Nanotechnology is a rapidly growing

Nanotechnology is a rapidly growing fieldwith potential application
in fields ranging fromelectronics to cosmetics [1,2]. Nanoscience covers
the basic understanding of physical, chemical and biological properties
in atomic and sub-atomic levels [3]. It has opened the doors to pave
way for the rapidly growing technologies involved in the design and
development of novel materials which exhibit unique and improved
properties. Silver nanoparticles (SNPs) fit very much into this category
due to itswide range of commercial applications involving several fields
like optics (for metal-enhanced fluorescence and surface-enhanced
Raman scattering), electronics, catalysis, sensors and therapeutics
[4–6]. Currently nano-silver is used for a variety of applications in everyday
consumer's life such as: nanosilver infused food storage containers
[7], nanosilver coated surfaces of medical devices to reduce
nosocomial infections, bandages, footwear and countless household
items respectively [8a]. According to Ayurveda (an ancient Indian
medical treatise), nanosilver is a popular additive in several Indian
health products due to its unique ability to fight infectious diseases
[8b, 8c, 8d, 8e]. On the other hand, SNPs are gainingmore importance
in the medical field as antimicrobials, sterilizers and testing tools
for diagnosing and detecting sensitive biomolecules. The large surface
area of SNPs allows them to be in better contact with microorganisms
and thus, impart good antibacterial activity even at
lower concentrations. When SNPs enter inside a pathogen, the particle
releases silver ions, thereby killing it. Several mechanisms have been
proposed to explain the activity of silver ion or SNPs on bacteria like:
i) inactivation of respiratory chain, ii) disruption of cell membrane
and leakage of its cellular contents, iii) binding to functional group of
proteins causing protein denaturation and cell death, iv) blocking of
DNA replication, and v) denaturation of enzymeswhich transport nutrients
across bacterial cell membrane [9]. Due to these properties,
nanosilver acts as an effective killing agent against a broad spectrum
of (Gram-negative and Gram-positive) bacteria, including the antibiotic
resistant strains [10].
SNPs can be synthesized using variousmethods like reduction reaction,
chemical and photochemical reaction, thermal decomposition, radiation
assisted method, electrochemical process, sono-chemical and
microwave assisted synthesis respectively [6,11–13]. Although these
methods can successfully produce silver nanoparticles in an efficient
manner it usually involves the use of toxic and hazardous chemicals
which have several harmful effects on the environment and human
health [14]. Again, the final product requires more purification steps,
as some of the chemicals/reducing agents/by-products left behind during the process get adsorbed on the surface of SNPs and can cause
adverse effects during a medical application or treatment. Additionally,
these methods use expensive chemicals and usually require stabilizers
to prevent agglomeration of SNPs. On the other hand, green chemistry
is a widely accepted alternative process for synthesizing SNPs.
Green synthesis does not involve the use of any toxic chemicals, it is
cost-effective, environment friendly, zero energy based and less time
consuming process. Moreover it does not require the use of any kind
of stabilizers. Various environmental friendly materials like plant
extracts, bacteria, actinomycetes, fungi and enzymes are categorized
and used as sources under ‘green synthesis’. SNPs synthesized by
green process are highly compatible for pharmaceutical and other biomedical
applications [15]. This process can be easily scaled up for the
bulk synthesis of SNPs without involving the use of any high pressure,
energy and temperature conditions [16]. Various plant resources have
been explored by researchers till date to synthesize silver nanoparticles
[11,13–19]. The key phytochemicals responsible for converting silver
ions into silver nanoparticles are found to be terpenoids, glycosides,
alkaloids, phenolics (flavonoids, coumarins, ubiquinones, tannins, etc.)
as identified in IR spectroscopic studies [20,21]. One of the commonest
plant products used for daily consumption is the seed (bean) of Coffea
arabica fam. Rubiaceae. The bean of this plant was earlier reported to
contain good levels of phenolic compounds [20,21] and thus, it could
be used as a potential bioreductant to produce SNPs.
Based on the above findings, the present study was carried out to
examine the use of dried roasted coffee seed in the form of a hydroalcoholic
extract to prepare silver nanoparticles and to prove its efficacy
as an effective antibacterial agent.