Establishment and Application of a Method for the Determination of Ganoderic Acid A

A method for the quantitative determination of ganoderic acid A was constructed using the principle of indirect competitive enzyme-linked immunosorbent assay (ELISA), and this method was used to determine the ganoderic A contents of Ganoderma lucidum samples in the market. The conjugate of ganoderic acid A and bovine serum albumin was used for four rounds of immunization on test rabbits to obtain rabbit antiganoderic acid A antibody IgG. The enzyme-labeled plate was coated with the conjugate of ganoderic acid A and ovalbumin. The first stage reaction in the indirect competitive ELISA was that the conjugate of ganoderic acid A in the sample competed with the conjugate coated on the enzyme-labeled plate to bind rabbit antibodies. The second stage reaction was the combination of goat anti-rabbit IgG–horseradish peroxidase and rabbit antiganoderic acid A antibody IgG. The results of the determination of ganoderic acid A standard by this method showed that the coefficient of variation of repeated wells in the group was <5%, the detection limit of ganoderic acid A was 0.6 μg/L, and ganoderic acid A had a substantial dose-response relationship in the content range of 0.9–72.9 μg/L (R2 = 0.994). This method was used to measure the ganoderic A content of 12 varieties of G. lucidum in the market and showed the obvious differences in the ganoderic acid A contents of the different varieties. This method is simple, fast, and of great importance to the quality control of Ganoderma products.

ELISA for the Detection of the Prohibited Doping Agent Higenamine

Higenamine is a natural benzyltetrahydroisoquinoline alkaloid produced by various plants. In the World Anti-Doping Agency report of 2020, higenamine is classified as a class S3 (selective and nonselective β2-agonist) prohibited substance. To minimize the problems resulting from the misuse of higenamine-containing products as well as from the abuse of doping agents in sport, numerous higenamine-detection methods have been investigated. In the present study, a monoclonal antibody against the (S)-enantiomer of higenamine was successfully produced and applied in the indirect competitive ELISA to detect the content of (S)-higenamine in plant samples and related products. By immunizing BALB/c mice with higenamine-BSA, the aforementioned monoclonal antibody was produced even when the hapten number, which was the higenamine molecules conjugated to the BSA molecule, was relatively low (approximately 4). The MAb was characterized and utilized in the established icELISA assay with a detectable range of 7.81 – 125 ng/mL. The assay limit of detection (LOD) was 4.41 ng/mL, indicating higher sensitivity than the conventional HPLC-UV methods. Various validation processes demonstrated that icELISA was precise, with the maximum CV (%) of the intra- and inter-assays of 11.58% and 10.18%, respectively. Moreover, the assay was accurate, with the recovery rates of spiked (S)-higenamine ranging from 82% to 113%, and sufficiently reliable for the detection of (S)-higenamine in various kinds of samples. Notably, the present study describes the first immunoassay for (S)-higenamine.

Development of Indirect Competitive ELISA for Lithospermic Acid B of Salvia miltiorrhiza with Its Specific Antibodies Generated via Artificial Oil Bodies

Lithospermic acid B (LSB), the major water-soluble ingredient of Salvia miltiorrhiza (Danshen), has been shown to be an active ingredient responsible for the therapeutic effects of this traditional Chinese herb used to treat cardiac disorders. This study aimed to develop an indirect competitive enzyme linked immunosorbent assay (ELISA) for the detection of LSB. Firstly, LSB was chemically conjugated to a modified oil-body protein, lysine-enriched caleosin, recombinantly expressed in Escherichia coli. Antibodies against LSB (Ab-LSB) were successfully generated by immunizing hens with artificial oil bodies constituted with the LSB-conjugated caleosin. Western blotting showed that Ab-LSB specifically recognized LSB, but not the carrier protein, lysine-enriched caleosin. To detect LSB via indirect competitive ELISA, LSB was conjugated with bovine serum albumin (LSB-BSA) and coated on a microplate. The binding between Ab-LSB and LSB-BSA on the microplate was competed dose-dependently in the presence of free LSB with a concentration ranging from 5 to 5 × 104 ng/mL. The IC50 value was approximately determined to be 120 ng/mL for LSB regardless of its complex with a metal ion of Na+, K+ or Mg2+.