Mold infestation of wet spray-applied cellulose insulation

Mold investigations were conducted in four buildings that had been insulated with wet spray-applied cellulose insulation (WSACI). Bulk WSACI samples were collected and analyzed by quantitative polymerase chain reaction (QPCR) methods. Airborne mold was evaluated using both Burkard total mold spore and Andersen culturable/viable sampling methods. Although reportedly treated with biocidal borates, QPCR analyses indicated that elevated concentrations of mold cells (reported as spore equivalents per gram) may be present in WSACI. QPCR analyses showed the following: (1) very high concentrations of Penicillium chrysogenum in samples from two of four buildings; (2) very high concentrations of Stachybotrys chartarum in samples from one building and a more moderate presence in a second; (3) moderately high concentrations of Aspergillus versicolor in samples from one building and more moderate concentrations in a second; (4) the presence of the opportunistic pathogen, Aspergillus fumigatus, in samples from three of the four buildings, and (5) the presence of 22 of 23 target mold species. Elevated airborne total mold spore concentrations were observed in all four of the buildings investigated. Culturable/viable airborne mold concentrations were moderately elevated in three of the four buildings. Mold genera/types present were relatively consistent among airborne mold samples collected by both methods and bulk sample analyses. Results of this study suggest that WSACI has the potential to cause elevated airborne mold levels in buildings where it has been applied and pose significant mold exposure and public health risks.     

Formaldehyde source interaction studies under whole-house conditions

This study was designed to determine the effect of source combinations on formaldehyde levels under whole-house conditions. Evaluations were conducted on particleboard (applied as subflooring) and hardwood plywood panelling (applied as a wall covering) both singly and in combination, and on urea-formaldehyde foam insulation and particleboard. Formaldehyde source combination/interaction evaluations revealed several different outcomes, including no augmentation of formaldehyde levels, a slight augmentation (30-50%) and complete addivity. Additivity was observed for regular and low emission grade particleboard and hardwood plywood combinations and for urea-formaldehyde foam insulation and particleboard subflooring. In contrast, controlled chamber studies employing samples of the same wood materials revealed no additive effects. Results of these studies raise questions about the reliability of using laboratory evaluations alone to predict formaldehyde levels under real-world residential conditions.     

An assessment of botanical air purification as a formaldehyde mitigation measure under dynamic laboratory chamber conditions

This study was designed to determine the effectiveness of spider plants (Clorophytum elatum var. vittatium) as a botanical air purification measure for formaldehyde under dynamic laboratory chamber conditions. Significant reductions in chamber formaldehyde levels were observed when spider plants were placed in experimental chambers. However, highest reductions occurred when spider plants were defoliated. Observed reductions in formaldehyde levels appeared to have been associated with soil medium factors and a source moisture storage phenomenon associated with the use of particleboard as a formaldehyde source inside the chambers. The results of this study do not support the conclusions of previous studies which suggest that botanical air purification using only plant leaves is an effective means of reducing residential formaldehyde levels.