Autoxidation of n-alkylisoindolines

Recent Developments in Isoindole Chemistry

Isoindoles are highly reactive aromatic heterocycles that have a variety of important applications in areas such as medicine, analytical detection, and solar energy. Due to their highly reactive nature, isoindoles can be used to access their derivatives, which possess a diverse array of biological activities. However, their reactivity also makes isoindoles unstable and thus, difficult to prepare. Consequently, there has been a need for the development of novel methods that address some of the synthetic challenges and limitations, as well as reactions that utilize isoindoles to access potentially useful compounds. This review will give an overview of the novel reactions reported within the past decade (2012 to 2022) that involve 2H- and 1H-isoindoles and fused isoindoles as reactants, key intermediates, or products. This review is divided into two parts, with the first part focusing on the synthesis of isoindoles and the second part focusing on reactions of isoindoles. The scopes and limitations of the methods described therein will be discussed and the significance of their contributions to the literature will be highlighted. Similar reactions will also be compared.

1 Introduction

2 Synthesis of Isoindoles

2.1 Synthesis of 2H-Isoindoles

2.2 Synthesis of 1H-Isoindoles

3 Reactions of Isoindoles

3.1 Reactions of 2H-Isoindoles

3.2 Reactions of 1H-Isoindoles

4 Conclusions

Detection of bacterial sulfatase activity through liquid- and solid-phase colony-based assays

Bacterial arylsulfatases are crucial to biosynthesis in many microorganisms, as bacteria often utilize aryl sulfates as a source of sulfur. The bacterial sulfatases are associated with pathogenesis and are applied in many areas such as industry and agriculture. We developed an activity-based probe 1 for detection of bacterial sulfatase activity through liquid- and solid-phase colony-based assays. Probe 1 is hydrolyzed by sulfatase to generate fluorescent N-methyl isoindole, which is polymerized to form colored precipitates. These fluorescent and colorimetric properties of probe 1 induced upon treatment of sulfatases were successfully utilized for liquid-phase sulfatase activity assays for colonies and lysates of Klebsiella aerogenes, Mycobacterium avium and Mycobacterium smegmatis. In addition, probe 1 allowed solid-phase colony-based assays of K. aerogenes through the formation of insoluble colored precipitates, thus enabling accurate staining of target colonies under heterogeneous conditions.

Aspects of the stability of isoindoles derived from the reaction of o-phthalaldehyde—ethanethiol with primary amino compounds

The stability of a series of fluorescent isoindoles formed under analytical conditions following the reaction of o-phthalaldehyde (OPA) and ethanethiol (ET) with a series of primary amines is reported. Increasing the bulk and degree of substitution of the isoindole N-substituent resulted in substantial increases in isoindole stability. The effects of excess reagents on isoindole stability is examined and OPA is observed to accelerate isoindole degradation whilst ET provides a stabilizing effect. Comparison with previously reported data involving the use of 2-mercaptoethanol revealed that ET clearly forms the more stable isoindole derivatives, i.e. a minimum of five-fold improved stability based on the time for 10% degradation to occur. Identification of the major degradation product together with kinetic data suggests that degradation proceeds via autoxidation.

Rational design and evaluation of improved o-phthalaldehyde-like fluorogenic reagents

Evidence was presented suggesting that the fluorescent isoindole produced by reaction of o-phthalaldehyde (OPA), ethanethiol, and primary amine was formed by initial imine formation followed by conversion to an alpha-alkylaminobenzylsulfide and subsequent ring closure to form the isoindole nucleus. This mechanism suggested that the minimum structural requirement for condensation to an isoindole was an o-diacyl benzene in which one of the carbonyl groups was aldehydic. A major drawback of OPA as an analytical reagent is the limited stability of the fluorescent 1,2-disubstituted isoindole. Since isoindole instability is related to autoxidation at C-3, the use of o-(formyl) arylketones as alternatives to OPA is attractive in increasing the lifetime of the fluorescent species in that such reagents would form 1,2,3-trisubstituted isoindoles. Two compounds, o-acetylbenzaldehyde (OAB) and o-benzoylbenzaldehyde (OBB), were synthesized and evaluated as potential fluorogenic reagents. Both formed fluorescent products. The rate of formation of isoindole from the latter was too slow to make it of practical analytical value; however, OAB formed isoindoles with t1/2 less than 10 s and offered markedly improved stability over that observed with OPA.