Various bioreactor systems such asr

Various bioreactor systems such as
recipient with automatized temporary immersion (RITA), bubble
column bioreactor (BCB), and balloon type bubble bioreactor (BTBB)
have been developed for plant micropropagation (Takayama 1991;
http://dx.doi.org/10.1016/j.scienta.2015.06.014
0304-4238/© 2015 Elsevier B.V. All rights reserved.
370 Md.Z. Rahman et al. / Scientia Horticulturae 192 (2015) 369–374
Alvard et al., 1993; Shohael and Paek, 2013). They offer several benefits including better control of culture conditions, optimal supply
of nutrients and growth regulators, renewal of culture atmosphere,
changing of the medium during the culture period according to
developmental stage, filtration of the medium for exudates, contamination control and production of clusters of buds or somatic
embryos (Ziv, 2005).
Several studies have reported the potential of different bioreactor systems for the mass propagation of potato microtubers
(Donnelly et al., 2003). Liquid cultures together with various
temporary immersion techniques, ebb and flood, Rita
TM
system,
twin-flask system, plastic bag cultivations as well as tilting rocker
system have also been evaluated for the production of potato
microtubers (Estrada et al., 1986; Akita and Takayama, 1994;
Teisson and Alvard, 1999; Jimenez et al., 1999; Grigoriadou and
Leventakis, 2003; Piao et al., 2003; Kämäräinen-Karppinen et al.,
2010). Most of these techniques, however, involve the periodical immersion of plant propagules in liquid media. However,
Weathers and Giles (1988)suggested that a different bioreactor
system, wherein plant materials were cultured in nutrient mist created by ultrasonic transducers, might be more effective for plant
micropropagation. They cultured various plants in nutrient mist
bioreactor systems and reported improved growth (Hao et al.,
1998). As plant propagules were directly exposed to the nutrient
mist, composed of medium micro-particles and gas, both nutrient
absorption and gas exchange of the plant tissue improved, resulting in enhanced plant growth (Hao et al., 1998). Although nutrient
mist bioreactors are mainly used for hairy root cultures, other plant
propagules may also be cultured in such systems (Weathers et al.,
2008).Hao et al. (1998)andKurata et al. (1991)reported improved
shoot growth and microtuberization of potato in a nutrient mist
bioreactor. A nutrient spray bioreactor (NSB) functions on a principle similar to that of a nutrient mist bioreactor, except that in the
former the liquid medium is sprayed over the plant materials by a
spray nozzle rather than by ultrasonic transducers.
In recent years, the farming of crops particularly seed-potato
development through tissue culture has silently revolutionized
in agricultural sector of Bangladesh and also in the world. Quality seeds of different crops including potato are produced in
commercial laboratories in Bangladesh using conventional micropropagation techniques such as semi-solid and liquid cultures.
These laboratories have standardized suitable protocols of their
own with the standard potato cultivars of the country by incorporating different factors like culture media, light, temperature,
explants, etc for maximizing microtuber production (Hossain,
2005; Hoque, 2010). However, little work has been done on microtuberization in bioreactor systems. In this study a nutrient spray
bioreactor (NSB) was developed at the laboratory scale and its
potential for application in potato micropropagation was evaluated.
The aim of this study was to develop and optimize a suitable system for potato shoot growth and microtuberization by
investigating the effect of different nutrient spray intervals, BAP
concentrations and inoculation densities on various aspects of
microtuber production. It also aimed to compare microtuber productivity of the NSB systemwith conventional semi-solid and liquid
culture systems.