Raymond Nelly Sophie, Müller Stöver Dorette, Jensen Lars Stoumann, Håkansson Sebastian
Plant and Soil Science Section, Department of Plant and Environmental Sciences, Faculty of Science, University of Copenhagen, Thorvaldsensvej 40, DK-1871 Frederiksberg C, Denmark.
Plant and Soil Science Section, Department of Plant and Environmental Sciences, Faculty of Science, University of Copenhagen, Thorvaldsensvej 40, DK-1871 Frederiksberg C, Denmark.
J Microbiol Methods. 2018 Jul;150:39-46. doi: 10.1016/j.mimet.2018.05.012. Epub 2018 May 17.
The impact of formulation and desiccation on the shelf life of phosphate (P)-solubilising microorganisms is often under-studied, particularly relating to their ability to recover P-solubilisation activity. Here, Penicilllium bilaiae and Aspergillus niger were formulated on vermiculite (V) alone, or with the addition of protectants (skimmed milk (V + SM) and trehalose (V + T)), and on sewage sludge ash with (A + N) and without nutrients (A), and dried in a convective air dryer. After drying, the spore viability of P. bilaiae was greater than that of A. niger. V formulations achieved the highest survival rates without being improved by the addition of protectants. P. bilaiae formulated on V was selected for desiccation in a fluidised bed dryer, in which several temperatures and final water activities (aw) were tested. The highest spore viability was achieved when the formulation was dried at 25 °C to a final aw >0.3. During three months' storage, convective air dried formulations were stable for both strains, except in the presence of skimmed milk for P. bilaiae which saw a decrease in spore viability. In the fluidised bed-dried formulations, when aw >0.3, the loss in viability was higher, especially when stored at 20 °C, than at aw <0.1. P-solubilisation activity performed on ash was preserved in most of the formulations after desiccation and storage. Overall, a low drying temperature and high final aw positively affected P. bilaiae viability, however a trade-off between higher viability after desiccation and shelf life should be considered. Further research is needed to optimise viability over time and on more sustainable carriers.
制剂配方和干燥对解磷微生物保质期的影响常常未得到充分研究,特别是与其恢复解磷活性的能力相关的方面。在此,分别将两色青霉和黑曲霉单独制剂于蛭石(V)上,或添加保护剂(脱脂牛奶(V + SM)和海藻糖(V + T))后制剂于蛭石上,以及制剂于添加养分(A + N)和未添加养分(A)的污水污泥灰上,并在对流空气干燥器中干燥。干燥后,两色青霉的孢子活力高于黑曲霉。V制剂配方在不添加保护剂的情况下实现了最高存活率。选择V制剂配方的两色青霉在流化床干燥器中进行干燥,测试了几个温度和最终水分活度(aw)。当制剂在25°C下干燥至最终aw>0.3时,可实现最高孢子活力。在三个月的储存期内,对流空气干燥的制剂配方对两种菌株均稳定,除了两色青霉在添加脱脂牛奶的情况下孢子活力有所下降。在流化床干燥的制剂配方中,当aw>0.3时,活力损失更高,尤其是在20°C下储存时,高于aw<0.1的情况。干燥和储存后,大多数制剂配方在灰分上的解磷活性得以保留。总体而言,较低的干燥温度和较高的最终aw对两色青霉的活力有积极影响,然而,应考虑在干燥后较高活力与保质期之间进行权衡。需要进一步研究以随时间优化活力,并研究更可持续的载体。
