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 CHEMICAL ENGINEERING TRANSACTIONS  
 

VOL. 49, 2016 

A publication of 

 
The Italian Association 

of Chemical Engineering 
Online at www.aidic.it/cet 

Guest Editors: Enrico Bardone, Marco Bravi, Tajalli Keshavarz
Copyright © 2016, AIDIC Servizi S.r.l., 
ISBN 978-88-95608-40-2; ISSN 2283-9216 

Comparative Analysis of Biocompatibility between Poly (L-
lactic Acid) (PLLA) and PLDL Purac® Nanofibers for use in 

Tissue Engineering 

Ana Carolina B. Benattia,b*, Mariana V. Xaviera , Milton F. Macedoa , Ana Amélia 
Rodriguesa , André L. Jardinia , Rubens M. Filhoa , Paulo Kharmandayana,b  
a 
Institute of Biofabrication  - School of Chemical Engineering, University of Campinas, CEP 13081-970, Campinas-SP, 

Brazil 
b 
School of Medical Sciences, Surgery Department, University of Campinas, CEP 13083-970, Campinas-SP, Brazil 

carol_benatti@hotmail.com 

The absorbable polyacid, poly (L-Lactide) (PLLA) is one of the most commonly used and studied materials in 
tissue engineering, for its biocompatibility and biodegradability. This work will show that the PLLA synthesized 
at our laboratory has the same biocompatibility as the PLDL Purac®. The PLLA was synthesized through ring-
opening polymerization and manufactured into nanofibers through the electrospinning process. The 
cytotoxicity of the material was evaluated by the calorimetric MTT assay (Sigma), Live/Dead (Molecular 
Probes), Direct Contact, Elution and Agar Diffusion.The assays were performed using  nanofibers membranes 
made with PLLA and with PLDL Purac®, where the biomaterials were in contact with the fibroblast cell culture, 
in the sense to compare the results between them. For the MTT, Live/Dead and Elution assays the nanofiber 
membranes were incubated with the fibroblast cell culture for 24h, 48h and 72h. For the Direct Contact and 
Agar Diffusion the nanofiber membranes were maintained in contact with the cells for 24h. For the assay 
controls we used DMEM-LG containing 0.5% phenol as the positive control of toxicity CT(+) and for negative 
control of toxicity CT(-) DMEM-LG containing 10% FBS. The ANOVA test was used to measure the MTT 
assay results, and within 24h of exposure, the cells in contact with the PLLA showed a higher proliferation rate 
than CT(-) and PLDL Purac®, being significantly different (p< 0,05). Whatsoever, there were no statistically 
significant differences between the PLLA, the PLDL Purac®,  and the CT(-) after 48h and 72h of culture 
(p>0.05). The morphology of the cells in contact with both biomaterials was also considered normal, showing 
no signal of cytotoxicity. The high rates of proliferation and viability of the cells in contact with the PLLA, 
shown by the biocompatibility assays, demonstrate that the PLLA is a biocompatible material. The PLDL 
Purac® exhibited similar results, as expected. Those findings show that the PLLA synthesized has the same 
biocompatibility as the PLDL Purac®. Thus, the PLLA synthesized in our laboratory is a high quality 
biomaterial that can assist in the manufacturing of nanofibers that can be adapted for different biomedical 
applications. 

1. Introduction 
Polymers constitute a very wide-ranging class of biomaterials, with diverse uses in the biomedical field. These 
biomaterials must show suitable mechanical properties as well as biocompatibility characteristics, for use in 
the human body. Therefore, they should not present any local or systemic adverse biological response. PLA is 
known for its outstanding biocompatibility and mechanical properties. It also features a diversification of 
applications, since simple changes in its physical and chemical structure may make it useful in different areas. 
It can be used as a combination of L-lactic (PLLA) and D, L-lactic (PLDL) acid monomers, being the latter 
rapidly degraded without formation of crystalline fragments during this process (Fukushima et al. 2008). 
Therefore, PLA and its copolymers are materials commonly used in tissue engineering. Whereas one of the 
goals of tissue engineering is to help improve tissue regeneration, the use of nanofiber membranes, combined 
with their potential for biodegradation, could be of interest for various biomedical applications, since they 
mimic the natural extracellular matrix (ECM), providing an excellent environment for the cells to attach, grow 

                                

 
 

 

 
   

                                                  
DOI: 10.3303/CET1649034 

 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 

Please cite this article as: Benatti A., Xavier M., Macedo M., Rodrigues A.A., Jardini A., Filho R., Kharmandayan P., 2016, Comparative analysis 
of biocompatibility between poly (l-lactic acid) (plla) and pldl purac® nanofibers for use in tissue engineering, Chemical Engineering 
Transactions, 49, 199-204  DOI: 10.3303/CET1649034

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and migrate, thus improving the rate of tissue regeneration (Dong et al. 2009). In the present study, we 
synthesized PLLA in our laboratory through ring-opening polymerization and manufactured nanofiber 
membranes with it. To assay the biocompatibility of the material, we performed different biocompatibility 
experiments, and we compared it with PLDL Purac® nanofibers membranes, a PLA co-polymer commonly 
used in tissue engineering, with excellent biocompatibility characteristics (Leiggener et al. 2006). 

2. Materials and Methods 

2.1 Manufacturing of PLLA and PLDL nanofibers 
For electrospinning, the biodegradable and biocompatible polymers PLDL Purac® and Poly(L-lactic acid) 
(PLLA) were used. PLLA was synthesized in our laboratory as described by Lopes (2014). In the nanofibers 
manufacturing process, the PLLA was dissolved in acetone and chloroform, and PLDL in acetone, both at 
analytical grade. The solution was then loaded in a 10ml syringe, connected to a polyamide cylinder, attached 
to a 0.7mm hypodermic needle as a nozzle. The flow rate of the jet (8ml/h) was controlled by using a syringe 
pump. To charge the solution, a 15kV high voltage power-source was used. The distance between the needle 
and the collector plate was of 17cm and the time of electrospinning of 2h. 
 
2.2 Cell Incubation 
The Vero cells (fibroblast) were seeded (3 x 106 cells/mL) in a culture plate and incubated with 5% CO2 at 
37ºC for 24h. Then, PLLA and PLDL nanofibers were added in wells and cultured for different times. DMEM-
LG containing 0.5% phenol and 10% FBS were used as the positive control CT(+) and negative control CT(-) 
for toxicity, respectively. All experiments were performed at least in triplicate (n=3). 
 
2.3 MTT  
The modified Mosmann (1983) method was chosen to perform the MTT assay. For this assay, after periods of 
incubation, the MTT solution (0.5 mg/mL Sigma) was added, and after 4h of incubation it was withdrawn and 
200 µl of dimethyl sulphoxide (DMSO) was added to determine the absorbance values, at an absorption 
wavelength of λ = 595 nm (FilterMax F5 Multi-Mode Microplate reader, Molecular Probes). The resulting 
absorbance values were expressed as optical density (OD) (mean value ± standard deviation). The 
comparison between the values was made through parametric data analysis One-way ANOVA. Analysis with 
p < 0.05 were considered significant. Analyzes were performed by using StatView software (SAS Institute Inc., 
Cary, NC, USA). 
 
2.4 Elution  
The elution assay is a quantitative method designed to show the presence of toxic material eluted from a test 
sample and the effects on the fibroblast cells cultured in the presence of the extract. For this assay, the 
materials were incubated in culture medium for 48h. After this period, the extract obtained from incubation of 
materials was inoculated with the fibroblast cells, prepared as mentioned in item 2.2. After various incubation 
periods (24, 48 and 72h), the extract was removed and a calorimetric assay was performed, as mentioned in 
item 2.3. 
 

2.5 Live/Dead® 
The qualitative fluorescence assay kit Live/Dead® (Molecular Probes) was used to qualify the fibroblast 
viability. After the incubation time, the cells were washed with 200 µl of PBS and treated with a solution of 
Calcein AM and Ethidium homodimer-1 (EthD-1) according to the manufacturer’s instructions. The cells were 
incubated at 37°C for 30 min, then washed with PBS and observed by inverted fluorescence microscopy 
(Nikon E800) with a specific program (Image Pro-Plus software). 
  
2.6 Direct Contact  
For direct contact assay fibroblasts were cultured into a high confluence layer in a 24 wells plate. Then, the 
culture medium was removed and replaced with fresh one. The nanofiber samples of PLLA and PLDL were 
placed onto the culture and incubated for 24h, with 5% CO2 at 37ºC. After this period, the materials and 
culture medium were removed from the wells. The remaining cells were fixated with alcohol 70% and then 
stained with Toluidine Blue (TB) and Xylidine Ponceau (XP). The stain only works on the living cells, and thus, 
the toxicity of the material is indicated by the absence of stained cells around the material. 
 
2.7 Agar Diffusion 
The agar diffusion assay is a qualitative test designed to show toxic effects of the material on cell morphology. 
A near confluent layer of fibroblasts was prepared in a 6-well culture plate. The medium was removed and the 
cells covered with a solution of 2% agar, which contained vital stain. While the agar solidified, the cells 
dispersed through it. The PLLA and PLDL nanofibers were then placed onto the surface overlaid of the agar 
and incubated for 24h at 37 ºC. Latex was chosen as positive control of cytotoxicity CT(+) and Teflon as the 
negative control of cytotoxicity CT(-). The live cells take up the neutral red vital stain and retain it, while the 

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dead cells do not. Thus, the toxicity of the material were evaluated by the loss of vital stain under and around 
the material, allowing differentiating the viable from the lysed cells. 
 

3. Results and Discussion 
3.1 Cytotoxicity by MTT assay 
Cytotoxicity tests were performed to study the polymer biocompatibility. In this study, we chose the MTT assay 
where the metabolic activity and the rate of cell growth indicated the degree of cytotoxicity of the PLLA and 
PLDL in the cell culture. MTT is a yellow salt that is reduced by mitochondrial dehydrogenase activity of the 
enzyme, resulting in a formazan purple salt. This reduction occurs only in living cells. Thus, cell viability was 
determined by the intensity of purple color, which is proportional to the amount of formazan crystals formed. 
After performing the MTT test, the absorbance values obtained generated the curves below (Figure 1). The 
graph shows the proliferation of fibroblast cells in contact with the PLLA and PLDL after 24, 48 and 72h of 
exposition. 
 

 
 

Figure 1. MTT assay for fibroblast cells cultured with PLLA and PLDL, negative control for toxicity CT(-) and 
positive control for toxicity CT(+) for 24 h, 48 h and 72 h.  

 
According to the ANOVA test, after 24h of exposure, there were statistical differences (p < 0,05) between CT(-
), PLLA and PLDL, with PLLA showing a higher rate of cell proliferation than PLDL and CT(-). Whatsoever, 
there were no statistically significant differences between the PLLA, PLDL and the (CT-) after 48h and 72h of 
culture (p > 0.05). Those results appoint that at the initial exposure time, where the medium is rich in nutrients 
and space for the cells to proliferate, there is a high rate of cellular growth. The presence of the nanofibers 
stimulate the cell development, which explains the higher amount of cells when cultured with the PLLA and 
PLDL nanofibers, than on the CT(-). Those findings show that the synthesized PLLA and the PLDL do not 
present cytotoxic behavior with respect to the fibroblast cells in the evaluated periods, in accordance with the 
MTT studies of Sarasua et al. (2011) and Wu et al. (2014). 
 
3.2 Elution 
The elution assay is a quantitative technique designed to show the incidence of toxic material eluted from a 
test sample into the culture medium. Figure 2 shows the kinetics of the cells exposed to the PLLA and PLDL 
nanofibers. As observed, the positive control of cytotoxicity CT(+) shows a very little presence of live cells. As 
for the negative control CT(-), cells with PLLA nanofibers and cells with PLDL nanofibers, both showed a high 
rate of proliferation at 24h of incubation, with no statistical difference between them, where at 24h of 
incubation there was a high amount of space and nutrients for the cells to multiply. At 48h there was a 
decrease in cell proliferation for CT(-), PLLA and PLDL, probably due to the increasing amount of metabolites 
and the decreased quantity of space and nutrients for the cells. The same happened at 72 h of incubation. 
These findings show that the synthesized PLLA and the PLDL does not negatively affect the fibroblast cell 
viability in the evaluated time periods. 
 

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Figure 2. Elution assay for fibroblast cells cultured with PLLA and PLDL, negative control for toxicity CT(-) and 
positive control for toxicity CT(+) for 24 h, 48 h and 72 h. 

3.3 Viability by LIVE/DEAD® 
The Live/Dead® assay provides a qualitative evaluation of the polymer biocompatibility when in contact with 
the cells. The fibroblast were cultured with the biomaterials at three different times: 24, 48 and 72h, along with 
it controls of toxicity. The calcein present in live cells produces an intense green fluorescence, which is 
determined by the enzymatic conversion of the non-fluorescent cell-permeant agent, calcein AM. EthD-1 
enters cells with damaged membranes undergoing a strong fluorescence enhancement upon binding to 
nucleic acids, thereby producing a bright red fluorescence in dead cells. EthD-1 is excluded by the intact 
plasma membrane of live cells. 
 

 

Figure 3. Live/Dead assay of fibroblast in contact with PLLA and PLDL at different times. A – Positive control 
CT(+). B – Negative control CT(-). C – PLLA nanofibers cultured with fibroblasts. D – PLDL nanofibers 
cultured with fibroblasts. 

 

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Figure 3 presents the results of the Live/Dead assay. Images A show the positive control of toxicity CT(+) 
where the cells were red stained, showing cell death at all times. Images B shown the negative control of 
toxicity CT(-), where, at different times, cells were stained in fluorescent green indicating that the cell 
membrane was intact. Images C show the cells in contact with PLLA for 24h, 48h and 72 h, respectively. They 
all showed normal morphology, as the ones at CT(-); however, at 72h we can see some cells red stained, 
showing that there are some dead cells. Whatsoever, at 72h of incubation, there are less nutrient and space 
for the cells to keep proliferating, with a high amount of metabolites in the culture medium. This can be the 
reason for the appearance of a higher number of dead cells in the culture. The same results were obtained for 
the cells in contact with PLDL, as shown in Images D. Those results show that the presence of PLLA and 
PLDL nanofibers did not affect negatively cell proliferation and morphology, instead improved cell proliferation, 
in line with the results previously shown by Bernstein et al. (2012), who tested PLLA with different formats, 
such as screws and pins through LIVE/DEAD® assay. Hence the qualitative assay of Live/Dead corroborate 
the quantitatively cytotoxicity assay MTT. 
 
3.4 Direct Contact 
The cells were directly exposed to the PLLA and PLDL nanofibers to assay if their presence would cause toxic 
effects on cell morphology. Since only live cells are stained, we can measure the toxicity of the material 
through the lack of stain around the area exposed to the material. Figure 4 presents the results of the assay; 
Images A report the control, where no material was in contact with the fibroblast, showing normal cell 
morphology (A1 and A2). Images B show the cells in contact with PLLA nanofibers and stained with Toluidine 
Blue (B1) and Xylidine Ponceau (B2), both images show a normal cell morphology, indicating that the PLLA 
nanofibers present no toxicity for the fibroblasts. Images C show the cells in contact with PLDL nanofibers and 
stained with Toluidine Blue (C1) and Xylidine Ponceau (C2) indicating that the PLDL nanofibers also present 
no toxicity for the fibroblasts.  

 

Figure 4. Direct Contact assay. Cells in contact with PLLA and PLDL stained with Toluidine Blue and Xylidine 
Ponceau. 

3.5 Agar Diffusion 
The agar diffusion assay is a qualitative test, where one can assay the toxicity of a material from the lack of 
dye around it, since only live cells can be stained. Figure 5 show the fibroblast cells in contact with PLLA, 
PLDL and their respective controls. On image A we can see the lack of dye of the cells in contact with the 
Latex CT(+), showing cell death. On image B, the cells were all stained with vital stain neutral red when in 
contact with the Teflon CT(-), showing that the cells were alive and with normal morphology. Image C show 
the cells in contact with PLLA nanofiber and image D with PLDL nanofibers. On both images, the cells were 
stained, both presenting normal morphology. This demonstrated that both materials do not present any toxic 
effect on cell culture. 

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Figure 5. A – Positive Control of Toxicity (Latex). B – Negative control of toxicity (Teflon). C- Cells exposed to 
PLLA nanofibers. D- Cells exposed with PLDL nanofibers. 

4. Conclusion  

The results of the MTT assay, Live/Dead, Direct Contact, Elution and Agar Diffusion bring to the conclusion, 
that both PLLA nanofibers and PLDL® nanofibers do not present toxic effect on fibroblast cell cultures. 
Moreover, there were no statistical differences between the quantitatively results of PLLA and PLDL® on the 
MTT and Elution assays. This show that the PLLA synthesized in our laboratory has the same biocompatibility 
characteristics than the PLDL®, a material available on the market.  

Acknowledgments  

The authors wish to acknowledge the financial support provided by the Scientific Research Foundation for the 
State of São Paulo and National Council for Scientific and Technological Development. 

Reference 

Bernstein A., Tecklenburg K., Südkamp P., Mayr H.O., 2012, Adhesion and proliferation of human osteoblast-
like cells on different biodegradable implant materials used for graft fixation in ACL-reconstruction. Arch 
Orthop Trauma Surg. 132 (11), 1637-1645. 

Dong Y., Liao S., Ngiam M., Chan C. K., Ramakrishna S., 2009, Tissue Eng. Part B. Rev. 15, 333-351. 
Fukushima K., Kimura Y., 2008, An efficient solid-state polycondensation method for synthesizing             

stereocomplexed poly(lactic acid)s with high molecular weight. J Polym Sci Part A: Polym Chem. 46, 
3714–3722. 

Leiggener C.S., Curtis R., Muuller A.A, Pfluger D., Gogolewski S., Rahn B.A., 2006, Influence of copolymer 
composition of polylactide implants on cranial bone regeneration. Biomaterials. 27,202–207. 

Lopes M. S., 2014, Microreactor development for Synthesis of Bioabsorble Polymer (PLLA) used as 
biomedical implants. Campinas, 2014. PhD Program in Chemical Engineering. State University of 
Campinas. 

Mosmann T., 1983, Rapid Colorimetric Assay for Cellular Growth and Survival: Application to Proliferation and 
Cytotoxicity Assays, J lmmunol Methods, 65, 55-63. 

Sarasua J.R., Rodrıguez-Lopez N., Zuza E., Petisco S., Castro B., del Olmo M., Palomares T., Alonso-Varona 
A., 2011, Crystallinity assessment and in vitro cytotoxicity of polylactide scaffolds for biomedical 
applications. J Mater Sci: Mater Med. 22, 2513–2523. 

Wu G., Wu W., Zheng Q., Li J., Zhou J., Hu Z., 2014, Experimental study of PLLA/INH slow release implant 
fabricated by three dimensional printing technique and drug release characteristics in vitro. Biomed Eng 
Online. 19, 13:97. 

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