Recently, it was revealed that oils

Recently, it was revealed that oilseed meal as by-product from
the biodiesel industry could be successfully utilised for the production
of PHAs. Studies applying fed-batch fermentations of
C. necator DSM 545 using rapeseed meal hydrolyzates as nutrient
supplement have demonstrated that the bacteria was capable to
synthesize up to 55.6% of P(3HB-co-3HV) (García et al., 2013). The
same results have been reported by Kachrimanidou et al. (2013)
with the same strain when the fermentation medium was supplemented
with hydrolyzates from sunflower meal.
Various members of the grass family have been tested for bioplastic
production. Koutinas et al. (2007) and Xu et al. (2010) have
examined the potential of a wheat-based biorefinery for the production
of PHA. In the first report, Koutinas and co-workers showed
that hydrolyzed wheat mixed with fungal extract could produce up
to 51.1 g/L PHB. Xu et al. (2010), reported that Cupriavidus necator
growing on wheat-derived media produced 162.8 g/L PHB. Grass
biomass has also been tested as a substrate for mcl-PHA production.
Cerrone et al. (2014) have found that P. putida contains 39% of CDW
when cultivated on volatile fatty acids derived from aerobically
digested ensiled grass. These PHAs were composed mainly of 3-
hydroxydecanoic acid.
Recently, Jerusalem artichoke (Helianthus tuberosus) has been
proposed as a feedstock for PHB production. Koutinas et al. (2013)
hydrolyzed Jerusalem artichoke tubers to fructose, glucose, amino
acids and peptides. This hydrolyzate was then tested as a substrate
for PHB production in shake flask fermentation, resulting in an
intracellular biopolymer content of up to 4 g/L. According to the
authors, it is possible to use hydrolyzed Jerusalem artichoke, but
the fermentation medium must be enriched with nutrient-rich
supplements.