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The In Vitro Effects of Pure and Street Methamphetamine on the proliferation and Cell Cycle of Mouse Brain Endothelial (bEnd5) cellsMafunda, Patrick Siyambulela January 2012 (has links)
<p><span style="font-size: 11.5pt">The blood-brain barrier (BBB) is an interface between the brain parenchyma and the circulating system. This barrier plays a vital role in protecting the CNS by restricting free paracellular diffusion of molecules from the systemic circulation. Methamphetamine (MA) is a highly addictive psychostimulant and has demonstrated neurotoxic properties as well as the ability to compromise the BBB. MA exposure is strongly linked with increased oxidative stress which can result in a decrease in the integrity of the BBB. </span></p>
<div><span style="font-size: 11.5pt">The aim of this study was to investigate <i>in vitro </i>effects of pure and street MA &ldquo / tik&rdquo / on DNA proliferation and cell cycles in mouse brain endothelial (bEnd5) cells. </span></div>
<div><span style="font-size: 11.5pt">Trypan blue was used to determine effects of MA (0.0001M-1mM) on cell viability and % cell growth. The Cell Titer Glo® / luminescent assay and nonradioactive analogue, 5-bromo-2'-deoxyuridine (BrdU) was used to detect ATP and DNA levels, respectively. Cell cycles (propidium iodide incorporation) were analysed using flow cytometry. Statistical analysis was performed using Wilcoxin Rank Sum Test in which P< / 0.05 was denoted as significant. </span></div>
<div><span style="font-size: 11.5pt">Results of this study showed that: </span></div>
<div><span style="font-size: 11.5pt">1. Viability of bEnd5 cells exposed to all selected concentrations of MA were unaffected when compared to controls (P> / 0.05)  / </span><span style="font-size: 11.5pt">  / </span></div>
<div><span style="color: windowtext / font-size: 11.5pt">2. % Cell growth was suppressed by MA exposure at 96hrs in comparison to that of controls (P&le / 0.03). </span></div>
<div style="margin: 0cm 0cm 25pt"><span style="color: windowtext / font-size: 11.5pt">3. Cells exposed to MA had significant higher ATP concentrations than control cells at 96hrs (P &le / .0.03) </span><span style="color: windowtext / font-size: 11.5pt">4. DNA synthesis was markedly suppressed in cells exposed to pure MA and street MA sample 4 (P&le / 0.03), while was similar and higher in cells exposed to street MA sample 1 (P=0.39), and street MA sample 2 and 3 (P&le / 0.04), respectively at 96hrs. </span><span style="color: windowtext / font-size: 11.5pt">5. bEnd5 cell were arrested between 72 and 96hrs at the G1-S phase.  / </span></div>
<div style="margin: 0cm 0cm 25pt"><span style="line-height: 115% / font-size: 11.5pt">In conclusion, this study demonstrated pure and illicit samples of MA obtained from forensic police did not affect the viability of bEnd5 cells, however resulted in the significant suppression of their cell numbers. This growth inhibition may be due to MA-induced cell cycle arrest at the G1-S phase. The study also showed that compounds found in the samples of street MA produced results significantly different to that of pure MA.</span></div>
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Some implications of associated mycoflora during hydrated storage of recalcitrant seeds of Avicennia marina (Forssk.) Vierh.Calistru, Claudia. January 2004 (has links)
Three questions are considered in the context of the possible effects of seedassociated
mycoflora, typified by Fusarium moniliforme, during hydrated
storage of recalcitrant seeds of the tropical species, Avicennia marina. These
are: 1) whether fungal infection reduces storage lifespan; 2) whether seeds
become more susceptible to fungal attack during storage and whether they
posses defence mechanisms that might suppress fungal proliferation in
hydrated storage (production of antifungal compounds and 13-1,3-glucanase
(EC 3.2.1.39) and chitinase (EC 3.2.1.14)] and 3) whether it is possible to
discriminate ultrastructurally between inherent deteriorative changes and
those that are fungally-induced.
1) The data indicate unequivocally that if fungal activity is curtailed, then the
hydrated storage lifespan of A. marina seeds can be considerably extended.
2) When inoculated immediately with F. moniliforme, newly harvested seeds
were extremely susceptible to the adverse effects of the fungus, while seeds
that had been wet-stored for 4 days showed a considerably heightened
resilience to the effects of the fungus prior to inoculation. The enhanced
resilience, although declining, persisted in seeds stored hydrated for up to 10
days prior to inoculation, being lost after 12 days. This finding was supported
by significant increase in 13-1,3-glucanase and chitinase and in antifungal
compound production during 10 days of wet storage. After 14 days of wetstorage,
seeds become more susceptible to the effects of fungusthanthose in
the newly harvested condition.
3) The resilience of seeds that had been stored in the short-term was
associated with ultrastructural changes indicative of enhanced metabolic
activity associated with the onset of germination (e.g. increase in vacuolation,
well-developed mitochondria and endomembrane system [ER and Golgi
bodies]). However, with sustained stress associated with wet-storage
IV
conditions, the seeds became increasingly badly affected by the fungus,
showing some ultrastructural fungally-induced abnormalities (e.g. nuclear
lobing, presence of lipid bodies and prevalence of Golgi bodies that had many
associated vesicles) and a decrease in 13-1,3-glucanase and chitinase activity.
It is suggested that the decreased susceptibility of A. marina seeds during
short-term storage relies on the ability to create an antifungal environment
prior to infection (through synthesis and accumulation of pre-formed and
induced antifungal compounds and antifungal enzymes), which would also be
an effective strategy during germination in the natural environment. / Thesis (Ph.D.)-University of KwaZulu-Natal, Durban, 2004
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Investigations into the responses of axes of recalcitrant seeds to dehydration and cryopreservation.Wesley-Smith, James. January 2002 (has links)
Achieving long-term storage of germplasm is critical for the conservation of plant biodiversity. Seed storage practices require that degradative reactions causing ageing be limited. By reducing the water content, cytoplasmic viscosity is increased to levels that minimise deteriorative reactions. Reducing the storage temperature additionally increases the storage lifespan by further reducing the rate at which such deleterious processes occur. Two broad categories of seeds can be distinguished based on their storage behaviour. Orthodox seeds are desiccation-tolerant; generally shed in the dry state and are metabolically quiescent. Such seeds are usually stored at low water contents (e.g. 5%), and their high cytoplasmic viscosity prevents freezing damage during cooling to subzero temperatures. On the other hand, desiccation-sensitive (recalcitrant) seeds do not undergo a maturation-drying phase, they are metabolically active at shedding, and sensitive to extreme or prolonged drying. Accordingly, recalcitrant seeds cannot be stored under conventional conditions because they do not survive drying to low water contents and are damaged by sub-zero temperatures, even when dried to the lowest water content tolerated. Therefore, procedures that facilitate harmless drying and cooling to low temperatures are required to achieve long-term storage of recalcitrant germplasm. Recalcitrant seeds that are dried rapidly can attain relatively lower water contents without injury. However, these seeds are usually large and this limits the drying rates that can be achieved even under favourable conditions. Isolating embryonic axes from the rest of the seed facilitates faster drying, and a consequent reduction in the water content at which damage occurs. In axes of many species, the level of drying attained before lethal desiccation damage occurs is sufficient to limit freeZing damage during cryogenic exposure and facilitate survival in vitro. However, many others are damaged when dried to water contents that preclude freezing, and also are killed if cooled to sub-zero temperatures at higher water contents. In such instances, the window of permissible water contents leading to survival may be small or nonexistent. A basic premise explored in this thesis is that by restricting the growth of intracellular ice crystals using increasingly rapid cooling rates, the range of permissible water contents can be widened, facilitating survival of axes at higher water contents. An overview of the problems associated with the long-term storage of recalcitrant germplasm, and the rationale behind such rapid cooling approach are presented in Chapter 1 of the present thesis. Subsequent chapters report investigations on the effects of variables required to dry and cryopreserve embryonic axes with minimum damage, in keeping with this approach. Collectively, those studies aimed at establishing a robust cryopreservation procedure for the conservation of recalcitrant germplasm with broad applicability across species. The approach presently adopted entailed manipulating the water content of excised axes using rapid drying to discrete water content ranges, and also using different methods to cool axes to cryogenic temperatures at various rates. The calorimetric properties of water in axes were investigated for Camellia sinensis (L.) O. Kuntze using differential scanning calorimetry (DSC). For all species, the effect of any drying or cooling treatment tested was determined by assessing the survival of axes in vitro, which provided the most reliable indicator of cellular damage. Additionally, the effects of different treatments upon the structural and functional integrity of axes were assessed using light and electron microscopy as well as measurement of electrolyte leakage. The studies undertaken are presented in a similar sequence to that in which they took place during the course of the experimental phase of this work. These are summarised below. Partial drying plays a pivotal role in the approach developed, and microscopy has contributed towards increasing present understanding of desiccation damage. Microscopy was used to determine the effects of drying rate upon the ultrastructure of recalcitrant axes. It was necessary to find reliable protocols to prepare specimens for light and electron microscopy that did not alter the architecture of the cells in the dry state. Freeze-substitution and conventional aqueous fixation were compared in Chapter 2 using variously dried material from three species. The results obtained revealed that an unacceptably high extent of artefactual rehydration occurs during aqueous fixation, and highlight the need for anhydrous processing of dehydrated samples. Significantly, that study also revealed that many cellular events commonly associated with desiccation damage (e.g. withdrawal, tearing and/or vesiculation of the plasmalemma) are not seen in freeze-substituted preparations, and are likely artefacts of aqueous fixation. Freeze-substitution was used subsequently (Chapter 3) to assess the effects of slow drying (2 - 3 days) or rapid drying (min) upon the survival of embryonic axes of jackfruit (Artocarpus heterophyllus Lamk.) Results confirmed the beneficial effects of rapid drying, and also provided insights into ultrastructural changes and probable causes underlying cellular damage that occur during a drying/rehydration cycle. Efforts subsequently focused on determining the effect of cooling rate upon survival of recalcitrant axes at various water contents. The study on embryonic axes of recalcitrant camellia sinensis (tea; Chapter 4) tested the hypothesis that rapid cooling facilitates survival of axes at higher water content by restricting the growth of ice crystals to within harmless dimensions. The presence of sharp peaks in DSC melting thermograms was indicative of decreased survival in vitro. These peaks were attributed to the melting of ice crystals sufficiently large to be detected by DSC as well as to cause lethal damage to axes. Increasing the cooling rate from 10°C min-1 to that attained by forcibly plunging naked axes into sub-cooled nitrogen increased the upper limit of water content facilitating survival in vitro from c. 0.4 to 1.1 - 1.6 g H20 g-1 (dry mass [dmb]). Subsequent studies tested whether a similar trend occurred in other recalcitrant species cooled under similar conditions. In order to investigate further the relationship between water content, cooling rate and survival it was necessary to achieve cooling rates reproducibly, and to quantify these reliably. The plunging device required to achieve rapid cooling, and instruments required to measure the cooling rates attained, are described in Chapter 5. That study investigated the effects of cryogen type, depth of plunge and plunging velocity on the cooling rates measured by thermocouples either bare or within tissues of similar size and water content as encountered in cryopreservation experiments. This plunger was used in subsequent studies to achieve the fastest cooling conditions tested. Favourable cooling conditions were selected, and the efficacy of this procedure to cryopreserve relatively large axes was tested (Chapter 6) using embryonic axes of horse chestnut (Aesculus hippocastanum L.) Axes at water contents above c. 0.75 g g-1 could not be cooled faster than c. 60°C S-1, but cooling rates of axes below this water content increased markedly with isopentane, and to a lesser extent with subcooled nitrogen. Axes were killed when cooled at water contents above 1.0 g g-1 but survived fully (albeit abnormally) when cooled in isopentane between 1.0 and 0.75 g g-1. Complete survival and increasingly normal development was attained at water contents below 0.75 g g-1, especially if isopentane was used. The study on horse chestnut axes emphasised that water content and cooling rate are co-dependent during non-equilibrium cooling. Accordingly, that study could not determine whether survival at lower water contents increased because of the corresponding increase in cooling rates measured, or because of the higher cytoplasmic viscosity that resulted from drying. That uncertainty was addressed by the study discussed in Chapter 7, using axes of the trifoliate orange (Poncirus trifoliata [L.] RAF.) That study investigated the effect of cytoplasmic viscosity upon survival of axes cooled and warmed at different rates. Survival and normal development was high at lower water contents, and seemingly independent of cooling rate at about 0.26 g g-1. At higher water contents the range of cooling rates facilitating survival became narrower and displaced towards higher cooling rates. This study revealed two conspicuous inconsistencies that questioned the beneficial effect of rapid cooling. Firstly, the fastest cooling rates did not necessarily facilitate the highest survival. Secondly, survival of fully hydrated axes was higher when cooled under conditions that encouraged - rather than restricted - the growth of intracellular ice crystals. These inconsistencies were explored further using embryonic axes of silver maple (Acer saccharinum L.). Freeze-fracture replicas and freeze-substitution techniques provided valuable insights into the way in which ice crystals were distributed in cells cooled using different methods at rates ranging between 3.3 and 97°C S-1. Extensive intracellular freezing was common to all treatments. Unexpectedly, fully hydrated axes not only survived cryogenic exposure, but many axes developed normally when cooled using the relatively slower methods (77 and 3.3°C S-1) if warming was rapid. The most conspicuous ultrastructural difference between plunge cooling and the relatively slower methods was the exclusion of ice from many intracellular compartments in the latter. It is possible that even the fastest warming cannot prevent serious cellular damage if ice crystals form within such 'critical' compartments. It is proposed that the intracellular location of ice is a stronger determinant of survival that the size attained by ice crystals. The study of A. saccharinum also investigated the recovery of axes cooled fully hydrated either rapidly (97°C S-1) or slowly (3.3°C S-1). This facet of the study showed that cell lysis became apparent immediately after warming only where damage was most extensive. In other cells damage became apparent only after 2.5 to 6 h had elapsed, thus cautioning against inferring survival from the ultrastructural appearance of cells immediately after warming. Microscopy enabled cell repair as well as the pattern of growth of cryopreserved tissues to be appraised at the cellular, tissue and organ levels. Similar studies are required to understand further the nature of freezing damage, and how those events affect cell function. The salient trends observed in previous chapters are brought together in Chapter 9. / Thesis (Ph.D.)-University of Natal, Durban, 2002.
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Some effects of drying rate and wet storage on aspects of the physiology and biochemistry of embryonic axes from diesiccation- sensitive seeds.Ntuli, Tobias M. January 2004 (has links)
Desiccation-sensitive seeds show differential viability characteristics during drying at different rates. A number of studies have demonstrated that rapid dehydration permits survival to lower water contents than does slower desiccation. The aim and objective of the present study was to test the hypothesis which states that rapid drying of desiccation-sensitive seeds removes water sufficiently fast to reduce the accumulation of metabolic damage. In addition, the hypothesis that wet storage subjects desiccation-sensitive seeds to mild, but increasingly severe, water stress causing oxidative damage if additional water is not supplied, was tested. In the present study, axes of germinating orthodox seeds of Pisum sativum and newlyshed recalcitrant counterparts of Quercus robur, Strychnos madagascariensis, Trichilia emetica, Trichilia dregeana and Avicennia marina were subjected to rapid or slow drying or wet storage. For those species where more than one harvest was investigated, differences were observed in water contents at shedding. For all the species studied, the dehydration rate could be described by an exponential and a modified inverse function for both desiccation regimes, and the water content remained constant with wet storage. The level of tetrazolium staining and germination percentage of axes decreased sharply drying and hydrated storage such that the marked decline took place at lower water contents upon rapid than slow dehydration. The conductivity of electrolyte leachate increased progressively during desiccation and moist storage of axes of all species investigated. Greater membrane leakage occurred upon slow, than rapid dehydration in axes of all species studied. Activities of respiratory enzymes which have a potentially regulatory role in glycolysis, phosphofructokinase (PFK), or the tricarboxylic acid cycle, malate dehydrogenase (MDH), and levels of the oxidized form of the coenzyme, nicotinamide adenine dinucleotide (NAD), of the enzymes of the electron transport chain, NADH dehydrogenases ofNADH-ubiquinone (coenzyme Q) reductase (complex I) and NADHcytochrome c reductase (complex IV), were monitored in the present investigation. v In addition, the role of free radical activity in the form of lipid peroxidation, which has been implicated in loss of viability in seeds, was examined by assaying the levels of hydroperoxides. The involvement of the free radical processing enzymes, superoxide dismutase (SOD), catalase (CAT) and glutathione reductase (GR), and the antioxidant, ascorbic acid (AsA), was also ascertained. The activity of PFK in axes of P. sativum remained constant during drying and wet storage. However, PFK activity increased as rapid dehydration and hydrated storage of Q. robur axes proceeded. In contrast, the activity of PFK in axes of Q. robur decreased during slow desiccation. Similarly, PFK activity was reduced upon drying, and moist storage, of T. dregeana axes such that higher activity of PFK was seen during rapid than slow dehydration. The activity ofPFK inA. marina axes also declined upon desiccation. The activity ofMDH in axes of P. sativum was also unchanged during drying and wet storage. However, an increase in MDH activity was recorded in Q. robur axes during dehydration and hydrated storage such that the activity of MDH was higher upon slow than rapid desiccation. In contrast, MDH activity in axes of T. dregeana decreased as drying proceeded. Similarly, the activity of J\.1DH declined during dehydration and moist storage of A. marina axes. An increase in the level of NAD occurred in axes of P. sativum during drying. In contrast, a decrease in NAD levels was seen upon dehydration and wet storage of Q. robur axes such that the level of NAD was higher upon rapid than slow desiccation. There was an enhancement of the level of NAD in axes of T. dregeana during hydrated storage. Conversely, NAD levels declined during drying ofA. marina axes. A decrease in the level of hydroperoxides in axes of P. sativum was seen as rapid drying proceeded. In contrast, hydroperoxide levels increased during wet storage of P. sativum axes. Similarly, the levels of hydroperoxides were enhanced upon dehydration and hydrated storage of Q. robur axes such that they were higher in axes during slow desiccation compared to those dried rapidly. Conversely, the hydroperoxide level in axes of T. dregeana was reduced upon rapid dehydration. In contrast, an elevation of the level of hydroperoxides was observed during moist storage. The levels of hydroperoxides remained constant as desiccation and wet storage ofA. marina axes proceeded. vi The activity of SOD in axes of P. sativum decreased during rapid drying. In contrast, SOD activity increased upon slow dehydration and wet storage ofP. sativum axes. There was a decline in the activity of SOD in Q. robur axes during slow desiccation. Similarly, SOD activity was diminished upon drying of axes of T. dregeana. The activity ofSOD in T. dregeana axes was enhanced during hydrated storage. An elevation in SOD activity also took place during rapid dehydration and moist storage of axes ofA. marina. The activity of CAT did not change during drying of axes of P. sativum. However, a decrease in CAT activity in Q. robur axes was seen upon slow dehydration and wet storage. Similarly, the activity of CAT declined as desiccation of axes of T. dregeana proceeded. In contrast, CAT activity inA. marina axes increased during slow drying. Whereas the activity of GR in axes of P. sativum increased during drying and wet storage, GR activity decreased in A. marina axes upon all treatments such that the activity ofGR was higher during rapid than slow dehydration. GR activity also declined upon slow desiccation and hydrated storage ofaxes of Q. robur. Similarly, the activity of GR in T. dregeana axes was reduced during moist storage. Finally, a decrease in the level of AsA in axes of P. sativum took place during drying. Nonetheless, dehydration and wet storage of Q. robur axes were associated with no siginificant change in AsA levels. There was also a decline in the level of AsA in axes of T. dregeana as rapid desiccation proceeded. Similarly, a reduction in AsA level occurred upon slow drying ofaxes ofA. marina. The results presented here are consistent with the observation that drying and wet storage adversely affected the respiratory enzymes, PFK, MDH and NADH dehydrogenase. It is suggested that the resultant metabolic imbalance led to more leakage of electrons from the mitochondrial electron transport chain than normal, and through lipid peroxidation increased levels of hydroperoxides. In addition, dehydration and hydrated storage may depress the activities of free radical processing enzymes, SOD, CAT and GR and levels of antioxidant, AsA. This phenomenon was less pronounced during rapid, in comparison to slow, desiccation and moist storage. However, it appears that the above biochemical events are overtaken by physical damage at higher water contents in the highly recalcitrant seeds. It was concluded that the differential effects of VII the drying rate and wet storage on responses of desiccation-sensitive seeds varies with tissue, harvest, species and the degree of desiccation sensitivity. / Thesis (Ph.D.)-University of KwaZulu-Natal, 2004.
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Development of explants potentially suitable for cryopreservation of the recalcitrant-seeded species Theobroma cacao L. and Barringtonia racemosa (L.) roxb.Naidoo, Prabashni. January 2008 (has links)
The two species investigated in this study were Theobroma cacao and Barringtonia racemosa. Theobroma cacao has worldwide economic importance, as cocoa (the main ingredient in chocolate) is produced from the seeds of this tree; while B. racemosa has several applications in herbal medicine. The seeds of both T. cacao and B. racemosa are highly recalcitrant and therefore not amenable to storage for any significant periods.
The long-term conservation of the germplasm of these species may only be feasible via cryopreservation. The aims of the present study were to: 1) optimize in vitro regeneration protocols for different types of explants that have the potential to be
cryopreserved while maintaining the genetic integrity of these two species; and 2) develop cryopreservation protocols for selected explants. For T. cacao, protocols were established for bud-break and multiplication for both in vitro - and greenhouse-derived nodal explants, as well as a rooting medium for shoots derived from axillary buds. Parameters investigated towards the cryopreservation of axillary shoots, from greenhouse nodal segments, and nodal segments from in vitro plantlets, included the size of the explant and pre-treatments for cryopreservation. Nodal segments (6 - 7 mm) and axillary shoots (2 - 4 mm) needed to be soaked in 0.5% (w/v) ascorbic acid for 10 min to minimise phenolic production and subsequent tissue death,
and surface-sterilized by soaking in 1% Ca(OCl)2 solution for 5 min to reduce microbial contamination. Subsequent cryopreservation attempts involved only in vitro nodal segments because of the lack of success in achieving elongation of excised axillary buds. Vitrification and slow freezing methods, with or without the application of cryoprotectants, did not achieve successful cryopreservation. Attempts to establish a protocol for producing somatic embryos, as an alternate to axillary shoots and in vitro nodal segments, resulted in the production of globular embryogenic callus for both leaf and cotyledon explants. Cryopreservation of these explants was not investigated in the
scope of this study. The study on B. racemosa focused on the development of a somatic embryogenesis protocol. Segments of embryonic axes produced globular-stage embryos when placed
on MS medium supplemented with 30 g 1-1 sucrose, 1.0 g 1-1 casein hydrolysate, 2.0 mg 1-1 2,4-D, 0.1 mg 1-1 BAP and 8.0 g 1-1 agar. Various strategies were employed to obtain embryo germination, which included 1) different time intervals on callus initiation medium; 2) the use of different auxins (IAA, NAA and 2,4-D) in combination with the cytokinins BAP and kinetin; 3) desiccation and 4) cold treatments. Although somatic embryo germination was not achieved, globular embryos proceeded with development to the cotyledonary stage when cold-treated for 8 h at 4°C. This study provides some fundamental bases for further investigation towards achieving long-term conservation for both T. cacao and B. racemosa. However, the use of meristems as explants for cryopreservation is suggested to be the way forward for the cryopreservation of both species. / Thesis (M.Sc.)-University of KwaZulu-Natal, 2008.
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A study of some chilling responses of recalcitrant seeds of Avicennia marina (Forssk.) Vierh. and Ekebergia capensis Sparrm.Lewis, Elisabeth Jacqueline. January 2002 (has links)
Seeds remain the most convenient and successful way for storing the genetic diversity
of plant species and for producing new plants routinely for agriculture and horticulture.
The importance of seed storage and the ability to predict seed longevity must therefore
not be underestimated. To be successful, storage conditions must maintain seed vigour
and viability and ensure that normal seedlings are subsequently established under field
conditions. Seed quality is best retained when deteriorative events are minimised,
which is achieved by storage of low moisture-content seeds under cool to cold, or even
sub-zero, temperatures. Such conditions are employed for 'orthodox' seeds, which are
desiccation tolerant and able to survive at sub-zero temperatures in the dehydrated state
for extended periods. It is seeds referred to as 'recalcitrant' that cannot be dehydrated
and often not stored at low temperatures because they are desiccation sensitive and may
not tolerate chilling. According to almost anecdotal records chilling temperatures for
such seeds are those below 15°C down to 0°C, depending on the species. The limited
storage lifespan of recalcitrant seeds presents a problem even for short-term storage, and
as most research on chilling sensitivity has been conducted on vegetative tissue,
relatively little data exist for seeds, especially recalcitrant types.
The purpose of this study was to gain an understanding of the chilling response of
recalcitrant seeds, as reduced temperature could have the potential to extend, rather than
curtail, storage lifespan, depending on the species. Selected physiological, biochemical
and ultrastructural responses of recalcitrant seeds of Avicennia marina and Ekebergia
capensis were characterised. Seeds of the two species were stored at 25, 16 and 6°C.
Germination, water content (determined gravimetrically), respiration (measured as CO2
production) and leachate conductivity (tissue electrolyte leakage over time) were
assessed at regular intervals. Chilling response at the subcellular level was examined
using transmission electron microscopy (TEM). Changes in sugar metabolism and
activities of the antioxidant enzymes superoxide dismutase (SOD), catalase (CAT) and
glutathione reductase (GR) were assessed for A. marina seeds, which were severely
affected by the chilling temperature of 6°C, losing viability after 1 week. In contrast,
the seeds of E. capensis retained viability after 12 weeks of storage at 6°C, indicating
the marked difference in chilling response between seeds of the two recalcitrant species,
despite their common tropical provenance. However, when E. capensis seeds were
stored at 3°C viability decreased significantly after 8 weeks, thus indicating how
critically temperature must be controlled if such conditions are to be profitably
employed.
Ultrastructural studies revealed that in both E. capensis and A. marina seeds vacuole
formation was initiated more rapidly at lower temperatures than at higher temperatures,
indicating that this was a response specific to the chilling stress imposed. Once again,
'lower temperatures' differed relative to the species concerned. In the E. capensis
seeds, nucleolar morphology was affected and the extent of chromatin patches in the
nuclei increased as the storage temperature was reduced. Other ultrastructural findings
could not be linked specifically to the chilling stress imposed on the E. capensis and A.
marina seeds.
Activity of the antioxidant enzymes SOD and GR was detected in the A. marina seeds.
No measurable CAT activity was detected. Glutathione reductase activity increased in
response to chilling stress, the rate of the increase depending upon the severity of the
chilling stress imposed. Other than when the A. marina seeds were placed directly at
6°C, there were no notable increases in SOD activity. Interestingly, SOD and GR
activity was not the same in the axes as in the cotyledons. Superoxide dismutase
activity was found to be higher in the axes and GR activity higher in the cotyledons. It
would have been beneficial to determine the extent of antioxidant enzyme activity in the
E. capensis seeds as well if this had been possible.
Generally, chilling of recalcitrant seeds seems to evoke a response similar to that of
dehydration below a critical water content. This could lead to the conclusion that
recalcitrant seeds do not possess the genetic ability to cope with dehydration or chilling
stress, if it were not for the existence of recalcitrant seed species that are more chilling
tolerant. / Thesis (M.Sc.)-University of Natal, Durban, 2002.
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The potential of hot water treatments for curtailing seed-associated mycoflora.Erdey, Deon Philip. January 1995 (has links)
The consequences of toxigenic fungi associated with stored seed have stimulated these
investigations aimed at developing treatments to minimise this mycoflora, without
significantly reducing seed quality or viability. The effects of immersion in water at 55, 57
and 60 QC for durations of 5 to 60 min were assessed for maize (Zea mays L.) seed in terms
of fungal status, water uptake, electrolyte leakage, germination and seedling establishment.
These assessments were conducted immediately after treatment, after re-dehydration for 2
days in an ambient air stream, and following a 1 month storage period under either cold (4
QC) or ambient (25 QC) conditions (33% and 91% RH, respectively). In all cases, the results
are compared with those of control seeds and seeds pre-imbibed for 4 h at ambient
temperature.
The level of internal contamination, represented almost entirely by Fusarium moniliforme
Sheldon, declined significantly when assessed immediately after treatment, the efficacy of
which increased with increasing temperature and duration of treatment. Seeds immersed in
water at 55 QC for a duration of 15 min exhibited an 85% reduction in infection levels, when
compared with those of the control, while those treated at 57 and 60 QC (same duration) were
uninfected. Immersing seeds in hot water, however, resulted in a lag in germination rate and
drop in germination totality, the degree of which was enhanced by increasing duration and
temperature of treatment, suggesting the status of the manipulation to be an accelerated ageing
treatment. The electrolyte leakage studies indicated that the reduced germination performance
of these seeds was not due to plasmalemma disorganisation. These deleterious effects,
however, were counter-balanced as seeds treated at 55, 57 and 60 QC for durations up to 60,
30 and 10 min, respectively, produced plants of superior quality than those of the control,
which is ascribed to the reduction of systemically transmitted pathogens. The efficacy of the
hot water treatment in reducing the levels of seed infection and improving seedling quality
was enhanced by subsequent re-dehydration. The reduction in seed-associated mycoflora was
maintained following storage for 1 month at both 4 QC (33% RH) and 25 QC (91% RH).
However, both seed and seedling quality were adversely affected following storage even under
cold, dry conditions, which may be a consequence of the pre-treatment history of the seeds,
which had been cold-stored for two years prior to the experiments. Applied as a pre-sowing
treatment, therefore, hot water treatment shows promise for producing a crop of superior
quality, less prone to fusarial pathogenesis. This treatment may be of particular importance
to Third-World subsistence communities. / Thesis (M.Sc.)-University of Natal, 1995.
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The influence of pollinator diversity and behaviour on pollen movement in Brassica rapa chinensis (Pak-Choi) crops, and its significance for gene escapeMesa, Laura A. January 2008 (has links)
The overall aim of the study was to assess the risk of gene flow from Brassica crops by insectmediated pollen transport. I measured the viability of pollen in Brassica flowers throughout crop development and compared this with the viability of pollen transported by insects inside and outside one early- and one late-season crop. In order to evaluate the relative importance of different species in pollen transport, I measured abundance of flower visitors during crop development, and measured the foraging behaviour of five key pollinator species throughout the growing season, in relation to variation in microclimate, crop phenology and the relative abundance of other pollinator species competing for flower resources. Flower visiting insects of Brassica rapa crops were highly diverse, and their abundance and diversity changed with crop phenology. I found similar abundances at the family level for both crops studied, although capture rates were greater in the early- than in the late-season crop. Across flowering development, the greatest numbers of insects were captured at the peak of flowering for both crops. During the flowering period, Diptera was the most abundant order collected, followed by Hymenoptera. The most abundant family in Hymenoptera was Apidae which tracked crop development in both fields, with greater numbers of insects captured inside than outside the field. Standardized-count pollen loads were smaller in Diptera than in Hymenoptera. Of the five key pollinator species sampled, Lasioglossum sordidum (Hymenoptera: Halictidae), Apis mellifera (Hymenoptera: Apidae) and Bombus terrestris (Hymenoptera: Apidae) transported similar pollen loads, which were much greater than those carried by Eristalis tenax (Diptera: Syrphidae) and Melangyna novae-zealandiae (Diptera: Syrphidae). The numbers of insects captured outside of the crop were 10% and 33% of the totals captured inside for the early- and the late-season crop, respectively. The proportion of insects entering versus leaving the crop varied considerably across species, crops and trap location (i.e., whether traps were inside or 50 m outside the border of the crop). However, it is worth noting that not uncommonly more insects were attracted into the crop early in the season, staying there rather than leaving, and then when flowers started to disappear there was a massive escape of insects leaving. This research provides evidence for the influence of crop age on the foraging behaviour of key pollinators and for species-specific variation in the foraging behaviour of Brassica visitors with crop development. Temporal variation in the rate and variability of movement between flowers, and the duration and variability in time spent on each flower, throughout the growing season differed markedly between pollinator species. Flower density, plant density, and the abundance of other insects contributed to the observed variation in pollinator behavioural activity for A. mellifera, E. tenax, M. novae-zelandiae and L. sordidum. Bombus terrestris had the greatest rates and variability of movement, and the greatest rates of flower visitation among all key pollinators studied. Therefore B. terrestris might contribute to gene flow to a greater extent than other key pollinators. Additionally B. terrestris had the greatest variability in the rate of movement, increasing the risk of pollen movement over long distances. In summary, I found that (i) insect abundance and diversity changed with crop phenology and Diptera was the most abundant order collected, (ii) flower density, plant density, and the abundance of other insect pollinators were important factors explaining pollinator behaviour for all key pollinators, except B. terrestris, (iii) B. terrestris might contribute to gene flow to a greater extent than other key pollinators, because it has a greater rate of flower visitation and a greater flight distance between flowers than other pollinators, and (iv) pollen viability tended to decrease with crop development and declined sharply even just 50 m outside the edge of the crop.
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FULL-THICKNESS SMALL INTESTINE NECROSIS WITH MIDGUT VOLVULUS, DISTRIBUTED IN A PATCHY FASHION, IS REVERSIBLE WITH MODERATE BLOOD FLOW : RESUMPTION OF NORMAL FUNCTION TO NON-VIABLE INTESTINEKISHIMOTO, HIROSHI, TANAKA, YUJIRO, KAWASHIMA, HIROSHI, UCHIDA, HIROO, AMANO, HIZURU 08 1900 (has links)
No description available.
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Assessing the economic viability of biogas plants at abattoirs in South Africa / Coenraad GoosenGoosen, Coenraad January 2013 (has links)
With electricity tariffs in South Africa escalating at a rapid pace the demand for alternative power sources has increased. One of these renewable energy sources includes the use of biogas. Biogas is not only one of the most efficient and effective renewable energy possibilities available but also requires less capital investment as compared to other renewable sources like hydro, solar and wind and are also more economical as it involves less per unit production cost. Biogas plants have been used around the globe for numerous years, but are a relative new technology in South Africa, predominantly in the red meat industry with the use of slaughter waste as a form of biomass. Slaughter waste offers a vital possible source of renewable energy. A variation of factors makes the production of renewable energy from slaughter waste particularly appealing. The continuous rise of energy prices, waste disposal prices, and incentives for renewable energy production have increased the value of outputs from slaughter waste-to-energy systems.
The primary objective of the research is assessing the economic viability of biogas plants at abattoirs in South Africa and if such a biogas plant would be beneficial to an abattoir. The research aimed to determine the viability through various capital budgeting techniques and define what the most significant calculated variables are that should be addressed in such an economic viability model. For the purposes of this study a Class A abattoir with a slaughtering capacity of 400 cattle per day was used as a case study. Biogas will be generated through anaerobic digestion and the utilising of the gas for the generation of electricity and heat by means of a CHP generator.
The economic viability study contains of a base case scenario and two other possible scenarios and provides recommendations and a concluding report, based on the scenario that is the most viable. The succeeding techniques which were recognised were used to analyse the economic viability of the biogas plant: Payback Period, Discounted payback period, Net present value, profitability index, and internal rate of return. Furthermore a sensitivity analysis was done in the study with a pessimistic and optimistic outcome on key variables. The study establish that in the base case scenario a positive net present value was realised, the internal rate of return was more than the required rate of return and the payback periods was shorter than required.
In this study the concept of biogas plants in the red meat industry were researched with the purpose of determining the economic viability of these plants. In determining the viability of the biogas plant the key variables that will impact the viability was also identified and discussed. Based on the data gathered and assumptions that was made it was concluded that a biogas plant will be beneficial to an abattoir and was considered economically viable. / MBA, North-West University, Potchefstroom Campus, 2014
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