USE OF SENSORY EVALUATION FOR MEASURING DEODORIZING EFFECTS OF AN AIR CONDITIONER

The application of sensory methodology for measuring deodorizing effect of an air conditioner equipped with electric plasma was introduced. Deodorizing effect was measured using chemical and sensory methods at different time (0, 30 and 60 min) and mode (control, blowing and cooling) of an air conditioner. Smoke from a roll of cigarette in a closed room was used as a source of odor and the concentrations of acetic acid and ammonia were measured as odorous chemical components. As one of the sensory methods triangle test was used and as a first step to obtain deodorizing effects by triangle test, the threshold of each panelist was obtained as the log dilution ratio of odor concentration at which the difference from odorless air was detected. The odor concentration at each time and mode was calculated using the threshold of the panel and the deodorizing effect was obtained on the basis of the odor concentration. In addition to a triangle test, scaling methods such as category scaling or magnitude estimation were used to measure deodorizing effect of an air conditioner. Deodorizing effects by scaling methods were calculated based on odor intensity with time at each mode. The regression analysis was done between the efficacy of deodorizing effect by sensory test and those by acetic acid and ammonia, the R² values of the regression equations for triangle test, category scale, and magnitude estimation were 0.84, 0.72 and 0.69, respectively. Deodorizing effect by triangle test explained the decrease of acetic acid and ammonia better than those by category scaling or magnitude estimation while high cost and time consuming labor involved in triangle tests reduced the merit. The results of this study demonstrated that various sensory methods could be used to measure deodorizing effect of air conditioners and further researches on fast and reliable methods are needed to establish the official procedures.     

Synthesis of elastin in aortas from chick embryos. Conversion of newly secreted elastin to cross-linked elastin without apparent proteolysis of the molecule

The biosynthesis of elastin was examined in matrix-free cells isolated by enzymic digestion of aortas from 17-day old chick embryos. After the cells were incubated with [14C]proline and then were rapidly boiled in buffer containing high concentrations of protease inhibitors and sodiumdodecyl sulfate, about one-quarter of the intracellular 14C-labeled protein was recovered as an elastin component with an apparent molecular weight of about 72 000. Examination of the medium from the cell suspension indicated that the largest elastin component secreted by the cells also had an apparent molecular weight of about 72 000. Pulse-chase experiments with intact aortas demonstrated that about two-thirds of the 72 000-dalton component disappeared in 2 h, apparently because it was converted to cross-linked fibers. When cross-linking was inhibited with penicillamine, the 72 000-dalton component persisted in the tissue 5 h. When cross-linking was inhibited with beta-aminopropionitrile, the elastin component of 72 000 daltons persisted for about 2 h, but thereafter it was gradually degraded to small peptides which were recovered in the incubation medium. The results suggest that elastin is secreted by cells in chick aorta as a polypeptide of about 72 000 daltons and that the secreted protein is incorporated into elastin fibers without cleavage to a protein of considerably smaller size.     

Assay of adenosine 3', 5' cyclic monophosphate by stimulation of protein kinase: a method not involving radioactivity

In order to meet a need for a cAMP assay which is not subject to interference by compounds in plant extracts, and which is suitable for use on occasions separated by many ³²P half-lives, an assay based on cAMP-dependent protein kinase has been developed which does not require the use of [γ-³²P]ATP. Instead of measuring the cAMP-stimulated increase in the rate of transfer of [γ-³²P] phosphate from [γ-³²P]ATP to protein, the rate of loss of ATP from the reaction mixture is determined. The ATP remaining after the protein kinase reaction is assayed by ATP-dependent chemiluminescence of the firefly luciferin-luciferase system. Under conditions of the protein kinase reaction in which a readily measurable decrease in ATP concentration occurs, the logarithm of the concentration of ATP decreases in proportion to the cAMP concentration, i.e., the reaction can be described by the equation: [ATP] = [ATP]₀ e^?[cAMP]kt. The assay based on this relationship can detect less than 1 pmol of cAMP. The levels of cAMP found with this assay after partial purification of the cAMP from rat tissue, algal cells, and the media in which the cells were grown agreed with measurements made by the cAMP binding-competition assay of Gilman, and the protein kinase stimulation assay based on transfer of [³²P] phosphate from [γ-³²P]ATP to protein. All of the enzymes and chemicals required for the assay of cAMP by protein kinase catalyzed loss of ATP can be stored frozen for months, making the assay suitable for occasional use.     

Light-dependent Emission of Hydrogen Sulfide from Plants

With the aid of a sulfur-specific flame photometric detector, an emission of volatile sulfur was detected from leaves of cucumber (Cucumis sativus L.), squash and pumpkin (Cucurbita pepo L.), cantaloupe (Cucumis melo L.), corn (Zea mays L.), soybean (Glycine max [L.] Merr.) and cotton (Gossypium hirsutum L.). The emission was studied in detail in squash and pumpkin. It occurred following treatment of the roots of plants with sulfate and was markedly higher from either detached leaves treated via the cut petiole, or whole plants treated via mechanically injured roots. Bisulfite elicited higher rates of emission than sulfate. The emission was completely light-dependent and increased with light intensity. The rate of emission rose to a maximum and then declined steadily toward zero in the course of a few hours. However, emission resumed after reinjury of roots, an increase in light intensity, an increase in sulfur anion concentration, or a dark period of several hours.

The emission was identified as H₂S by the following criteria: it had the odor of H₂S; it was not trapped by distilled H₂O, but was trapped by acidic CdCl₂ resulting in the formation of a yellow precipitate, CdS; it was also trapped by base and the contents of the trap formed methylene blue when reacted with N,N-dimethyl-p-phenylenediamine and Fe³⁺.

H₂S emission is not the cause of leaf injury by SO₂, since bisulfite produced SO₂ injury symptoms in dim light when H₂S emission was low, while sulfate did not produce injury symptoms in bright light when H₂S emission was high.

The maximum rates of emission observed, about 8 nmol min⁻¹ g fresh weight⁻¹, are about the activity that would be expected for the sulfur assimilation pathway of a normal leaf. H₂S emission may be a means by which the plant can rid itself of excess inorganic sulfur when HS⁻ acceptors are not available in sufficient quantity.

     

Estimation of growth yield and maintenance coefficient of plant cell suspensions

Methodology is presented for the determination of growth yield (Y(g)) and maintenance coefficient (m) for carbon utilization of plant cells grown in suspension culture. Estimation of Y(g) and m requires measurements of specific growth rate (micro) and specific rate of substrate uptake (q) at different growth limiting substrate concentrations. Batch culture of tobacco cells did not permit evaluation of Y(g) and m because micro is constant and maximal during most of the growth cycle. In batch culture, the period of declining specific growth rate is extremely brief because of the rapid transition from logarithmic growth to stationary phase. This occurs because the K(m) for growth is relatively small compared to the initial sucrose concentration. Thus, when the substrate level reaches the K(m), the large mass of cells rapidly depletes the remaining substrate. In contrast, semicontinuous culture facilitates the determination of Y(g) and m because various steady-state growth rates can be achieved. Mathematical expressions were developed to determine the effective values of micro and q over the semicontinuous replacement interval. The validity of this approach was verified by conducting simulations using experimentally determined parameters.     

Cell growth and water relations of the halophyte,Atriplex nummularia L., in response to NaCl

Summary Growth reduction or cessation is an initial response of Atriplex nummularia L. cells to NaCl. However, A. nummularia L. cells that are adapted to 342 and 428 mM NaCl are capable of sustained growth in the presence of salt. Cells that are adapted to NaCl exhibit a reduced rate of division compared to unadapted cells. Unlike salt adapted cells of the glycophyte Nicotiana tabacum L., A. nummularia L. cells do not exhibit reduced rate of cell expansion after adaptation. However, the cell expansion rate of unadapted A. nummularia L. cells is considerably slower than that of unadapted glycophyte cells and this normally low rate of cell expansion may contribute to the enhanced capacity of the halophyte to tolerate salt. Turgor of NaCl adapted cells was equivalent to unadapted cells indicating that the cells of the halophyte do not respond to salt by osmotic over adjustment as reported for the glycophyte tobacco (Binzel et al. 1985, Plant Physiol. 79:118–125).