This systematic review was conducted according to the guidelines of the Cochrane Handbook for Systematic Reviews of Interventions,11 following the four-phase flow diagram of the Preferred Reporting Items for Systematic Reviews and Meta-Analyses (PRISMA) Statement.12 This report is based on the PRISMA Statement. The following databases were screened: MedLine (PubMed), SciFinder, Web of Science, Scopus, Scielo, Google scholar, and ProQuest. For patents, the sources searched comprised the following: INPI, Google patents, Espacenet, Patents online, USPTO, and WIPO.

The search strategy is described in Table 1, and the focused question is as follows: What is the antimicrobial potential of PE against human and animal pathogenic microorganisms?

Study characteristics, demographic information, enrollment criteria, microorganisms tested, antimicrobial assay types, duration, results, control and groups, and sample size (Tables 2 and 3) were extracted independently for two reviewers (J.L.S.S. and V.B.S.G.). Missing information was sought from authors and/or inventors. The full text papers and patents were assessed independently and in duplicate by the reviewers. Any disagreement on the eligibility of studies included was resolved through discussion and consensus, and in case of disagreement, a third reviewer (R.G.L.) decided whether the article should be included. All titles and abstracts of articles and patents initially found were analyzed and selected in accordance to the eligibility criteria. No restrictions were considered regarding the language and year of publication. The reference lists of studies included were hand-searched for additional articles. Full copies of all potentially relevant studies were identified. Studies that met the inclusion criteria or for which insufficient data were available in the title and abstract to make a decision were selected for full analysis. Authors of the studies were contacted in case of missing data (e.g., data provided in graphs); these studies were only included if the authors provided the missing information. Data extraction was conducted by consensus between the two researchers who conducted the collection.

The risk of bias for all the included studies was assessed based on The Cochrane Collaboration's tool,11 and the methodological quality was adapted from another systematic review of antimicrobial monomers used in dental materials.13 The parameters used for the evaluation of methodology assays were discussed by the researchers involved, and judgment was carried out by group discussion. Assessment of risk of bias was conducted using Review Manager 5.3 software.

After database screening [Pubmed (16), Scopus (8), SciFinder (27), Web of Science (9), Scielo (0), Google scholar (34), and ProQuest (3)] and removal of duplicates, 89 studies were identified. After title and abstract screening, 29 studies remained, and this number was reduced to 14 after careful examination of the full texts. The last electronic search was conducted on December 4th, 2017. Fig. 1 shows a flowchart summarizing the selection process of articles and patents.

Fig. 1.

Flow chart.

(0.29MB).

Of the 89 articles initially recovered from all databases, 75 articles were excluded because they were not related to the antimicrobial activity of PE and failed to satisfy the selection criteria. A total of 60 articles were excluded after reading the title and abstract, and 12 were excluded after screening the full text because they tested properties other than antimicrobial pathology for humans or animals. One study tested an intestinal protozoan parasite that causes diarrhea in both humans and domestic animals14; one article used an agent accelerating the growth of plants and the development of roots.15 PE has been studied as a repellent and insecticide against insect pests to crops,5 as an antimicrobial agent for wood fungi, and as a weed control agent.4,6,16–19 Two studies used the PE as phenol source and tested the antibacterial activity of separate components.20,21 In addition, two articles were excluded as the researchers featured no access to full text versions,22,23 and one article was a review study.24

In the patent databases, INPI (0), Google patents (0), Espacenet (7), patents on line (44), USPTO (11), and WIPO (7), the search strategy initially retrieved 69 patents. After removal of duplicates, this number was reduced to 37. A total of 25 patents were excluded after reading the titles and abstracts (Fig. 1) as they were not related to PE. Of the remaining 12 patents, 1 patent was excluded because it reported a promoter of environmental properties in soil, plants, and fish.25 Twelve patents were included in the analysis.

Table 2 describes the microorganisms tested, the source of PE, concentrations, methodologies used and the application area for each study from articles, and patents selected in the search. Table 3 shows the data of the patents included in this review.

All articles were published between 1998 and 2014. Most studies showed different cellulose sources to burn and generate different types of PE for its test as an antimicrobial agent. Several sources were commercial extracts,1,7,26–33 and others were experimental extracts.19,34,35 One study tested microbial strains isolated from dogs and cats.26 One article analyzed four strains of pathogenic Candida albicans, which were isolated from patients suffering from urinary tract infection (two strains), vaginitis, and onychomycosis (one each),7 and one tested another C. albicans strain.30 One study tested PE as an agent to prevent viral epidemics in agricultural and human environments.27 Various studies reported PE as a food preservative.28,30,31,33,36,37 Only one in vivo study used Salmonella-infected Balb/c mouse model.35 All in vitro studies reported the bacterial or antifungal activity of PE. The methods used for the tests included disk diffusion and minimum inhibitory concentration. The growth profile of the bacteria was examined via time-kill and viral inactivation assays.27

Regarding patent documents, the data showed 11 patents deposited from 1981 to 2009. Antibacterial, antifungal, and preservative proprieties of PE were found in these patents, which claimed PE incorporation into additives for the treatment of animal feedstuffs,38 fiber-reinforced cellulosic food casing,39 compositions for food preservation,40–42 carbon fiber,43 cosmetic composition,44 biodeodorizing agent,45 antimicrobial compositions,46 pharmaceutical composition for symptoms of atopic dermatitis,47 and compositions for oral microbes.48

Studies on PE in patents were older than articles. In 1981, PEs incorporating selective additives were used as antifungal and antibacterial preservative agents for the treatment of animal feedstuffs.38 In 1983, PE was used in a fibrous reinforced cellulosic food casing with PE to provide antimycotic quality in the casing without separating antimycotic agent.39 In 1991, a PE derivative product was applied to wieners post-peeling and before packaging to inhibit L. monocytogenes reinoculation and extend the shelf life of the wieners without adversely affecting their taste and/or edibility.41 In 2004 and 2008, other patents developed methods and compositions for antimicrobial treatment of food products.40,42

The antimicrobial property of PE was used for the development of carbon fiber by soaking carbon fibers in a heat treatment solution mainly comprising PE from wood or bamboo.43 PE was also used as biodeodorizing agent composition containing a culture solution; the PE solution showed an excellent antimicrobial activity against putrefactive or pathogenic bacteria and a long-lasting deodorizing effect.45

Two studies developed antimicrobial products for skin; a cosmetic composition containing a PE solution featuring an antimicrobial activity and antioxidant activity as a main component was obtained and considered suitable for skin protection.44 A pharmaceutical composition for ameliorating symptoms of atopic dermatitis comprising refined PE was proven to avoid side effects, such as skin irritation and bad smell, by removing harmful materials and toxicity and improving antimicrobial activity.47

One patent developed a silver-ionized PE to enhance antimicrobial activity of PE against pathogenic bacteria: E. coli, Salmonella sp., Bacillus sp., Staphylococcus sp., Vibrio sp., Aspergillus sp., Fusarium sp., Tricoderma sp., and Candida sp.46 Another patent used PE against pathogenic microorganisms of oral cavity and provided compositions and methods to inhibit the growth of oral microbes and promote oral care.48

The examination of PE as an antimicrobial agent, the broad spectrum of its properties, with and without enhancing additives, was evaluated against heat-resistant, spore-forming, aerobic bacilli, gram-negative bacillus associated with avian, and human enteritis. Various saprophytic molds (mycelial fungi) are associated with animal feeds, spoilage and, in several instances, human and animal mycotoxicoses. In each instance, our findings indicate that PE effectively and irreversibly reduces natural and/or experimental microbial contaminants associated to animal feedstuffs.38

The cellulose sources reported in the studies included in this systematic review comprised woods of hickory, mesquite, apple, pecan, moso bamboo (Phyllostachys pubescens), Rhizophora apiculata, walnut tree branches, and E. ulmoides olive. Branch and rice hull and five studies presented no information about these cellulose sources.

Further in vivo studies are required for the development of new products using PE and the investigation of its possible use as an antimicrobial agent against resistant pathogenic microorganisms and development of pharmaceutical medicines. Many pathogenic microorganisms are tested for use as food preservative; this extract demonstrated a remarkable antimicrobial potential but was not identified in in vivo studies for humans or clinical assays.