Synthesis and Bioactivity of 1-((2-Carbamoylguanidino) (furan-2-ylmethyl)urea

1-((2-Carbamoylguanidino)(furan-2-ylmethyl)urea was synthesised by coupling purified furfural with urea. The compound was characterized by GC-MS, FTIR, and H-NMR. The pathogens, Escherichia coli, Salmonella typhi, Staphylococcus aureus and Bacillus subtilis were isolated and screened with different concentrations of 1-((2-carbamoylguanidino)(furan-2-ylmethyl)urea. All the pathogens were susceptible to the synthesized compound except Bacillus subtilis. Due to this broad spectrum of activity, 1-((2-Carbamoylguanidino)(furan-2-ylmethyl))urea) can be use for various medicinal purposes and is therefore encouraged for the development of a novel drug in future.


Introduction
In the last decades, there has been a growing interest in synthesis, researching and developing new antimicrobial agents from various sources to combat microbial resistance [1]. Currently, microbial infections have become an important clinical threat, with significant associated morbidity and mortality which is mainly due to the development of microbial resistance to the existing antimicrobial agents [2]. Microbial resistance to antibiotics is one of the most important global health problems, justifying the necessity of innovation; most synergic radical antimicrobial agents have emerged [1] [3]. The antibiotic resistance problem is amplified by the ability of bacteria to grow in an adherent state, developing microbial communities called biofilms, which exhibit a phenotypic resistance, i.e. tolerance, rendering them to1000-fold more resistant to antibiotic treatments when compared to their planktonic counterparts [4]. The important hallmarks of chronic biofilm-based infections are extreme resistance to antibiotics and many other conventional antimicrobial agents, and an extreme capacity for invading the host defences [5].
Furfural is a heteroaromatic aldehyde (furan-2-carbaldehyde) produced from a variety of agricultural by-products [6] and is obtained by hydrolysis and dehydration of pentose carbohydrates contained in lignocellulose [7]. It is a chemical that is potentially relevant in organic synthesis due to its cheapness and bio-availability [7] [8]. It is an essential chemical in the synthesis of furan; an intermediate for the production of pharmaceutical drugs and fine chemicals in the industries (Eseyin & Steele, 2015). It serves as an agricultural nematocide: it is used to control plant-parasitic nematodes without adversely affecting the growth and yield of the plant (Rodriguez-Kabana, Kloepper, Weaver, & Robertson, 1993). Furfural does not kill the nematodes directly but promotes a bacterial activity that acts as an antagonist, thus influencing the biological activity of the nematodes (Zeitsch, 2000). Due to low acute and ecological, non-systematic (not absorbed by the plant) and safe applicability to the soil through water solution, furfural is seen as a biomass-derived active ingredient in nematocide formulation for agriculture products (Rodriguez-Kabana et al., 1993).
Heterocyclic compounds are important to human life because their structural subunits exist in many natural products such as vitamins, hormones, antibiotics and pigments. Furfural derivatives are the subject of many research studies due to their widespread potential biological activities such as antimicrobial [13], antiviral [14], antioxidant [15], antitumor, antihistaminic and fungicides [16]. These have rendered furfural derivatives valuable active ingredients of medicine and plant protecting agents. These compounds are useful in the field of medicine and are used as a starting material for the synthesis of a new drug [16].
Urea is an important nitrogen-containing compound that has proved to be useful substances in drug research in recent years [13] [17]. Some urea derivatives possess valuable antituberculosis, antibacterial and anticonvulsant properties [18]. Thioureas can be used in the control of plant pathogens like Penicillum expansum and Fusarium oxysporum [19]. Urea is a raw material for the production of two main classes of chemical substances; urea-formaldehyde resins and urea melamine-formaldehyde which are used in marine plywood. It has the highest nitrogen content of all the nitrogenous fertilizer commonly used in agriculture [20]. Emmanuel et al. [21] reported for the first time the antifungal American Journal of Analytical Chemistry activity of 2-aminooxazole thiourea derivatives against Botrytis cinerea.
Synthetic medicinal chemistry, with the skill, wisdom and effort has proven to be a major endeavour not only confined to the laboratories of universities in general, but also to the bulkdrug industry in particular [22]. Biological activity of a compound is a function of the structure [23]. Minor changes may cause prominent implication overactivity. Replacement of one group by the other in a specific location in the molecule may sometimes completely reverse the action of the compound [24]. The probable points of differences amongst the antibiotics may be physical, chemical, pharmacological properties, antibacterial spectra and mechanism of action [25]. In view of these data, we have undertaken the synthesis, characterization and antimicrobial evaluation of 1-((2-Carbamoylguanidino)(furan-2-ylmethyl)urea. The unique fact about this paper is that the bioactivity of this furfural derivative, 1-((2-Carbamoylguanidino)(furan-2-ylmethyl)urea has not been reported in the literature. Furfural was bought from a chemical store and purified by vacuum distillation.

Materials and Methods
Other chemicals such as urea, ethanol, and sodium hydroxide were of Analar grade and used without further purification. Thin-layer chromatography (TLC) was carried out using a Merck pre-coated silica gel plate (10 × 10 cm); the Rf value was obtained using a solvent mixture of n-hexane and ethyl acetate in a ratio of 2:3. The chromatogram was visualized using an ultraviolet lamp at 256 nm.

Synthesis of 1-((2-Carbamoylguanidino)(furan-2-ylmethyl))urea
The furfural used in this study was bought from a chemical store. The deteriorated furfural was purified by vacuum distillation at the temperature of 65˚C to 80˚C. The procedure adopted in the synthesis of 1-((2-Carbamoylguanidino)(furan-2-ylmethyl)urea was earlier reported by Orie et al. [26]. The purified furfural

Pathogen Isolation
The test pathogens (Escherichia coli, Salmonella typhi, Staphylococcus aureus and Bacillus subtilis) that were used for the antimicrobial screen were isolated from clinical samples obtained from Beracah Hospitals, Rukpokwu, Port Harcourt, Rivers State.

DMSO Solubility Screen
This was done to determine the concentrations of DMSO (ranging from 10%v/v to 100%v/v) that best dissolves test compounds/agents to be used for the screen.
To carry out this screen, 0.1 g of each synthesized agent was suspended in 100 mL of the different concentrations of DMSO at room temperature with continuous agitation for 12 hours. After the incubation period, the observed solubility patterns were recorded.

Toxicity Screen
This screen was carried out to determine the concentrations of DMSO (amongst those that achieved the best agent solubility) that did not show any inhibition pattern on the test microbial pathogens. The well-in-agar diffusion method was used to carry out this screen, where 10 µL of these different DMSO concentrations were introduced into wells (

Minimum Inhibitory Concentration (MIC) Screen
This screen was done to determine the least concentration of the test agents that is capable of inhibiting the growth of each microbial test pathogens. The screen was also carried out using the well-in-agar diffusion method. For each test pathogen that was screened, a cell concentration of 10 8 cells was first inoculated into Mueller Hinton agar plates, after which wells (5 mm diameter) were dug and filled (10 µL) with the different concentrations of each of the test agent. The plates were then incubated for 12 -24 hours at 37˚C. After incubation, the observed zones of inhibition for each concentration of each test agent on each test pathogen were recorded. MIC concentration was then determined by looking out for that particular minimum concentration of the test agent that was capable of inhibiting the growth of a given test pathogen.

Minimum Bactericidal Concentration (MBC) Screen
This screen was carried out to determine the least concentration of the test agents that is capable of inhibiting the growth of each microbial test pathogen by killing their cells. For each microbial pathogen, 0.1 mL of the cells (10 8 Table 1 shows the physio-chemical properties, FTIR and NMR results of 1-((2-Carbamoylguanidino)(furan-2-ylmethyl))urea), these results are in line with Emmanuel et al. and Orie et al.

Results and Discussion
From the results presented in Table 2, it was extrapolated that 1-((2-Carbamoylguanidino)(furan-2-ylmethyl))urea) has an antibacterial activity on all the test pathogens with the exception of Bacillus subtilis, given that all concentrations showed no inhibition zones on the pathogen ( Table 2).
The efficacy of this activity on the different test pathogens varied as indicated by their MIC readings ( Table 2). The sample showed the most activity on Salmomellatyphi because it is the organism with the least concentration of the sample (0.001 mg•L −1 ) as its MIC. The second most susceptible pathogen to the sample was Escherichia coli (0.01 mg•L −1 ), while the least susceptible pathogen was Staphylococcus aureus (1.0 mg•L −1 ). Bacillus subtilis was not inhibited by the agent.
With the exception of Bacillus subtilis, the sample has a bactericidal action on the test pathogens, but also at varied concentrations. For Escherichia coli, concentrations that are above 0.1 mg•L −1 will bring about the death of cells. For Sta-phylococcus aureus, concentrations below 1.0 mg•L −1 will bring about the death of cells, while for Salmonella typhi, concentrations that are below 0.1 mg•L −1 will bring about the death of cells. Table 3 shows Minimum Bactericidal Concentration (MBC) of CFM on Test Pathogens. The compound CFM exhibited both bactericidal and bacteriostatic properties when screened on the pathogens. Bactericidal mode of inhibition was observed with Escherichia coli and Salmonella typhi, while bacteriostatic mode of inhibition was observed with Bacillus subtilis.  Table 2. Activity of 1-((2-Carbamoylguanidino)(furan-2-ylmethyl))urea) on test pathogens.