Abstract
During the present time, anti-microbial features of copper (Cu) and zinc oxide (ZnO) nanoparticles (NPs) are extensively used to combat the growth of pathogenic microbes. CuNPs and ZnONPs are recurrently used in cosmetics, medicine and food additives, and their potential for toxic impacts on human and ecosystem is of high concern. In this study, the fate and toxicity of 16- to 96-nm-ranged biosynthesized copper (Bio-CuNPs) and zinc oxide (Bio-ZnONPs) was assessed in male Wistar rats. In vivo exposures of the two nanoparticles are achieved through two different administration routes namely, intraperitoneal (i/p) and intravenous (i/v) injections. The three different concentrations, no observable adverse effect concentration (NOAEC), inhibitory concentration (IC50) and total lethal concentration (TLC), were appraised at the dose range of 6.1 to 19.82 μg/kg and 11.14 to 30.3 μg/kg for Bio-CuNPs and Bio-ZnONPs respectively, for both i/p and i/v routes on 14th and 28th day of observation. These dose ranges are considered based on the previous study of antibacterial dose on multidrug-resistant pathogenic bacteria. In this study, we investigated the toxic effect of Bio-CuNPs and Bio-ZnONPs on animal behaviour, animal mass, haematologic indices, organ indices and histopathology of liver, spleen, kidney and brain organs. We found that i/v and i/p administration of Bio-ZnONPs in three different doses did not cause mortality and body weight was slightly reduced up to second week of administration compared with the vehicle control group. At the dose ranges of 11–16 μg/kg (i/v) and 24–30 μg/kg (i/p), no significant changes were observed in the serum creatinine level as well as serum ALT, serum AST level and ALP level which were 40.7 mg/dl, 37.9 IU/L and 82.4 IU/L normal as compared to vehicle control on 14th and 28th day of observation. These findings are confirmed in liver, kidney and spleen indices and histopathology studies. Furthermore, liver and kidney injury occurred when the concentrations of Bio-CuNPs were at 9.5 μg/kg (IC50) and 11.7 μg/kg (TLC) for i/v route of administration. Similarly, increase in serum ALT (67.7 mg/dl), AST level (70 IU/L) and ALP (128 IU/L) was also observed. And the body weight was significantly lower than in the control group after 14th day, and there were statistically significant differences observed by this route; interestingly, the toxicity of Bio-CuNPs in serum is prolonged (up to 28th day). Effect of Bio-CuNPs through i/p route was considerably low as compare to the control. Results of the present study revealed that Bio-ZnONPs have no effect on kidney and liver function biomarkers (both i/v and i/p) as compared to Bio-CuNPs.
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Background
Certain metals are required for the normal physiological functions in living organisms. Since the past decade, there has been increase in the use of metal based NPs in bio-medical applications, exponential use of NPs alerts the safety concerns to reduce and/or prevent NP induced adverse effects on the living system [1]. Among NPs, Cu and ZnO are generally found in the food supplements and human body [2, 3]. Unique physiochemical properties of Cu and ZnONPs attain functional applications in physiological metabolic processes, thus increasing their commercial value in industries [4,5,6]. However, adverse effects, including hemolysis, gastrointestinal distress, and liver and kidney damage were observed upon excess intake of Cu and ZnONPs [7].
Particularly, the absorption of CuNPs is readily takes place after the ingestion, inhalation and the dermal exposure [8, 9], significantly through the gastrointestinal tract [8, 10]. CuNPs target mucosal cells and retain inside by bonding with metallothionein or glutathione [11]. It is stored primarily in the liver, brain, heart, kidney and muscles. It was reported, 98% of Cu binds with Ceruloplasmin, a serum protein which lead to cellular toxicity. [12, 13].Cu is a catalytic inducer of superoxide radicals, hydroxyl radicals and hydrogen peroxide via the Haber-Weiss reaction [14], higher concentrations of Cu may cause oxidative induced stress.
Based on the extent of solubility ZnONPs were being considered as separate group of NPs within the metal oxide NPs [15]. Zinc element is found in human body and ZnONPs are known to be of lower toxic [3]. However, excessive zinc is reported to induce toxic effects [16]. Release of metallic cations Zn2from ZnONPs are also proved to be toxic in micro-organisms and rodents [17]. ZnO NPs might enter via different routes to reach blood flow and induce adverse impacts on organs [18]. Preliminary results indicated ZnONPs affected organ systems may show inflammation, altered heart rate and functions, and oxidative stress [19, 20]. According to [21], inhalation of 20 nm ZnONPs (2.5 mg/kg bw) by rats twice a day resulted in an increased Zn content in the liver after 12 h and in kidneys after 36 h.
Increased awareness towards nanotoxicity, studies have been reported on the in vivo toxicity of CuNPs and ZnONPs for intranasal instillation [22, 23], intratracheal instillation [24, 25] and oral administration [26,27,28], dermal exposure [29, 30]. In order to evaluate the toxicity intravenous (i/v) and intraperitoneal (i/p) administration needs has to be performed. To our knowledge, minimal reports are available on CuNPs and ZnONPs toxicity for intravenous and intraperitoneal administration. Moreover, the toxicological mechanism and tissue distribution of the two NPs have not yet been systematically studied on following i/v and i/p injection.
Hereby, we demonstrated the toxicity of 16-96 nm ranged biosynthesized CuNPs and ZnONPs in male wistar rats through intraperitoneal (i/p) and intravenous (i/v) injectionsat the desired on 14th and 28th day of observation.
Method
Biosynthesis of bio-CuNPs and bio-ZnONPs
Biological synthesis of CuNPs and ZnONPs from non-pathogenic Enterococcus faecalis was adapted by extracellular enzymatic method [31, 32]. Further, the shape and size of synthesized nanoparticles were confirmed using field emission scanning electron microscopy (FeSEM) and transmission electron microscopy (TEM).
In vivo studies
Experimental animals and animal husbandry
Specific disease-free, 12- to 13-week-old male Wistar rats were purchased from Mahaveera Enterprises, Hyderabad, India. Animals were selected within a weight range of 160–200 g for each group and acclimatized for 1 week prior to the initiation of treatment, and health status of rats was monitored daily. The animals were housed under standard conditions of temperature (24 ± 1 °C) and relative humidity (55 ± 10%) respectively, in 12-h light/dark cycles. During treatment, animals were housed in cages with stainless steel mesh lids. Animals were fed with commercially available standard pellet diet (VRK Nutrition Solutions, Sangli, Maharashtra, India Ltd.). Drinking water was supplied to the animals, ad libitum.
Toxicity studies were performed at Luqman College of Pharmacy, Kalaburagi, India. Animal handling was performed according to Good Laboratory Practice. The study protocol was approved by Institute Animals Ethics Committee (Approval number: 346/CPCSEA).
Preparation and Administration of Bio-Cu and ZnONPs
The stock suspensions of Bio-CuNPs and Bio-ZnONPs (50 mg/ml) were prepared by dissolving separately in double distilled water for overnight and were filtered using 0.22 μ syringe filters. Filtrates are used to prepare the working standard ranging from 1.25-175 μg/ml concentration.
Animals were divided into three groups of three different concentrations for each nanoparticle type. Considering six rats/group for intravenous route (coded as experiment A set) and six rats/group for intraperitoneal route (coded as experiment B set), as per Tables 1 and 2. In both experiment sets group A served as control (vehicle distilled water).
Observation and examination items
Clinical signs
During the test, post treatment observation was done once in a day to monitor the signs of clinical toxicity and/or death.
Feed and water consumption
Feed and water consumption was recorded daily after the starting date of treatment, was calculated from the differences between the supplied amounts and the remaining amounts.
Animal behaviour and body weight
Every two days after injection, rats were weighed and assessed for behavioral changes.
Hematological indices
Using a standard saphenous vein blood collection technique, blood was drawn for hematology analysis (using potassium-methylenediaminetetraacetic acid collection tubes). According to the standard hematologic analysis 300 μl of blood was collected from the rat and on 14 and 28 days standard hematologic parameters, i.e, platelet count, hematocrit, hemoglobin, red blood cell count, and white blood cell count were analyzed [33].
Biochemistry panel analysis of serum
To determine the serum biochemical levels including the alanine aminotransferase (ALT/GPT), creatinine (CRE), aspartate aminotransferase (AST) and alkaline phosphatase (ALP), control and treated rats were sacrificed and whole blood samples were collected for centrifugation (3000 rpm) for 15mins. Assessment was performed by an automatic biochemical analyzer for 14 and 28th day’s samples [34].
Detection of organelles weight
After 14 and 28 days, the rats were anesthetized by ether with phosphate-buffered saline and were dissected. Organs of the control and treated groups were harvested immediately. Heart, lung, thymus, brain, kidney, liver and spleen were separated carefully and washed with sodium chloride solution and rinsed with ice-cold deionized water and dried with filter paper. Morphology and color of dissected organs were investigated and weight of each organ was measured. To examine the grade of changes explicitly caused by Bio-Cu and ZnONPs, the Organ index (O X ) was calculated separately by using formula [35]:
Where Organ Index (OX) may change as:
Heart index (HX), Liver index (LiX), Spleen index (SX), Lung index (LuX), Kidney index (KX), Thymus index (TX), Brain index (BX).
Histology
One rat from each group including control was fixed with 10% buffered formalin following phosphate-buffered saline exsanguinations. A small piece of liver, kidney, spleen and brain was fixed by 10% formalin and embedded into paraffin. Paraffin blocks were sectioned and processed for hematoxylin and eosin staining. Stained sections were observed using bright field microscopy [36].
Statistical analysis
All data are expressed in mean ± SD of the mean of the three independent experiments; each was carried out in triplicate, N = 6 rats per group.
Results and Discussion
Synthesis of Bio-CuNPs and Bio-ZnONPs were carried out by extracellular enzymatic method during exposure of reactants to Enterococcus faecalis supernatant. FeSEM analysis of Bio-CuNPs and Bio-ZnONPs can be seen with size ranging from 1 to 100 nm in distribution (Additional file 1). TEM analysis reports the presence of biosynthesized CuNPs and ZnONPs with core shell morphology of size 12–90 nm and spherical in shape for CuNPs [31] and ZnONPs ranging from 16 to 96 nm [32] (Additional file 2).
Evaluation of Bio-Cu and ZnONPs on male wistar rats was investigated with no sign of mortality upon NP treatment. Furthermore, after the treatment and till the end of experiment duration frequent examination of white feces was monitored after i/v administration of Bio-CuNPs at 9.5 to 11.5 μg/kg dosage. Between third and fourth week, Bio-CuNPs’ treated rats have showed significant rise in feed and water consumption for i/v was 9.5 μg/kg (IC50) and 11.5 μg/kg (TLC) whereas for i/p route(dose range: 24.8 to 30.3 μg/kg) and control group rats from 3rd to 4th week.Variation in the body weight of rats after i/v and i/p administration of Bio-CuNPs and Bio-ZnONPs was shown in Tables 3 and 4.Reduction and increase in the body weight are valuable indicators in assessing the toxicity of a test sample [37]. Previous reports evidenced in toxicity studies on 13.5 nm gold [33] and 100 nm silver [38] NPs effect on body weight by i/v injection was less than i/p and oral administration. According Rhiouani et al., the low decrease in weight after 4 days of treatment in all of the treated groups can suggest adverse effects of toxic substances on the animals [39].
It can be seen that i/v and i/p administration of Bio-ZnONPs in the three different doses (NOAEC, IC50 and TLC) body weight was slightly reduced up to second week of administration compared with the control group. However, after 14th day body weight was regained. In case of i/p administration, reduction in body weight was induced by Bio-ZnONPs (30.3 μg/kg) at total lethal concentration and was lower than control group, thus indicating trivial toxicity via i/p route over the i/v route(Table 4, Fig. 1a). Similarly, rats treated with Bio-CuNPs, at 9.5 μg/kg and 11.7 μg/kg concentration via i/v route slight reduction in the body weight was noticed. Till 14 days treatment with Bio-CuNPs no sign adverse effects on growth and body weight gain were observed. Body weight variation within 28 days at a dose of 11.7 μg/kg (i/v route) is shown in Table 3. After 14th day of treatment, it was found considerable decrease in body weight via i/v route when compared with the control group. Thus, indicates toxicity of Bio-CuNPs via this route (Fig. 1b). Bio-CuNPs treated rats via i/p route administration induced minor decrease in body weight and no sign of mortality was observed in both i/p and i/v routes. Therefore, i/p injections induced lower toxicity (shown in Table 4 and Fig. 1a).
Hematology indices
Estimation of hematologic parameters such as, RBC count, WBC count, platelet count, hemoglobin level and blood clotting time are the important entities to measure the toxicity of treated NPs. For day 14 and 28, concentration-dependent hematology results arepresented in Tables 5 and 6 for i/p and i/v route of administration. Dosage of Bio-CuNPs at 9.5 μg/kg (IC50) and 11.7 μg/kg (TLC) via i/v route has shown reduced RBC count in contrast to Bio-ZnONPs. However, concentration-dependent trend has not been noticed. For rats treated with Bio-ZnONPs through i/v route of administration, hemoglobin level, platelet count, and white blood cells have changed, but no significant difference is observed among all three concentrations (NOAEC, IC50 and TLC). But in case of i/p route of administration, significant decrease and changes in red blood cell count, white blood cells, hemoglobin level and platelet count has been found on 14th day of observation (Table 5) as compared to the control and Bio-CuNPs treated. Surprisingly, hematologic effects are found to be normal on 28th day (Table 6).
The hematologic effects of the different injection methods (i/v, i/p) for the two different Bio-NPs on 14th and 28th day of observations are diverse. It can be observed that hemoglobin, red blood cells, white blood cells and platelets decrease via i/v route in Bio-CuNPs treatment and via i/p route in Bio-ZnONPs treated rats. But the significant decrease in RBC counts was observed. This indicates that the different injection routes did not induce significant differences in platelet count, hemoglobin, or white blood cells except in rats injected with Bio-CuNPs (i/v route). Red blood cells show a significant difference after i/p and i/v injection (as shown in Tables 5 and 6).
Biochemical assay of serum
Serum creatinine is waste product; higher creatinine production indicates kidney damage. Bio-ZnONPs (i/v route: dosage of 11-16 μg/kg, i/p route: dosage of 24-30 μg/kg) not significantly affected serum creatinine level when compared with control on 14th and 28th day. (Tables 7 and 8, Fig. 2a, b). Rats treated with Bio-CuNPs (i/v route: dosage of 06-12 μg/kg) have showed increase in serum creatinine level to 2.3 mg/dl when compared with control. However,i/p route of injection did not showed significant changes (Tables 7 and 8). The blood serum has large number of enzymes but to assess the normal and pathological symptoms of liver, alanine transaminse (glutamate pyruvate transaminase) and aspartate transaminases (glutamate oxalate acetate transaminase) are useful. Aspartate transaminase is of mitochondrial origin present in large quantities in liver, heart, kidney and skeletal muscles. Serum alkaline phosphatase is a globulin enzyme of low molecular weight, found in higher concentration in bones, hepatobiliary tract and kidney. The activity of this enzyme can be determined by the estimation of organic phosphate liberated from the glycerol phosphate. The serum level of the enzymes was increased in both hepatocellular and obstructive Jaundice. In the i/v route of administration, Bio-ZnONPs (40.7 mg/dl, 37.9 IU/L, 82.4 IU/L) no significanteffects on serum ALT, serum AST and ALP levels as compared with control. Although i/p administration showed significant increase in ALT, AST and ALP level as compared with control at 14th and 28th day (Fig. 2a and b). Results of toxicity study on serum showed Bio-ZnONPs no changes in the levels of creatinine, ALT, AST and ALP levels for i/v route till 28 days.
In contrast, rats treated with Bio-CuNPs through i/v route, showed significant increase in serum ALT (67.7 mg/dl), AST level (70 IU/L), and ALP (128 IU/L). Effect of Bio-CuNPs through i/p route was considerably low compared to control. The difference of the results could be attributed to difference in the dosage routes, toxicity of nanoparticles as well as the duration of administration. We found Bio-ZnONPs have no effect on kidney and liver function biomarkers (both i/v and i/p) as compare to Bio-CuNPs.
Detection of organelles weight and histological study
Changes in the organ weights of rat at different Bio-NPs doses, illustrate the adverse effects of NPs on organs. It can be seen that the weights of the heart, liver, spleen, lung, kidneys, and brain are decreased in rats when treated with Bio-ZnONPs as depicted in Tables 9 and 10. Furthermore, consideration of the organ reaction and grade of changes were examined by calculating organ index (OX) of each organ separately. The organ index for heart, liver, spleen, lung, kidneys, brain and thymus are presented in Tables 9 and 10.
Difference in the weight of spleen and thymus were observed after i/v and i/p administration in Bio-CuNPs and Bio-ZnONPs treated rats. On 14th day, Bio-ZnONPs has shown decreased spleen index via i/p injection, and increased by i/v administration (Table 9). In case of Bio-CuNPs treated rats via i/v administration showed significant reduction in spleen index on 14th (0.265) and 28th day (0.49). Thus indicating, the immune system has been affected by i/v Bio-CuNPs administration and i/p Bio-ZnONPs administration. In case of, i/p Bio-ZnONPs administration, immune system of rat is recurring to the normal state after 14th day and proves the effect is not prolonged. Taken together with the previous body weight variation, it seems that i/v administration route of Bio-CuNPs can affect the heart, liver, lung, kidneys, and brain; furthermore it might damage the immune system. From Fig. 3a, it implies spleen and thymus are main target of organs by Bio-CuNPs.
In case of i/v and i/p Bio-CuNPs treated groups obvious effects on organ index has been observed at both IC50 and TLC doses. Moreover, of the two different administration routes, the intraperitoneal injection show the modest toxicity in Bio-ZnONPs treated groups and highest toxicity in Bio-CuNPs treated groups. Efficient drug absorption by i/p injection was known to be rapid due to the dense blood vessels and lymph in the murine peritoneum [40]. Correspondingly, the intravenous injection shows the least toxicity in Bio-ZnONPs treated groups and highest toxicity in Bio-CuNPs treated groups.
Toxicological changes in rats
We tried to scrutinize the effects of toxicity, at different doses and time intervals of Bio-NPs. Tissues treated with Bio-ZnONPs (i/v route: dosage range 11-16 μg/kg, i/p route: dosage range 24-30 μg/kg) showed no changes in the liver, kidney, spleen and brain when compared with control tissues (Figs. 4, 5, 6 and 7). Necropsy observations (autopsy: dissective examination of dead rat) specified that all organs of Bio-NPs treated rats exhibited the anatomic features (e.g., characteristics of color, shape, and size) to be expected based on their appearance in untreated animal. As compared to Bio-ZnONPs, Bio-CuNPs treated rats showed more significant changes in anatomic features of kidney, liver, spleen and brain tissues in contrast to control (Figs. 4, 5, 6 and 7).
Bio-CuNPs induced damages via i/v route administration and showed dose-dependent trend in tissues. At TLC (11. 7 μg/kg) concentration, Bio-CuNPs showed severe damage to the liver and kidney tissues of Wistar rats. In addition, Bio-CuNPs treated via both i/v and i/p route have induced necrosis of glomerular cells (glomerular atrophy), bowman capsule and proximal tubular in group 14th and 28th day rats (Fig. 4b, e, c and f) when compared to the untreated control. Glomerular necrosis is due to immunological reimbursement, but tubule damages are mostly due to toxic effect of the NPs. The tubular damage caused by the toxic effects of Bio-CuNPs through both i/v and i/p route also increased the glomerular pressure and causes glomerular atrophy.
Normal control group showed normal histological structure of hepatic lobule and the central vein which is surrounded by normal hepatocytes (Fig. 6). Bio-CuNPs treated via i/p route (19.82 μg/kg) showed mild histological changes including Kupffer cell activation both in 14th and 28th day observation (Fig. 6b, e). Rats treated with Bio-CuNPs via i/v route showed severe changes including cytoplasmic vacuolization of central vein surrounded hepatocytes and hepatic haemorrhage for 14th day observation (Fig. 6c). Surprisingly, 28th day group showed moderate changes including fatty changes of hepatocytes and pyknosis of hepatocytic nuclei (Fig. 6f). Liver tissue treated with Bio-ZnONPs, for 14th day of i/p route administered group, showed moderate changes demonstrated by fatty changes of hepatocytes (Fig. 6i). Bio-ZnONPs’ treated groups showed slight improvement, and significant hepatoprotective activity was observed in 28th day as compared to 14th day (Fig. 6l). On 14th day onwards, restoration of normal hepatic architecture has taken place in Bio-ZnONPs’ treated animals.
A decline in the spleen cell (red pulp), whereas an increase in lymphocytes (white pulp), in spleen tissue extracted from rat treated with Bio-CuNPs via i/v route (Fig. 5c, f) was noticed. In primary observation, accretion of Bio-CuNPs in the spleen was noticed in the red pulp and was related with a modest loss of cell mass; reduced cell mass was obvious on the 28th day time point when compared with 14th day of i/v administration (Fig. 5f), whereas minor changes were observed in red pulp depletion when rats were treated with Bio-CuNPs via i/p route on both 14th and 28th day time point. Structural changes were not seen in the white pulp or in splenic blood vessels (arteries or venous sinuses) and intravascular erythrocytes (Fig. 5b, e). No morphological changes have been found in spleen tissues treated with Bio-ZnONPs (Fig. 5). The H&E-stained brain sections of rats, treated (i/v and i/p) with NPs, showed no changes in brain region, olfactory bulb (perivascular localization) and the choroid plexus and ependyma of the lateral ventricles (Fig. 7).
Conclusion
Animal toxicity studies using 16- to 96-nm-ranged biosynthesized copper (Bio-CuNPs) and zinc oxide (Bio-ZnONPs) was assessed in male Wistar rat at the dose range of 6.1 to 19.82 μg/kg and 11.14 to 30.3 μg/kg respectively for both i/p and i/v routes on 14th and 28th day of observation. We observed no mortality and normal behaviour in the animals treated with Bio-CuNPs and Bio-ZnONPs in their specific dose range. The results also verified the Bio-CuNPs and Bio-ZnONPs at low concentrations do not cause identifiable toxicity even after their breakdown in vivo over time. Increased concentrations of these Bio-NPs induce weight reduction, but no significant statistical difference was observed for Bio-ZnONPs’ treated animals. In the case of i/v and i/p Bio-CuNPs’ treated groups, obvious effects on organ index have been observed at both IC50 and TLC doses. Moreover, of the two different administration routes, the intraperitoneal injection shows the modest toxicity in Bio-ZnONPs’ treated groups and highest toxicity in Bio-CuNPs’ treated groups. Correspondingly, the intravenous injection shows the least toxicity in Bio-ZnONPs’ treated groups and highest toxicity in Bio-CuNPs’ treated groups. Considering all the results of studies, targeting Bio-ZnONPs by intravenous injection is promising for possible biomedical application.
Abbreviations
- ±:
-
Plus or minus
- ALP:
-
Alkaline phosphatase
- ALT:
-
Alanine aminotransferase
- AST:
-
Aspartate aminotransferase
- Bio-CuNPs:
-
Biogenic copper nanoparticles
- Bio-ZnONPs:
-
Biogenic zinc oxide nanoparticles
- BX :
-
Brain index
- CRE:
-
Creatinine
- Cu:
-
Copper
- FesEM:
-
Field emission scanning electron microscopy
- H&E:
-
Haematoxylin eosin
- Hb:
-
Haemoglobin
- HX :
-
Heart index
- i.e.:
-
That is
- i/p route:
-
Intraperitoneal route
- i/v route:
-
Intravenous route
- IC:
-
Inhibitory concentration
- KX :
-
Kidney index
- LiX :
-
Liver index
- LuX :
-
Lung index
- NOAEC:
-
No observable adverse effect concentration
- NPs:
-
Nanoparticles
- Ox :
-
Organ index
- RBC:
-
Red blood cell
- SD:
-
Standard deviation
- SX :
-
Spleen index
- TEM:
-
Transmission electron microscopy
- TLC:
-
Total lethal concentration
- TX :
-
Thymus index
- WBC:
-
White blood cell
- ZnO:
-
Zinc oxide
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Acknowledgements
All the authors gratefully acknowledge the Department of Biotechnology, Gulbarga University, Gulbarga, India, for providing the facilities to pursue this research. We are thankful to Dr. Syed Sanaullah, principal, and Md. Liyakat Ahmed, Luqman College of Pharmacy, Gulbarga, for providing the necessary facilities and support.
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The work was funded by DST-INSPIRE Fellowship (IF130489), Department of Science and Technology, New Delhi, India.
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KCR and AC conceived and preformed the experiments. HHK assisted with the experiments. All authors contributed in interpreting results, arranging tables and illustrations and preparing the manuscript. KCR improved the experimental design and manuscript. All authors read and approved the final manuscript.
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Figure S3. TEM images of (A) Bio-CuNPs and (B) Bio-ZnONPs synthesized from Enterococcus faecalis [41]. (DOCX 901 kb)
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C, A., K Handral, H. & Kelmani R, C. A Comparative In Vivo Scrutiny of Biosynthesized Copper and Zinc Oxide Nanoparticles by Intraperitoneal and Intravenous Administration Routes in Rats. Nanoscale Res Lett 13, 93 (2018). https://doi.org/10.1186/s11671-018-2497-2
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DOI: https://doi.org/10.1186/s11671-018-2497-2