performance. The synergetic effect of AIE and the protonation on the 1, 2-diazine segments allows them to detect strong acids with very low pKa values.

The similarities of the 4-hydroxy-1,3-thiazole unit, a chromophore and fluorophore, with naturally occurring luciferin, determine Menzel et al. [37] to obtain new of arylamine-modified thiazoles as donor-acceptor dyes. The donor part of the dyes was based on the 4-methoxy-1,3-thiazole core substituted with an arylamine (phenyl-, p-anisole-, p-tolyl-, or phenothiazine-) in the 5-position as donor, and a pyridine, pyrimidine, or pyrazine moiety in the 2-position as acceptor.

The synthesis of the 4-hydroxy-1,3-thiazoles 42a–c involved a Hantzsch thiazole cyclizations between the corresponding azaheterocyclic thioamides 40a–c and ethyl 2-bromo-2-(4-nitrophenyl)acetate 41a. Similarly, starting from ethyl 2-bromo-2-(4-bromophenyl)acetate 41b and pyridine-2-carbothioamide 40a, compound 42d was prepared, then methylated via Williamson ether synthesis, with methyl iodide in DMSO. The reduction of the nitro group in 43a–c with freshly prepared Raney nickel and hydrazine in EtOH fallowed (see Scheme 11).

The reaction condition for the double N-arylation Buchwald–Hartwig cross-coupling reaction were: bis(dibenzylideneacetone)palladium(0) [Pd(dba)₂] as the precatalyst, KOtBu as the base, and toluene as solvent. By using the P(tBu)₃ reagent, the desired products were obtained in moderate to good yields (76–90%). The obtaining of both disubstituted A1 and B1, and the monosubstituted products A1m (69%) and B1m (88%), demonstrates the two-step nature of the reaction (see Scheme 12).

The Buchwald–Hartwig reaction starting with 43d, a thiazole substituted aryl halide, was not successful under the conditions of the double N-arylation of the amines 44a–c, the biarylphosphane 2-(dicyclohexylphosphanyl)-2′,6′-dimethoxy-1,1′-biphenyl (SPHOS) was required as ligand (see Scheme 13).

The arylamine donors has a strong influence on the emission quantum yields recorded in CH₃CN solution at room temp, the phenyl-based triarylamines having good quantum yields (40–47%), while the p-anisole-based triarylamines show values below 1% for quantum yields, and consequently no fluorescence for the p-N,N′-dimethylaniline derivative. The obtained photoluminescence quantum yields (see

Table 6. Spectroscopic properties, in CH₃CN at room temperature, of the synthesized dyes.

Dye	λabs [nm]	log ε	λabs [nm]	log ε	λem [nm]		Φfl [%]	τ [ns]
A1	301	4.33	405	4.44	547		47	3.83
A2	299	4.35	417	4.43	605		<1	0.26
A3	307	4.43	433	4.36	n.d.		n.d.	n.d.
B1	303	4.40	425	4.47	593		40	2.99
B2	302	4.40	439	4.46	611		<1	0.13
C1	302	4.32	426	4.36	601		8	1.26
C2	301	4.38	433	4.46	630		<1	<0.1 *
D1	292	4.11	380	4.24	478		90	3.12
D2	257	4.72	377	4.42 **	484 sh,	507	2	0.11
D3	240	4.77	373	4.40	455 sh,	470	<1	0.13

λ_abs-the maximum wavelength of absorption, log ε-logarithm of the molar absorption coefficient λ_em -the maximum wavelength of photoluminescence, Φ_fl-photoluminescence quantum yield, τ-fluorescence lifetime, n.d-not detected, *-below demand interval, **-measured in THF, sh.-shoulder.

) are correlated with the measured emission lifetimes (τ).

Only the emission due to the carbazole moiety, as a main band, can be observed for compound D1 in the polar CH₃CN, while for D2 and D3 the emissions are modest.

The authors [37] carried out measurements of the absorptions (and emissions) in different solvents for compounds A2 and D1 in order to investigate them in more detail (see

Table 7. Spectroscopic behavior of dyes A2 and D1 in different solvents.

Solvent	A2						D1
	λabs [nm]	log ε	λem [nm]	Φfl [%]	Stokes Shift [cm−1]	τ [ns]	λabs [nm]	log ε	λem [nm]	Φfl [%]	Stokes Shift [cm−1]	τ [ns]
Heptane	427	4.585	483, 512	63	3900	2.6	387	4.466	456, 464	97	4300	2.4
Dioxane	425	4.441	530	59	4700	3.8	385	4.399	472	100	4800	2.7
CHCl3	428	4.422	561	40	5500	4.0	387	4.235	475	95	4800	2.9
THF	425	4.485	552	43	5400	3.8	384	4.474	473	100	4900	2.8
MeOH	421	4.456	581	<1	6500	0.1	382	*	489	81	5700	3.3
CH3CN	417	4.434	603	1	7400	0.1	380	4.244	475	90	5300	3.1

λ_abs—the maximum wavelength of absorption, log ε—logarithm of the molar absorption coefficient λ_em—the maximum wavelength of photoluminescence, Φ_fl—photoluminescence quantum yield, τ—fluorescence lifetime, *—extinction coefficient could not be measured, due to the poor solubility.

). The increasing of the solvent polarity induces a weak hypsochromic shift on the absorption maxima, but a bathochromic shift on the emission maxima. This behavior is due to a conformational transformation from a planar locally excited (LE) state to an intramolecular charge-transfer (ICT) or, consequently, to a twisted intramolecular charge-transfer (TICT) state.

Menzel et al. [37] tested also the ability of these dyes to act as ligands and synthesized seven new ruthenium complexes and measured their emission spectra. The synthesis of the heteroleptic Ru^II complexes involve the activation of the cis-(dmbpy)₂RuCl₂ precursor with AgPF₆ prior to the complexation in acetone with the appropriate ligand (1 equiv.) for 24 h under reflux conditions (see Scheme 14).

Each complex shows an enhanced absorption in the visible part of the UV/Vis spectrum, due to additional ligand-centered (LC) π–π* transitions and metal-to-ligand charge-transfer (MLCT) transitions originating from 4-methoxy-1,3-thiazole ligands.

2.3. Fused Azaheterocycles

Fused azaheterocycles combine an electron-excessive pyrrole and an electron deficient azine ring which involve an uneven π-electron distribution. This uneven π-electron distribution induces interesting optical properties on the compound with such fused azaheterocycles and make them very attractive materials in optoelectronics [38,39]. Moreover, the variety of potential applications in the fields of medicinal of these compounds explains the increased interest of researchers in their study [40,41,42].

Rajbongshi et al. [38] obtained new chromeno[2,3-b]indoles 47a–c as part of the series of chromenoindole derivatives by reacting 1-(α-amino-α-arylalkyl)-2-naphthol 45 with indole 46 at 100 °C in the presence of catalytic p-toluenesulfonic acid, I₂ and tert-butyl hydroperoxide (TBHP), as is presented in Scheme 15.

In various solvents, the fluorescence spectra of the produced chromeno[2,3-b]indoles 47a–c alter and show a significant Stokes shift, ranging from 250 nm in acetonitrile to 186 nm in ethyl acetate. The chromeno[2,3-b]indoles’ fluorescence quantum yield was evaluated at 280 nm using tryptophan in water as a reference and at 313 nm using naphthalene.

Table 8. Fluorescence quantum yield (Φ_fl) of the chromeno [2,3-b]indole derivatives 47a–c in acetonitrile and ethyl acetate at 280 nm (tryptophan in water as reference) and at 313 nm (naphthalene in ethanol as reference).

Compound	Fluorescence Quantum Yield
	Acetonitrile		Ethyl Acetate
	280 nm	313 nm	280 nm	313 nm
47a	3.7	3.5	3.9	3.7
47b	3.6	3.7	4.3	3.5
47c	3.9	3.6	3.7	3.4

displays the fluorescence quantum yields of obtained compounds.

The investigated chromeno[2,3-b]indoles 47a–c produce fluorescence at a significantly lower energy compared to their absorption, and their fluorescence spectra exhibit a solvatochromic shift, which suggests intramolecular charge transfer in the excited state. The three chromeno[2,3-b]indoles’ with strong Stokes-shifted fluorescence suggests that they may be used as luminescent solar concentrators or scintillators.

Li et al. [39] obtained a fused five-membered azaheterocycle with an aggregation-induced emission (AIE) characteristic using an unanticipated regioselective photoreaction.

The starting compound o-TPBQ 48 were easily prepared through a facile one-step synthetic route via a modified Sonogashira coupling reaction according to the previously reported literature [43,44].

The authors proposed all of the potential products, including the common six-membered ones, 50 C₆-TPBQ′ and 51 C₆-TPBQ″, as well as the five-membered ring product 49 (C₅-TPBQ), although the likelihood of this is very low. They also considered the specific location of the N atom in o-TPBQ and the reported literature on the photoreaction. Surprisingly, the typical six-membered cyclized product (C₆-TPBQ’ or C₆-TPBQ”) was not obtained; instead, only the five-membered cyclized product 49, C₅-TPBQ, was obtained (see Scheme 16). NMR and high-resolution mass spectroscopies were used to confirm the structure of C₅-TPBQ.

In DMSO/water solutions with various water fractions, the photoluminescence spectra of C₅-TPBQ were recorded. This compound has a low fluorescence quantum yield in DMSO solution (1.1%), and when water is gradually added to the solution, an increased photoluminescence signal is obtained. The AIE characteristic was demonstrated by the 110-fold increase in emission intensity in DMSO/water mixes with 99% water compared with DMSO solution.

This research provides a method for quickly and easily creating fused five-membered azaheterocyclic compounds with unique fluorescence properties. These compounds have a wide range of uses in the biological and optoelectronic domains.

Having in view the synthesis of new 1H-pyrazolo[3,4-b]quinoxaline (PQX) derivatives with specific photophysical properties as potential materials for optoelectronics, Wojtasik et al. [45] tried to improve the Cadogan synthesis of these compounds. The authors used triphenylphosphine as reducing agent, in dimethylacetamide (DMAc) at 240 °C, under microwave irradiation and obtained PQX derivatives in much shorter time and with better yields of the final product (see Scheme 17).

The substrates 52a–g were obtained by the coupling of the appropriate 2-iodonitrobenzene derivatives 54 with 1,3-disubstituted 5-aminopyrrazole 55 in the presence of palladium catalyst and BINAP (2,2′-bis(diphenylphosphino)-1,1′-binaphtyl), as is presented in Scheme 18. By this reaction, authors obtained the best yields, despite the long reaction time.

The recorded emission spectra of compounds 53e–g reveal an emission maximum between 436 nm and 483 nm, according to the nature of the substituents from the 6th position and the used solvent. These results are presented in the

Table 9. The photophysical constants of the compounds 23e–g in different solvents.

Compound	Solvent	c [mol dm3]	λabs [nm]	ε(λabs) [M−1 cm−1]	λem [nm]	Φfl [%]
53e	MCHX	2.94 × 10−5	396	5315	436	1.0
	THF	4.68 × 10−5	399	3816	459	1.5
	ACN	4.89 × 10−5	398	3865	461	2.1
53f	MCHX	3.68 × 10−5	402	5324	442	0.7
	THF	3.83 × 10−5	404	5175	467	3.4
	ACN	4.02 × 10−5	406	4852	479	67.2
53g	MCHX	3.17 × 10−5	399	4051	443	1.0
	THF	3.43 × 10−5	397	4055	480	6.8
	ACN	3.44 × 10−5	397	4156	483	11.6

λ_abs—spectral position of the first absorption maxima, ε(λ_abs)—magnitude of the molar absorptivity of λ_abs, λ_em—the spectral position of the fluorescence maxima, Φ_fl—the fluorescence quantum yield, MCHX-methylcyclohexane, THF—tetrahydrofuran, CAN—acetonitrile.

.

The introduction of the electron donor substituent (methyl group-53e) in the 6th position of 1,3-dimethyl-1H-pyrazolo[3,4-b]quinoxaline 53d did not changed the emission properties comparing with the unsubstituted 53d system, while the electron-accepting substituents (chlorine-53f and trifluoromethyl group-53g) shifted the fluorescence band twoards longer wavelenghts by 8 nm to 21 nm, respectively, and induced an increase of the quantum yield of the fluorescence.

In order to develop a new family of thermally activated delayed fluorescence (TADF) emitters, utilizing the donor-acceptor scaffold, Goya et al. [46] focused on the use of the electron-deficient azaaromatic scaffold in place of the usual dibenzo[a,j]phenazine (DBPHZ) unit. Organic compounds that can display TDAF are very intense studied as emitters for efficient OLEDs, since they can achieve theoretically 100% internal quantum efficiency (IQE) by harvesting electrically generated triplet excitation and convert into the emissive singlet excitations through reverse intersystem crossing (rISC).

Pyrido[2,3-b]pyrazine (PYPZ) moiety was selected as the electron-acceptor (A) unit, due to the both pyridine and pyrazine π-deficient heterocycles. When this electron deficient core is connected with an appropriate electron-donor (D), intramolecular charge-transfer (ICT) in the excited state will occur and CT states should become the first singlet excited state (S1). As donor part was selected dihydrophenazasiline (DHPHAzSi) since DHPHAzSi compounds are moderate electron donor.

The 7-bromo-2,3-diphenylpyrido[2,3-b]pyrazine 59 and 10-bromo-acenaphtho[1,2-b]pyrido[2,3-e]pyrazine 61 donors were bonded to the corresponding DHPHAzSi acceptors through the Pd-catalyzed Buchwald-Hartwig amination in good yields (see Scheme 19).

The starting compounds 59 and 61 were prepared according to the literature procedures [47,48], through the condensation between 2,3-diamino-5-bromopyridine with benzyl and phenanthrene-9,10-dione, respectively.

The photophysical properties of compounds 56–58, were investigated in a non-polar polymer matrix Zeonex^®, and in small molecule hosts, 4,4′-bis(N-carbazolyl)-1,1′-biphenyl (CBP) and tris(4-(9H-carbazoyl-9-yl)phenyl)amine (TCTA) and are presented in

Table 10. The photophysical properties of the compounds 56–58.

Compound	Host	λem [nm]	Φfl [%]	τPF [ns]	τDF [μs]	DF/PF	EA [eV]	S1 [eV]	T1 [eV]	ΔEST [eV]
56	Zeonex®	527	25	13.24 ± 1.18	9.45 ± 0.98	6.08	0.024	2.46	2.27	0.19
	CBP	555	34	25.28 ± 1.06	1.06 ± 0.11	1.57	0.031	2.24	2.12	0.12
	TCTA	555	26	32.29 ± 0.57	2.10 ± 0.44	1.20	0.026	2.25	2.07	0.19
57	Zeonex®	521	8	8.68 ± 0.09	0.7 ± 0.06	5.16	0.062	2.37	2.26	0.11
	CPB	553	29	17.67 ± 0.18	2.7 ± 0.24	1.99	0.033	2.28	2.05	0.22
	TCTA	551	14	26.81 ± 0.83	3.92 ± 0.32	1.14	0.037	2.26	2.05	0.21
58	Zeonex®	507	6	7.27 ± 0.32	9.90 ± 0.76	3.15	0.061	2.44	2.34	0.10
	CPB	535	20	11.84 ± 0.42	10.9 ± 0.66	0.78	0.036	2.33	2.07	0.27
	TCTA	529	10	32.45 ± 1.23	5.26 ± 0.71	1.17	0.034	2.34	2.09	0.25

λ_em—the maximum wavelength of photoluminescence spectra, Φ_fl—photoluminescence quantum yield in degassed, τ_PF—prompt fluorescence lifetime, τ_DF—delayed fluorescence lifetime, DF/PF—the ratio of delayed fluorescence to prompt fluorescence, EA—activation energy of the triplet to singlet transfer, error ± 0.01 eV, S₁—singlet energy, error ± 0.03 eV, T₁—triplet energy, error ± 0.03 eV, ΔE_ST—energy splitting, error ± 0.03 eV, Zeonex^®—Cyclo Olefin Polymer is an engineered plastic that provides “glass-like” transparency, low protein absorption, high purity, low water absorption, and excellent moisture barrier. All parameters were estimated at 300 K.

.

Compounds 56–58 manifest emissions in two different time domains. The first component is the prompt fluorescence (PF) from the singlet excited state (S1), with a lifetime in the nanosecond time delay, and the second components are the delayed emissions from the high triplet excited state (T2) (as theoretical calculations revealed), decaying in micro to millisecond delay time.

Georgescu et al. [49,50,51] studied the synthesis and fluorescence of 3-aryl-7-benzoyl-pyrrolo[1,2-c]pyrimidines in order to determinate the influence of the chemical structure and of solvent polarity on their optical properties.

The authors used, for the synthesis of 3-biphenyl-pyrrolo[1,2-c]pyrimidines, a one-pot, three-component procedure [49,50], which involve a 1,3-dipolar cycloaddition reaction of a 4-biphenyl pyrimidinium-N-ylide with an activated alkyne 65 in 1,2-epoxybutane at reflux. The ylide is generated “in situ” from the corresponding pyrimidinium salts that was formed by the N-alkylation of the pyrimidine 63 with halogenoketone 64. The advantage of performing the reaction in a one-pot three-component approach is the direct formation of the final aromatic compounds 66a–j, avoiding the formation of dipyrimidino-pyrazinic inactivated products (see Scheme 20).

The absorption and emission spectra of compounds 66a–j were recorded in acetonitrile:chloroform (1:1) (3.5 * 10⁻⁶ mol/L) solutions. The fluorescence quantum yield has been calculated (

Table 11. The main spectral features of the compounds 4a–j in acetonitrile:chloroform (1:1).

Compound	Absorption				Emission							Reference
	λabs1 [nm]	ε1 [L/(mol cm)]	λabs2 [nm]	ε2 [L/(mol cm)]	λex1 [nm]	λem1 [nm]	λex2 [nm]	λem2 [nm]	Δν1 [cm−1]	Δν2 [cm−1]	Φfl [%]
66a	293	49,337	386	105,456	268	453	383	454	15,238	4083	4.64	[50]
66b	263	25,640	389	34,200	262	459	354	466	16,381	6789	6.42	[50]
66c	262	87,480	381	144,430	262	462	381	463	16,552	4648	19.02	[50]
66d	266	43,920	384	68,180	2658	462	389	466	15,668	4536	6.35	[50]
66e	270	18,880	399	20,706	270	457	400	462	15,155	3354	0.18	[50]
66f	290	38,272	383	68,795	290	435	380	446	11,494	3894	55.27	[50]
66g	268	34,200	398	44,780	262	451	360	463	15,994	6179	3.47	[50]
66h	262	65,250	380	77,820	263	430	380	460	14,767	4576	8.91	[50]
66i	292	39,784	380	34,836	264	455	380	464	15,900	4764	15.37	[50]
66j	260	40,740	381	44,950	329	478	358	472	9860	6740	11.85	[49]

λ_abs—the maximum wavelength of absorption, ε—the molar absorption coefficient, λ_ex—excitation wavelength, λ_em—the maximum wavelength of photoluminescence, Φ_fl—photoluminescence quantum yield, Δν—Stokes shifts.

) for all compounds 66a–j using Equation (1) using quinine sulphate as standard.

$${\Phi }_{\mathrm{f}\mathrm{l}}={\Phi }_{\mathrm{r}\mathrm{e}\mathrm{f}}\times \frac{\mathrm{I}}{\mathrm{A}}\frac{{\mathrm{A}}_{\mathrm{r}\mathrm{e}\mathrm{f}}}{{\mathrm{I}}_{\mathrm{R}\mathrm{e}\mathrm{f}}}\times \frac{\mathrm{n}}{{\mathrm{n}}_{\mathrm{r}\mathrm{e}\mathrm{f}}}$$

(1)

In order to calculate the quantum yield (Φ_fl), according to the Equation (1) we need to determine the maximum value of the absorbance at the emission wavelength λ_em2, (A), area of the emission peak (I), and refractive index (n) for the solution of investigated compound, and quantum yield (Φ_ref), maximum value of the absorbance at the emission wavelength λ_em2 (A_ref), area of the emission peak (I_ref), and refractive index (n_ref) for the standard solution (quinine sulphate), respectively.

Looking at the values from Table 11, it can be seen that two of the compounds (66c p-flouoro substituted and 66f 3,4-dimethoxy substituted) have higher values of quantum yield. These higher values of quantum yield can be explained by a more extended π electron conjugated system in the case of this compound. Ethyl 3-(4-biphenylyl)-7-(3,4-dimethoxybenzoyl)pyrrolo[1,2-c]pyrimidine-5-carboxylate was found to have the highest quantum yield value (55%). These higher quantum yield values suggest that the studied compounds are promising candidates for fluorescent chemical sensors.

In view of future exploitation of pyrrolo[1,2-c]pyrimidine compounds in the field of bio-imaging investigations Georgescu et al. [51] synthesized a series of new pyrrolo[1,2-c]pyrimidine derivatives and studied their photophysical properties. The synthetic approach was similar with the one described above, but this time did not use the one pot strategy, but only by the 1,3-dipolar cycloaddition of the pyrimidinium ylides generated “in situ” from the corresponding pyrimidinium bromides 67 with the alkyne dipolarophiles 68 in 1,2-epoxybutane as reaction medium and acid scavenger (see Scheme 21).

The photophysical properties of fused derivatives 69a–j were investigated by using different sorts of solvents (see

Table 12. The spectroscopic features for absorption and fluorescence of 69a–j in chloroform solution (10⁻⁶ M).

Compound	R4	Absorption				Emission
		λabs1 [nm]	ε1 [L/(mol cm)]	λabs2 [nm]	ε2 [L/(mol cm)]	λex [nm]	λem [nm]	Δν1 [cm−1]	Δν2 [cm−1]	Φfl [%]
69a	H	268	23,300	396	39,100	396	462	15,668	3608	51.77
69b	H	265	25,200	400	36,800	400	462	16,091	3355	38.26
69c	H	275	29,090	397	47,900	397	458	14,530	3355	61.35
69d	H	258	42,300	405	53,800	405	437	15,876	1808	42.40
69e	CO2Me	261	44,620	386	46,960	386	463	16,716	6786	11.04
69f	CO2Et	252	39,520	390	50,630	390	539	21,130	7088	2.64
69g	CO2Me	242	42,770	392	57,930	392	440	18,595	6957	6.63
69h	CO2Et	250	61,060	395	65,910	395	456	18,070	3387	2.99
69i	CO2Me	242	25,600	396	27,850	396	450	19,100	3030	27.46
69j	CO2Me	268	56,200	388	47,200	388	535	18,622	7116	3.24

λ_abs—the maximum wavelength of absorption, ε—the molar absorption coefficient, λ_ex—excitation wavelenght, λ_em—the maximum wavelength of photoluminescence, Φ_fl—photoluminescence quantum yield calculated using quinine sulphate standard, Δν—Stokes shifts.

). In chloroform, compounds derived from the ethyl propiolate, 69a–d, present better fluorescence yield than the compounds derived from the symmetric alkynes 69e–j. The excitation, during the recording of the emission spectra, was performed at λ_abs2 at which a higher intensity of the fluorescence was obtained. A main emission band is located in the blue region of the visible spectrum in 437–463 nm region.

The authors [51] investigate the influence of all R₁, R₂, R₃ and R₄ substituents on the fluorescence properties of the synthesized compounds and concluded that a substituent that determine the growth of conjugation inside the pyrrolo[1,2-c]pyrimidine fragment lead to an increase of the fluorescence, while a substituent that determine the decrease of conjugation inside the pyrrolo[1,2-c]pyrimidine fragment lead to decrease of the fluorescence.

Tomashenko et al. [52] obtained new pyrido[2,1-a]pyrrolo[3,2-c]isoquinoline 76a–c heterocyclic system by using Pd to catalyze the intramolecular cyclization of 1-[1-benzyl-2-(2-bromophenyl)-1H-pyrrol-3-yl]pyridin-1-ium bromides 74a–c (see Scheme 22).

The obtained compounds 76a–c have fluorescent properties in solutions, with quantum yields for 76c in methanol reaching 81%. Photophysical data were studied in toluene, acetonitrile, dichloromethane (DCM) and methanol, respectively (

Table 13. Photophysical properties of compounds 76a–c in toluene, acetonitrile, dichloromethane (DCM) and methanol solutions at room temperature, λ_ex = 420 nm. Lifetimes (τ) were determined at λ_max of the emission bands.

Compound	Solvent	Emission λmax nm	Excitation λmax nm	τ ns	Φfl %
76a	MePh	602	337, 430, 516	4.6 ± 0.5	14
	MeCN	598	405, 494	3.9 ± 0.5	8
	DCM	590	329, 413, 502	5.5 ± 0.5	18
	MeOH	507	295, 428	9.0 ± 0.5	76
76b	MePh	640	427, 528	1.0 ± 0.2	7
	MeCN	630	401, 498	1.0 ± 0.2	0.7
	DCM	628	438, 500	1.0 ± 0.2	3
	MeOH	530	292, 426	10.3 ± 0.5	47
76c	MePh	645	440, 539	1.4 ± 0.2	7.5
	MeCN	642	417, 513	1.5 ± 0.2	2.5
	DCM	626	330, 420, 522	1.7 ± 0.2	9
	MeOH	537	443	7.5 ± 0.5	81

Τ—fluorescence lifetime, Φ_fl—photoluminescence quantum yield.

). The obtained compounds display moderate to strong fluorescence in solution, giving minor variations in emission maxima position with changes in solvent polarity. The biggest effect was shown in methanol solutions and upon addition of proton donors to aprotic solvents.

2.4. Our Recent Contribution to the Field

Nitrogen ylide chemistry is a traditional research area in our group, professors Zugravescu and Petrovanu being the pioneer of this field [53]. Several compounds with complex azaheterocyclic skeleton were synthesized through the N-ylides. Many of these compounds present practical importance either to their biological activities, having antimicrobial [40,41], anticancer [42,54,55,56,57,58], antitubercular [58,59,60,61] or anti-leishmaniasis [62] activity, or to their optical properties (some of this compound presenting intense blue fluorescence) [63,64,65,66,67,68,69]. Here we will present our recent (last 12 years) achievements in the synthesis of fluorescent azaheterocyclic compound.

In one extensive work [63,64], we carried out a comprehensive investigation into the synthesis of fluorescent pyrrolodiazine (PD). All PD derivatives 78–82 were produced using a methodology which involve two steps. In the first stage, diazinium salts 78a–h were obtained by quaternization of diazine [pyridazine (PY) or phthalazine (PH)] with halogenated derivatives with increased reactivity. In the 2nd stage, a typical Huisgen [3+2] dipolar cycloaddition of diazinium ylides 78′ to the corresponding dipolarophiles were performed (see Scheme 23).

The synthesis of the desired pyrrolodiazine derivatives 79–82 was performed under conventional thermal heating (TH) and using MW irradiation, by a typical Huisgen [3+2] dipolar cycloaddition. The reactions under MW irradiation have shown some important advantages such as significantly higher yields, decreasing the reaction time from hours to 5 min and five times less amount of solvent is needed.

To obtain a perspective on the effect that the C-7 substituent of the pyrrolodiazine skeleton the photoluminescent properties of the obtained compounds were measured in different solvents and are presented in

Table 14. λ_max (nm) of absorption spectra, fluorescence spectra, and relative quantum yields (%) of PD compounds 79–82.

Compound	Fluorescence (λmax, nm) (Quantum Yields (%))			Absorption (λmax, nm)
	EtOH	CHCl3	Cyclohexane	EtOH	CHCl3	Cyclohexane
79a	431 (70)	430 (90)	430 (83)	343	351	355
79b	431 (70)	429 (90)	430 (83)	343	352	355
79c	429 (63)	431 (82)	434 (76)	356	362	366
79d	446 (1)	436 (8)	433 (11)	334	335	329
79e	448 (2)	439 (3)	434 (-)	334	334	329
79f	451 (1)	438 (7)	436 (10)	332	333	327
79g	487 (1)	471 (1)	insoluble	374	375	insoluble
79h	448 (4)	431 (5)	434 (8)	314	319	322
80a	430 (66)	423 (91)	416 (85)	349	357	361
80b	429 (66)	422 (91)	416 (85)	349	358	361
80c	436 (89)	437 (76)	insoluble	365	370	insoluble
80d	442 (1)	436 (5)	insoluble	333	335	insoluble
80e	430 (2)	436 (7)	insoluble	330	332	insoluble
80f	433 (1)	437 (4)	432 (8)	333	334	329
80g	446 (4)	430 (5)	432 (9)	315	319	322
80h	446 (4)	430 (4)	432 (8)	316	320	322
80i	448 (3)	432 (2)	insoluble	319	322	insoluble
81b	442 (2)	439 (2)	insoluble	326	321	insoluble
81c	427 (1)	439 (5)	insoluble	316	304	insoluble
82a	430 (9)	427 (18)	415 (40)	470	479	496
82b	430 (9)	427 (18)	415 (40)	470	479	496
82c	432 (3)	424 (4)	420 (4)	485	488	508
82d	433 (4)	424 (4)	419 (4)	484	488	508

.

While the partially saturated dihydro-pyrrolo-PY (82a–d) are red-shifted and have a poor or moderate quantum yield (around 5–40%), the tetrahydro-pyrrolodiazine (81b,c) have a negligible quantum yield (less than 5%). The fully aromatized pyrrolo-PY (79a–c and 80a–c) are highly powerful blue emitters with extremely high quantum yields (up to 90%). The highly blue emitters of completely aromatized pyrrolo-PH (79h and 80g–i) exhibit a low quantum yield of less than 10% and an unusual, blue-shifted absorption with λ_max of absorption around 314–322 nm.

Regarding the effect of the substituent from the 7th position of the pyrrolodiazine skeleton, the pyrrolo-PY compounds exhibit intense blue fluorescence and have a very high quantum yield when the substituent is an ester or amide group, whereas the quantum yield is negligibly low when the substituent is a ketone (see Scheme 24).

We confirmed the experimental results through theoretical calculations into another study from our group [65]. According to computational study, the first nπ* state may be significantly stabilized when the carbonyl group from the 7th position of the pyrrolo-PY moiety is oriented so that it faces the diazine nitrogen. Given the lower (fluorescent) ππ* state expected for all conformations, such an effect does not seem to affect the fluorescence of the ester derivative. On the other hand, we found that the same nπ* state is predicted to have a lower energy than the first ππ* state for the most stable conformation of the benzoyl-substituted derivative, which is consistent with the weak fluorescence that was experimentally seen.

We demonstrate how the highly fluorescent ester-substituted pyrrolopyridazine’s solvent-dependent photophysical characteristics can be accurately predicted by TD-DFT in SS-PCM solvation when hybrid functionals such as B3LYP or PBE0 are used, together with a reasonable basis set.

In order to increase the fluorescent properties of the pyrrolo-PY derivatives, we studied the influence of the substituent from phenyl ring on the 2nd position of pyrrolo-PY skeleton [66], and used the strategies adopted for construction of fluorescent pyrrolo-PY derivatives are similar to those presented in the previous study [64] (see Scheme 25).

The reactions under MW irradiation have shown some important advantages such as slightly higher yields and decreasing of the reaction time from 2 h to 5 min in liquid phase and 15 minutes in solid phase.

For the obtained compounds 86 and 87, we investigated the photoluminescent properties (see

Table 15. The spectroscopic features for absorption and fluorescence intensity of 86a–d and 87a–d in in acetonitrile solution (5 × 10⁻⁵ M).

Compound	λmax (nm) [ε (L mol−1 cm−1) × 103]					Fluorescence Intensity
	Number of Absorption Maxima
	I	II	III	IV	V
86a	356.00 [2.65]	347.00 [2.33]	277.00 [30.33]	264.00 [25.02]	225.00 [11.30]	6276.11
86b	357.00 [2.93]	337.00 [2.58]	280.00 [32.95]	263.00 [26.00]	226.00 [11.90]	6554.21
86c	355.00 [2.93]	341.00 [2.80]	284.00 [30.23]	265.00 [24.15]	228.00 [11.91]	7510.05
86d	356.00 [3.00]	340.00 [2.73]	284.00 [31.68]	264.00 [24.73]	227.00 [11.75]	8264.76
87a	344.00 [3.50]	340.00 [3.46]	276.00 [31.15]	264.00 [26.75]	226.00 [7.45]	5016.82
87b	350.00 [3.18]	335.00 [2.95]	276.00 [32.38]	264.00 [26.75]	226.00 [11.51]	5269.64
87c	350.00 [3.18]	335.00 [3.01]	282.00 [30.21]	265.00 [25.68]	227.00 [6.00]	6018.34
87d	350.00 [3.31]	334.00 [3.06]	276.00 [34.46]	264.00 [29.01]	228.00 [12.33]	6304.55

).

The pyrrolo-PY substituents had some effect on the absorbance and fluorescence properties. Thus, the cycloadducts with carboethoxy groups, in the seventh position have a more fluorescence than those with a carbomethoxy groups, in the same position and also the cycloadducts with a para-chlorophenyl substituent in the second position of pyrrolo-PY moiety have a more fluorescence than those para-bromophenyl substituted.

Continuing our studies [67], we synthesized a new class of fused pyrrolodiazines 91–95 in order to obtain new fluorescent compounds by the same strategy-obtaining of the N-ylides fallowed by their cycloaddition with activated alkynes (see Scheme 26). The reactions were conducted both under conventional TH and MW irradiation. The reactions under MW irradiation have shown a series of advantages such as decreasing the reaction time from 6 hours to 10 minutes and slightly higher yields.

After the synthesis of the desired pyrrolodiazines, we investigated their photoluminescent properties in non-polar solvents cyclohexane and dichloromethane. The measured parameters are presented in

Table 16. λ_max (nm) of absorption spectra, λ_max (nm) of emission spectra, and relative quantum yields (%) of compounds 91–95.

Compound	Fluorescence (λmax, nm) (Quantum Yields (%))		Absorption (λmax, nm)
	Cyclohexane	Dichloromethane	Cyclohexane	Dichloromethane
91	426 (24)	432 (21)	360	358
92	422 (25)	426 (26)	356	354
93	428 (7)	441 (5)	327	325
94	439 (6)	446 (4)	324	322
95	491	-	374	372

λ_exe = 360 nm for samples 91 and 92; λ_exe = 320 nm for samples 93 and 94; λ_exe = 370 nm for sample 95.

.

A relationship between structure of cycloadducts and fluorescence quantum yields was founded. Thus, the compounds with pyrrolo-pyridazine skeleton showed good quantum yield (around 25%), while compounds with pyrrolophthalazine skeleton showed a lower quantum yield.

In the next step we obtained some new bromoderivatives with increased reactivity by bromination of fluorescent pyrrolodiazines in heterogeneous catalysis in the presence of copper (II) bromide (see Scheme 27). These bromo-derivatives can fluorescently label biological macromolecules due to their increased reactivity, being easily incorporated in those bio-macromolecules.

Having in view the results of the previous studies, we prepared a new family of pyrrolobenzo[f]quinoline derivatives [68] in order to obtain blue fluorescent azaheterocyclic derivatives. The pyrrolobenzo[f]quinolines 102a–c, 103a–c and 104c were obtained by the same setup. In the first stage, benzo[f]quinolinium salts 100a–c were obtained by quaternization of benzo[f]quinoline with bromoketones. In the 2nd stage, a typical Huisgen [3+2] dipolar cycloaddition of benzo[f]quinolinium ylides 101a–c to the alkyne as dipolarophiles was performed (see Scheme 28). A comparative study of these reactions was carried out under conventional thermal heating and under ultrasound (US) irradiation. The reactions under US irradiation have shown a series of advantages such as decreasing the reaction time from 2 days to 2 hours and slightly higher yields.

The photophysical properties of azatetracyclic derivatives 102a–c, 103a–c and 104c were studied in cyclohexane and trichloromethane, respectively, and are presented in

Table 17. λ_max (nm) of absorption spectra and λ_max (nm) of emission spectra of compounds 102a–c, 103a–c and 104c.

Compound	Fluorescence (λmax, nm)		Absorption (λmax, nm)
	Cyclohexane	Trichloromethane	Cyclohexane	Trichloromethane
102a	434	439	399	403
102b	434	440	399	402
102c	440	445	384	386
103a	432	432	378	381
103b	432	433	376	375
103c	451	430	373	370
104c	450	449	374	369

λ_exc = 396 nm for samples 102a and 102b; λ_exc = 380 nm for sample 102c; λ_exc = 370 nm for samples 103a and 103b; λ_exc = 365 nm for samples 103c and 104c.

.

The obtained cycloadducts are blue emitters having λ_max of fluorescence around 430–450 nm. The cycloadducts with similar structure 102a,b and 103a,b present small differences in their electronic spectra, while the cycloadducts with bulky pivaloyl group 102c and 103c or without keto group in the 3rd position 104c shows more intense fluorescence emission.

As a continuation of this work, in another study [69] we derivatized the previously obtained cycloadducts 102a,b and 103a,b in order to use this blue fluorescent azaheterocyclic derivatives as fluorescent biomarkers. In the first step, we applied this functionalization to the tetracyclic cycloadduct products 102a,b and 103a,b by the bromination in heterogeneous catalysis obtaining a mixture of mono or dibrominated product type 105a–d and 106a–d (see Scheme 29). This bromo-derivatives can fluorescently label biological macromolecules (peptides, proteins, DNA) due to their increased reactivity, being easily incorporated in those bio-macromolecules.

In the next step, by a nucleophilic substitution, the monobrominated cycloadducts 105a–d were used as starting materials for the synthesis of corresponding azides 107a–d. The reaction was carried out in tetrabutylammonium bromide (TBAB) as phase transfer catalyst and in a chloroform/water mixture (see Scheme 29).

For the new fluorophores (bromides 105a–d and azides 107a–d) we investigated optical properties on chloroform diluted solutions (see

Table 18. λ_max (nm) of absorption spectra, λ_max (nm) of emission spectra and fluorescence quantum yield (%) of compounds 105a–d and 107a–d.

Compound	Fluorescence (λmax, nm)	Absorption (λmax, nm)	Quantum Yields (%)
105a	443	394	22.11
105b	431	391	18.64
105c	444	412	15.92
105d	433	393	17.09
107a	430	406	9.34
107b	435	387	7.17
107c	430	409	8.99
107d	445	393	5.30

λ_exc = 380 nm for sample 107b; λ_exc = 385 nm for samples 105a, 105b, 105d and 107d; λ_exc = 400 nm for samples 105c, 107a and 107c.

).

When comparing the fluorescence intensity of the bromides 105a–d to the fluorescence of the azides 107a–d, we observed a decrease in fluorescence, due the alteration of the planar structure of the molecule. The same effect is highlighted when comparing the fluorescence intensity of the underivatized cycloadducts 102a,b and 103a,b with the fluorescence intensity of the derivatized azatetracyclic bromides 105a–d or azides 107a–d.

Another research field of interest to us, is of the compounds which contain a pyrrolo[2,1-a]isoquinoline or imidazo[2,1-a]isoquinoline framework, due to their potential biological activity, but also to their extended π-conjugated systems that make them excellent candidates for photophysical applications [70]. Thus, we synthesized several new pyrrolo [2,1-a]isoquinolines and imidazo[2,1-a]isoquinolines in order to realize a complete study regarding their photophysical properties and potential applications in the field.

The chosen method for the assembly of fused target polyheterocycles relied on 1,3-dipolar cycloaddition of different isoquinolinium ylides 111a–c (in situ generated in basic medium from corresponding salts 110a–c, which were obtained by isoquinoline 108 alkylation with halides 109a–c) to ethyl propiolate or ethyl cyanoformate. The intermediate dihydropyrrolo[2,1-a]isoquinolines 112′a–c underwent oxidative dehydrogenation under atmospheric conditions, yielding the final compounds 112a–c in good yields (63–80%). Using ethyl cyanoformate as dipolarophile in similar conditions, we obtained imidazo[2,1-a]isoquinolines 113a–c presumably via dihydroderivatives 113′a–c (see Scheme 30).

The electronic absorption and emission spectra of the obtained azaheterocycles were recorded in dichlorometane (DCM) and dimethylsulphoxide (DMSO), and are presented in

Table 19. Photophysical properties of isoquinoline derivatives.

Compound	Solvent	λabs [nm]	λem [nm]	Φfl [%]	τ1 [ns]	τ2 [ns]
112a	DCM	352, 335, 320, 275, 244	356, 374, 392, 415sh	28.37
	DMSO	353, 336, 321, 276	359, 376, 395, 415sh	63.47	0.069	3.115
112b	DCM	358, 341, 325, 274, 246	363, 381, 401, 425sh	20.10
	DMSO	358, 341, 325, 275	361, 382, 401, 425sh	53.95	0.866	3.095
112c	DCM	358, 341, 324, 274, 247	363, 381, 401, 425sh	31.28
	DMSO	358, 341, 325sh, 275	364, 382, 400, 425sh	55.76	0.112	3.219
113a	DCM	338, 323, 309, 252	340, 356, 375, 395sh	41.04
	DMSO	339, 324, 309	345, 361, 378	3.36	0.031	2.785
113b	DCM	338, 323, 309, 251	344, 360, 374, 400sh	18.37
	DMSO	338, 324, 309	346, 360, 374	7.96	0.060	2.700
113c	DCM	338, 323, 309, 252	345, 359, 375, 400sh	29.41
	DMSO	339, 323, 309	346, 359, 372	15.95	0.036	5.400

λ_abs—the maximum wavelength of absorption spectra, λ_em—the maximum wavelength of photoluminescence spectra, Φ_fl—photoluminescence quantum yield, τ—fluorescence lifetime, sh—shoulder.

. The substituents on the 1st and 3rd positions of the pyrrole ring (COOMe, COOEt) have a low influence on the spectral pattern of pyrroloisoquinolines 112b and 112c. In addition, the solvent polarities have little to no influence on the electronic absorption spectra of pyrrolo- and imidazo-isoquinolines, suggesting that the ground state of these derivatives is not influenced by the solvent polarity. The extended π-π* conjugation in the imidazoisoquinolines system due to the substituents from the 1st and 3rd positions of the pyrrole ring induced a bathochromic shift of the absorption maxima. In DMSO, in the case of pyrroloisoquinolines, a hypsochromic shift of the absorption band occurs.

In the case of the compound 112a containing CN group on the pyrrole ring, a similar behaviour of the emission spectra to absorption spectra was observed, namely a hypsochromic shift in both DCM and DMSO solvents, and no influence of the solvent polarity on the position of the emission maxima. The substituents on the pyrrole ring have no influence on the position of emission bands for derivatives 113a–c, excepting on the compound 113a which displays a hypsochromic shift in dichloromethane. The emission bands of imidazoisoquinolines 113a–c are hypsochromic shifted in DCM and DMSO comparing with the emission bands of pyrroloisoquinoline derivatives 112a–c. Time-correlated single photon counting (TCSPC) technique was used to determine the luminescence lifetimes. In DMSO, over the entire emission range, a double-exponential function describes better the emission decays for all investigated compounds. In DMSO, pyrroloisoquinolines 112a–c have longer fluorescence lifetime τ1 than those of imidazoisoquinolines 113a–c. The lifetimes of the excited-state for all compounds are in the nanosecond timescale.

Indolizine derivatives with phenanthroline skeleton [71,72,73] were another research field in our group due to both their potential biological activities and their extended π-electron system which make them valuable materials in the construction of new optoelectronic devices. Compounds 114a–g and 115a–e were synthesized in our group using the same 3+2 dipolar cycloaddition strategy of cycloimmonium ylides to activated alkynes (see Scheme 31) [71]. In this case 4,7-phenanthrolin-4-ium and 1,7-phenanthrolin-7-ium ylides, generated from the corresponding monoquaternary 116 and 117 salts, were added to ethyl propiolate or dimethyl acetylene dicarboxylate DMAD.

The absorption spectra of all the compounds present the fine structure specific to phenanthrene spectrum. The extended π-system of the 1,7-phenanthroline compounds explained the bathochromic shift to longer wavelength absorption band as compared to the UV-Vis absorption spectra of 4,7-phenanthroline derivatives. The position of the absorption and emission maxima of phenanthroline derivatives are highly influenced by the substituents on the pyrrole ring, as can be observed from

Table 20. Photophysical characteristics of some phenanthroline derivatives.

Compound	Φfl [%]	τ1 [ns]	τ2 [ns]	τ3 [ns]	f1	f2	f3
114a	38.71	4.41
114b	17.87	3.39
114c	16.89	0.48	9.35		0.23	0.77
114e	75.42	4.00
114f	6.65	0.41	2.51	8.12	0.37	0.25	0.38
114g	6.09	0.60	8.06		0.57	0.43
115a	33.10	3.12
115b	6.16	0.76	4.45		0.94	0.06
115e	4.43	3.73

Φ_fl—photoluminescence quantum yield, τ—fluorescence lifetime, f—the weighted contribution.

. The introduction of CN, COOMe and COOEt groups in the 9th and 7th positions of the pyrrole ring determine a hypsochromic shift of the absorption and emission maxima of phenanthroline derivatives (114a, 114b, 115a). The same effect on the absorption and fluorescence spectra is obtained when a third substituent (COOMe) is introduced in the 8th position of the pyrrole ring, only in the case of the compound 114e.

The phenanthroline derivatives displayed broad and structureless emission band in 425 to 480 nm depending on the substituent nature at the pyrrole moiety. For 1,7-phenanthroline derivatives the emission band vas found in the 440–450 nm region, while for 4,7-phenanthrolines the emission band was found in 425–480 nm region. The position and the nature of the substituent at the pyrrole ring have a great influence on the fluorescence quantum yield of pyrrolo-phenanthroline derivatives. Scheme 32 illustrates the effect of substituents from the pyrrole ring on the fluorescence yield of pyrrolophenanthroline derivatives.

The fluorescence emission of disubstituted phenanthroline derivatives (114d, 115c, 115d) is practically quenched by the presence of halogens (Cl, Br) in the para position of phenacyl group (COC₆H₄) from 9th position of the pyrrole ring. The emission quantum yield decreases significantly (115e−0.044) when COC₆H₄OMe-(p) group is introduced in the 9th position of the pyrrole ring due to the withdrawing effect of the methoxy group which determines a decrease in conjugation in the 1,7-phenanthroline system. Time-correlated single photon counting method in dichloromethane was used for the fluorescence lifetimes (τ) estimation.

The obtaining of small organic molecules capable to be incorporated in specific biomolecules or used in biomedical optical imaging was another research field in our group. A promising scaffold able to fulfil this purpose could be the bipyridyl. Bipyridyl, having two heterocyclic cores, can involve one or both of them in the formation of ylides and/or cycloaddition products. Thus, for these compounds we can obtain mono-salts [74], mono-ylides [74], mono-cycloadducts (indolizines) [74], mono-indolizine mono-salts [75,76,77], mono-indolizine mono-ylides [75,76,77], and theoretically bis-indolizines.

In one of our studies [74] we report on the synthesis, fluorescence properties and a preliminary evaluation of pyridyl-indolizine containing anthracene moiety as a DNA binding agent. The conversion of the ethyl ester group from the 1st position of the indolizine into the corresponding propargyl-based indolizine derivative facilitate the addition of anthracenyl group through a “click” reaction. Fluorescent pyridyl-indolizine derivative 124 was synthesized in moderate yield in an adapted four step synthesis. In the first step a cycloaddition of 4,4′-dipyridinium ylide, generated from the corresponding monoquaternary 4,4′-dipyridinium phenacyl salt 118, with ethyl propiolate as activated alkyne gives an indolizine intermediate 119. Isolated indolizine 119 ester was hydrolysed into the corresponding carboxylic acid derivative 120 in the second step, then in the third step was reacted with propargyl amine to yield alkyne-substituted indolizine derivative 121, suitable for further “click” reactions. Separately, chloromethylanthracene 122 was straightforwardly transformed into corresponding azide 123. In the final step, alkyne indolizine 121 was reacted together with azide 123 in a “click” type reaction to yield the final substituted pyridyl-indolizine 124 (see Scheme 33).

The emission properties of compounds 121 and 124 were investigated in DMF at different pH values using 1xTAE buffer solutions (40 mM Tris, 20 mM acetic acid and 1 mM EDTA), and are presented in

Table 21. UV-vis and fluorescent properties of indolizines 121 and 124 in aqueous buffer at different pH.

Compound	pH	λex [nm]	λem [nm]	Stokes Shift [cm−1]
121	2.0	395	521	6123
	5.0		539	6764
	5.5		539	6764
	6.0		539	6764
	6.5		539	6764
	7.0		539	6764
	7.5		539	6764
	8.0		539	6764
	12.0		491, 526	4950, 6305
124	2.0	395	560	7459
	5.0		486, 525	4740, 6269
	5.5		480, 513	4483, 5823
	6.0		480, 514	4483, 5861
	6.5		480	4483
	7.0		480	4483
	7.5		481	4526
	8.0		482	4570
	12.0		482	4570

λ_ex—excitation wavelength, λ_em—the maximum wavelength of photoluminescence, Stokes shifts—Δν = 1/λ_ex − 1/λ_em.

. The excitation wavelength was 395 nm and the emission spectra were recorded in 425–700 nm domain.

The emission of precursor alkyne 121 at acidic pH value of 2.0 is 6-fold stronger than at pH values of 5.0–12.0, while the fluorescence intensity of compound 124 at pH = 12.0 is 7-fold greater than at pH = 5.0. In the case of the precursor alkyne 121, the emission spectrum presents a band with a shoulder at 495 nm at pH = 12.0 and a strong bathochromic shift of the emission maximum at pH values from 8.0 to 5.0, while the emission spectrum of compound 124 at pH = 5.0–12.0 presents bands with a shoulder at 475 nm. At pH = 12.0, the solution emits strongly in the green spectral window at 475 nm.

Agarose gel electrophoresis analysis and spectroscopic investigations were performed in order to investigate the interaction of nucleic acids with pyridine-indolizines 121 and 124. Thus, deoxyribonucleic acid, low molecular weight from salmon sperm (sDNA) was used as a natural double-stranded DNA to test the binding properties of these compounds by agarose gel electrophoresis. The investigation shows that both investigated compounds 121 and 124 interact with sDNA.

The interactions of compounds 121 and 124 with sDNA was examined also by UV-visible and fluorescence investigation. Absorption and emission spectra were recorded before the addition of sDNA, immediately after the addition of sDNA solution and after the incubation of the indolizine-sDNA mixture at room temperature for 24 h. The absorption spectrum of compound 121 changes only after 24 h by the decrease of the absorption band intensity. Contrarily the absorption spectrum of compound 124 showed instantaneous changes in the shape of the band, upon the addition of sDNA, the structured band yielded by anthracene suffering modifications and after 24 h transforming into a broad band with a slightly weaker intensity. Thus, the presence of the anthracene moiety in the structure of indolizine 124 facilitates easier interaction with nucleic acids due to its higher affinity for DNA when compared to the propargyl moiety of the indolizine 121. The same conclusion is obtained after the study of the fluorescence spectra of the mixtures: in case of compound 121, alteration of the initial shape or intensity of the emission band was only observed after addition of sDNA and 24 h of incubation, while for the compound 124 immediate increase in fluorescence intensity of the mixture was observed, followed by additional increase after 24 h.

In order to investigate the ability of mono-indolizine mono-salts to interact with DNA, we used spectral methods UV-vis and fluorescence spectrometry [75]. Thus, a series of mono-indolizine mono-salts 125a–e were synthesized starting from the corresponding mono-indolizines 126 by alkylating with halogeno-ketones 127. The monoindolizines 126 were obtained by the cycloaddition of the corresponding ylides, generated in situ from the mono salts 128, with ethyl propiolate (see Scheme 34).

The absorption spectra of the mono-indolizine mono-salts were recorded in aqueous solution. The electron-donating methyl or methoxy group from the last inserted aromatic ring leads to a small bathochromic shift. DNA solution was progressively added to 125a and the spectra were recorded, in order to study the interaction of compound 125a with DNA. The hypsochromic shift of dye absorption maxima with the progressive addition of the DNA solution reflect the DNA binding to 125a. Moreover, in the UV region (350–360 nm) a hyperchromic effect was observed. This typical hyperchromic effect is caused by the damaging of the DNA double-helix structure due to the intercalation of 125a to DNA.

The interaction of 125a with DNA was also investigated by emission spectra in acidic conditions since our investigated dyes display a lower solubility and instability in weakly basic condition. The fluorescence reached a maximum in pH range 1.8–3.6. The fluorescence intensities vary as follow: 125b > 125a > 125e or 125d > 125c, being relatively higher in pH range 2.5–4.5. At higher pH values the solubility of dyes was very low due to the ylide formation.

Some preliminary investigation used herring sperm DNA (hsDNA) or control plasmid pUC19 in order to establish the interaction of the dyes with DNA. The fluorescence quenching of 125a upon addition of hsDNA shows that the dye 125a interact with DNA. The fluorescence of 125a-DNA system was investigated at different dye (125a) concentration and quenching extent has a maximum value at 6 μM concentration of dye. Supplementary investigation on the interaction mechanism for binding of 125a to hsDNA showed a similarly interaction way of 125a and ethidium bromide with hsDNA, compound 125a being binded in the minor groove of DNA.

Since the solubility the compound 125a is poor, to increase its solubility and to extend its applications as cell staining agent or cell pH sensitive dye, we proposed the incorporation of compound 125a in β-cyclodextrin (β-CD) [76]. The reversible transformation of the pyridinium moiety in compound 125a to the corresponding nitrogen ylide 129a under proper pH condition (see Scheme 35), influence its fluorescence emission spectra, making it a pH sensible fluorescent dye.

The inclusion complex of indolizinyl-pyridinium salt in β-cyclodextrin (β-CD) was prepared by heating the equimolar amounts of components in water till 110 °C for 60 min, cooling down the solution under stirring for 6 h to reach the equilibrium followed by filtration through Phenex syringe filters (pore size: 0.45 μm).

The ESI-MS experiments and molecular docking studies confirmed the formation of an inclusion complex between indolizine derivative and β-cyclodextrin in 1:1 and 1:2 ratios. The cytotoxicity of the inclusion complex was considerably reduced comparing with the cytotoxicity of free indolizine on both HeLa (human cervix adenocarcinoma) and NHDF (normal human dermal fibroblasts) cells.

For the first time we demonstrated that the toxicity of a fluorescent dye was strongly reduced by the formation of cyclodextrin inclusion complex, allowing the successful application in cell staining. The study regarding cell membrane permeability showed that the nontoxic inclusion complexes mixture specifically accumulates in cell acidic organelles since could not pass through the cell plasma membrane.

Recent, ref. [77] we prepared three new cyclodextrin encapsulated pH sensitive dyes and investigated their ability for self-aggregation and in vitro assessments as fluorescent cellular probes. The mono-indolizine mono-salts 130a–c (their structures are presented in Scheme 36) were synthesized in moderate yields in an adopted two step strategy based on our methodological background.

Due to poor solubility in water of the indolizinyl-pyridinium salts 130a–c, these compounds were tested for the formation of inclusion complexes with β-CD. We started with an equivalent of each compound suspended in water, followed by the addition of an excess of β-CD (5 eq.) and heating to 90 °C until the reaction solution became transparent (after 25 min of heating). In case of 130c_CD the solutions remaining completely transparent after cooling down, while in case of 130a_CD and 130b_CD the formation of slightly cloudy solutions was observed. The excess up to 10 equivalents of the CD amount in the reaction mixture still did not change the appearance for the 130a_CD and 130b_CD at room temperature. These solutions were used in the subsequent analyses only after a microfiltration procedure.

The ESI-MS experiments and molecular docking studies confirmed a 1:1 and 1:2 ratios between indolizine derivative and β-cyclodextrin in the inclusion complex.

Absorption and emission spectra of indolizine derivatives 130a–c and their inclusion complexes 130a–c_CD were recorded at 1.0, 7.4, and 13.0 pH values. (1.0, 7.4, and 13.0) and the results compared. The indolizines 130a and 130b have similar absorption spectra, but slightly different than the absorption spectra of the indolizine 130c. At pH = 13.0, all the investigated indolizines have shown similar spectra. In the case of inclusion complexes 130a–c_CD, their absorption spectra at acidic and neutral pH values (1.0 and 7.4, respectively) are similar for all the investigated complexes, but different compared to the absorption spectra of the starting indolizines 130a–c. At basic pH values (pH = 13.0), the shape of the spectra of all complexes 130a–c_CD is drastically changed in comparison to each other and to the starting indolizines 130a–c.

The excitation wavelength was 420 nm when fluorescence spectra of 130a–c and 130a–c_CD were measured at different pH values. Starting indolizines 130a–c exhibited similar emission spectra at acidic and neutral pH values, with an emission band around 550 nm. This band is approximately two times higher in intensity at acidic than neutral pH value. At basic pH values (pH = 13.0), the indolizines shown low to no fluorescence. The reversible transformation of pyridinium salts into analogous non-fluorescent ylides may explain this pH-dependent behaviour. The inclusion complexes 130a–c_CD demonstrated slightly different pH dependent behaviours, showing a similar low intensity at basic pH values, but different intensities at acidic pH values. The fluorescence intensities of the inclusion complexes 130a_CD and 130b_CD at acidic pH are only slightly higher than intensities at neutral pH values, while in the case of the inclusion complex 130c_CD, the fluorescence intensities at both the acidic and neutral pH were comparable. The formation of the inclusion complexes altered the planar structure of the indolizinyl-pyridinium salt molecules due to the specific rotation limitations induced by the steric hindrances with the CD, which determine a decrease of fluorescence intensity of the inclusion complexes at acidic pH values.

Supplementary studies shown that the inclusion complexes have no cytotoxicity, they specifically accumulate within acidic organelles or mitochondria due to cellular permeability, and their intracellular fluorescence increase over a 24 hours period with outstanding signal stability.

3. Concluding Remarks

In conclusion, the present review article deals with design, synthesis, and photophysical properties of azaheterocycle-based materials. Several synthetic methodologies were used for the obtaining of fluorescent 5, 6 membered and fused azaheterocycles. The structure-fluorescence relationship of the obtained compound was investigated and allowed the authors to obtain compounds with better fluorescent properties in terms of emission wavelength, emission intensity and quantum yield.

The presented approaches regarding the synthesis of fluorescent azaheterocycles, using varied methodologies, enable researchers to create a library of multifunctional derivatives, possessing high efficiency of fluorescence.

The tunable emission properties of the azaheterocyclic compound make them valuable materials as potential luminophores in OLED devices, as luminescent solar concentrators or scintillators, as fluorometric (naked-eye chemosensor) molecular sensors for detection of metal ions, strong acids and bases with high selectivity, as thermally activated delayed fluorescence emitters and as fluorescent probe.