用于生产油菜（Brassica rapa L.）微型蔬菜的替代生长介质的物理化学、农艺学和微生物学评价。

Physicochemical, agronomical and microbiological evaluation of alternative growing media for the production of rapini (Brassica rapa L.) microgreens.

作者信息

Di Gioia Francesco, De Bellis Palmira, Mininni Carlo, Santamaria Pietro, Serio Francesco

机构信息

Department of Agricultural and Environmental Science, University of Bari Aldo Moro, via Amendola 165/A, 70126 Bari, Italy.

University of Florida, Institute of Food and Agricultural Sciences, South West Florida Research and Education Center, Immokalee, FL 34142, USA.

出版信息

J Sci Food Agric. 2017 Mar;97(4):1212-1219. doi: 10.1002/jsfa.7852. Epub 2016 Jul 11.

DOI:10.1002/jsfa.7852

PMID:27311947

Abstract

BACKGROUND

Peat-based mixes and synthetic mats are the main substrates used for microgreens production. However, both are expensive and non-renewable. Recycled fibrous materials may represent low-cost and renewable alternative substrates. Recycled textile-fiber (TF; polyester, cotton and polyurethane traces) and jute-kenaf-fiber (JKF; 85% jute, 15% kenaf-fibers) mats were characterized and compared with peat and Sure to Grow® (Sure to Grow, Beachwood, OH, USA; http://suretogrow.com) (STG; 100% polyethylene-terephthalate) for the production of rapini (Brassica rapa L.; Broccoletto group) microgreens.

RESULTS

All substrates had suitable physicochemical properties for the production of microgreens. On average, microgreens fresh yield was 1502 g m in peat, TF and JKF, and was 13.1% lower with STG. Peat-grown microgreen shoots had a higher concentration of K and SO and a two-fold higher NO concentration [1959 versus 940 mg kg fresh weight (FW)] than those grown on STG, TF and JKF. At harvest, substrates did not influence microgreens aerobic bacterial populations (log 6.48 CFU g FW). Peat- and JKF-grown microgreens had higher yeast-mould counts than TF- and STG microgreens (log 2.64 versus 1.80 CFU g FW). Peat-grown microgreens had the highest population of Enterobacteriaceae (log 5.46 ± 0.82 CFU g ) and Escherichia coli (log 1.46 ± 0.15 CFU g ). Escherichia coli was not detected in microgreens grown on other media.

CONCLUSION

摘要

背景

泥炭基混合料和合成垫是用于微型蔬菜生产的主要基质。然而，两者都价格昂贵且不可再生。回收纤维材料可能是低成本且可再生的替代基质。对回收纺织纤维（TF；聚酯、棉花和聚氨酯痕迹）和黄麻-红麻纤维（JKF；85%黄麻，15%红麻纤维）垫进行了表征，并与泥炭和Sure to Grow®（Sure to Grow，美国俄亥俄州比奇伍德；http://suretogrow.com）（STG；100%聚对苯二甲酸乙二酯）进行比较，用于生产油菜（Brassica rapa L.；Broccoletto组）微型蔬菜。

结果

所有基质都具有适合微型蔬菜生产的理化性质。平均而言，泥炭、TF和JKF中微型蔬菜的鲜产量为1502 g/m²，而STG的鲜产量低13.1%。泥炭种植的微型蔬菜芽中K和SO的浓度较高，NO浓度[1959对940 mg/kg鲜重（FW）]比在STG、TF和JKF上种植的高出两倍。收获时，基质对微型蔬菜的需氧细菌种群没有影响（log 6.48 CFU/g FW）。泥炭和JKF种植的微型蔬菜的酵母-霉菌计数高于TF和STG种植的微型蔬菜（log 2.64对1.80 CFU/g FW）。泥炭种植的微型蔬菜中肠杆菌科（log 5.46±0.82 CFU/g）和大肠杆菌（log 1.46±0.15 CFU/g）的数量最多。在其他培养基上种植的微型蔬菜中未检测到大肠杆菌。

结论

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用于生产油菜（Brassica rapa L.）微型蔬菜的替代生长介质的物理化学、农艺学和微生物学评价。

Physicochemical, agronomical and microbiological evaluation of alternative growing media for the production of rapini (Brassica rapa L.) microgreens.

作者信息

机构信息

出版信息

BACKGROUND

RESULTS

CONCLUSION

背景

结果

结论

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