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Message from the President; MAS calendar of events; and lists of MAS
council officers, past MAS presidents, MAS sustaining members, MAS award
winners, MAS distinguished scholars, and previous MAS award winners.
Lipases (glycerol ester hydrolases, E.C. 3.1.1.3) are enzymes of
great industrial interest due to their ability to catalyze a broad range
of hydrolytic and synthetic reactions. They find applications in the
synthesis of compounds used in clinical, nutritional, environmental,
pharmaceutical and chemical fields. For example, lipases are used to
catalyze key intermediate steps in the synthesis of biologically active
compounds such as Naproxen, Ibuprofen and Atenolol [1]. Depending on the
application, lipases may need to be purified and characterized
biochemically before they can be used. However, the purification of
microbial lipases is often made difficult by the presence of high
molecular weight aggregates. These aggregates can form due to the
presence, in the fermentation medium, of lipids used to induce the
production of the enzyme by the microorganism or simply due to
hydrophobic interactions amongst the enzyme molecules themselves [2]. In
previous work, we characterized a new lipase produced by Bacillus
megaterium CCOC P2637. The enzyme eluted in the void volume during gel
filtration chromatography, indicating that it was present in the form of
a high molecular weight aggregate. This aggregate was dispersed when a
gradient of 60% (v/v) isopropanol was used, but formed again when the
enzyme was injected in a gel filtration column for further purification,
even when the elution buffer contained 20% (v/v) isopropanol. Further,
when the enzyme was diluted in buffer (phosphate pH 7.0 20 mM)
containing 30% isopropanol, its specific activity was double the
activity obtained by diluting in buffer without isopropanol [3].
Pollens appear like a fine to coarse powder that is liberated by the
microsporangia of Gimnosperms and Angiosperms. The pollen grain wall,
the sporoderm, envelopes the microgametophytes (male gametophytes),
which produce the male gametes of seed plants. Pollen grains are
interesting from the material science point of view since the native
polymer, the sporopollenin, found in the sporoderm outer layer (exine),
is one of the toughest known materials which is degraded by oxidation
but is resistant to reduction. This property permits the sporopollenin
persistence as an unaltered polymer in sediments of great age, e.g the
Ordovician period, 400 million years ago. Sporopollenin is a mixture of
fatty acids, phenyl-derivatives as p-coumaric acid, and carotenes [1].
Its nanostructure is not yet completed revealed. Therefore, more studies
must be performed. A number of models have been proposed for the
sporopollenin nanostructure of spores and pollen grains [2]. Rowley et
al. [3-4] interpret exine structure as being formed by helical subunits,
based on transmission and scanning electron microscope (TEM and SEM)
studies. The atomic force microscopy (AFM) is the ideal method to study
the sporopollenin nanostructure [5] since the arrangement of components
is not visualized easily through other microscope techniques (e.g. TEM
and SEM). In the present work, we used AFM to study the sporopollenin
nanostructure of the Ilex paraguariensis A.St.Hil. exine, an Angiosperm
(Aquifoliaceae).
Message from the President; IMS calendar of events; and lists of IMS
board of directors, IMS appointments, IMS corporate sponsors, past
IMS presidents, IMS award winners, competition judges, and the IMS
conference organizing committee.
Diamond-like carbon (DLC) films have been intensively studied with a
view to improving orthopaedic implants. Studies have indicated
smoothness of the surface, low friction, high wear resistance, corrosion
resistance and biocompatibility [1-4]. DLC coatings can be deposited
using various techniques, such as plasma assisted chemical vapour
deposition (PACVD), magnetron sputtering, laser ablation, and others
[5]. However it has proved difficult to obtain films which exhibit good
adhesion. The plasma immersion process, unlike the conventional
techniques, allows the deposition of DLC on three-dimensional
workpieces, even without moving the sample, without an intermediate
layer, and with high adhesion [6], an important aspect for orthopaedic
articulations. In our previous work, DLC coatings were deposited on
silicon and Ti-13Nb-13Zr alloy substrates using the plasma immersion
process for the characterization of microstructure, mechanical
properties and corrosion behaviour [7-9]. Hardness, measured by a
nanoindenter, ranged from 16.4-17.6 GPa, the pull test results indicate
the good adhesion of DLC coatings to Ti-13Nb-13Zr, and electrochemical
assays (polarization test and electrochemical impedance spectroscopy)
indicate that DLC coatings produced by plasma immersion can improve the
corrosion resistance [9].
Message from the President; and lists of the executive committee,
non-executive officers, AMMS Inc. state representatives, past AMMS
presidents, and AMMS awards.
While investigating isolated or agglomerates of treated Vaccinia
virus intracellular mature (IMV) particles in atomic force microscopy
(AFM) equipment we noticed that in some occasions the enveloped
particles had been totally disrupted, with the interior being spread
around. We have also observed in these samples what appear to be some
rather intriguing viral surface interactions. Instead of showing a clear
division between individual virions the particles seem to be continuous
at the interfaces that show coalescence. In order to understand what was
happening we focused our attention on the analysis of the images of the
interface between virions particles, trying to find out what was the
explanation for such type of particle surface interaction and in which
conditions it would take place.
Atomic force microscopy (AFM) is a powerful tool for direct
visualization of supported biological membranes [1]. Moreover, in-situ
AFM measurements permit investigations of biological phenomena in real
time and in physiological environments. In a previous work, we have
studied the morphology and stability of supported phospholipid layers
prepared by solution spreading (casting) on mica [2]. The images were
acquired in the contact or contact-intermittent modes and the samples
analyzed ex-situ just after solvent evaporation and after a hydration
step, and in-situ with immersion in a buffer solution. Contact-mode
imaging is less suitable for soft or weakly attached materials, since
the tip can often scrape or drag the membranes during scanning, a
disadvantage that can be overcome by applying intermittent methods.
However, studies have also demonstrated that by adjusting the operative
force it is possible to use contact-mode to obtain AFM images of soft
phospholipids layers [3]. In the present work, we applied successfully
in-situ AFM contact-mode to characterize phospholipid layers of
1,2-dimyristoyl-sn-glycero-3-phosphatitidylcholine (DMPC) and
1,2-dioleoyl-sn-glycero-3-phosphatidylcholine (DOPC), as well as a
binary mixture of these phospholipids. The supported membranes were
prepared on mica substrates by vesicle fusion method.
The adsorption of polysaccharides onto solid substrates provides an
environment for the immobilization of biomolecules [1] giving rise to
conditions for the development of biosensors [2] and kits for
immunoassays. One can find in the literature reports about the adhesion
of proteins on cellulose ester membranes [3]. However, studies about the
formation of cellulose ester ultrathin films have been seldom reported.
Cellulose esters are nontoxic materials largely used as coating layers,
fibers, inks and films.
In the last decades several investigations have been conducted with
the objective of studying the
microstructural characteristics and mechanical properties in low carbon
microalloyed steel [1,2].
These steels contain a polyphase microstructure, with complex mixture of
bainite, MA constituent
(martensite-austenite residual), pearlite, ferrite and martensite. They
are often used in the automobile
industry, in the production pipelines for the transport of gas and oil
in areas of sub-zero temperature
and in the naval ship construction, because they possess high strength,
high toughness at low
temperature and good weldability.