1. INTRODUCTION
Biomedical applications of chitosan include, drug delivery, tissue engineering, wound dressings, implant coatings and therapeutic agent delivery systems. Chitosans are biocompatible, profuse, nontoxic, biodegradable and renewable carbohydrate polymers [1-7].
Recent research has revealed the antimicrobial potential of chitosan on its Mr and DA [8-12] and higher viscosity of Mr and chitosan solutions have its multidimensional benefit. Alternatively, the low molecular weight chitosans could be depolymerised by physical, acidic or enzymatic methods. The highest bacterial activity towards pathogenic bacteria was found in LMWC (5 - 10 kDa) [13], whereas, 20 kDa product prevented progression of diabetes mellitus and showed a higher affinity for lipopolysaccharides (LPS) than the native chitosan ~140 kDa [14]. The sensible use of LMWC in milk safeguarding and oral hygiene is also reported [15].
It was reported that chitosan is biocompatibility and biodegradability [16,17] applied in drug delivery systems to prepare encapsulation of drugs, enzymes, proteins and DNA in nanospheres or microspheres level [18-20]. Drugs for biological activities could be developed by using chitisan only. Both soluble and microspheres chitosan showed a type of toxic in murine melanoma cell line and chitosan with hydrochloride exhibited extra toxic with an IC50 [21]. Dose dependent inhibitory effects of amino cationic chitosan derivatives showed the proliferation of numerous tumour cell lines with lowest IC50 towards liver cancer [22,23].
The most important properties of CH-NPs could provide a high resemblance used for negatively charged biological membranes and targeting specific site in vivo [13]. The CH-NPs with different concentrations could inhibit the dissimilar proliferated tumour cell lines whereas it could be toxic against normal liver cells [19]. The present investigations illustrate the possible mechanisms of CH-NPs and effects on the proliferation of human Lymphoma, SUDHL-4 cell line. It was characterized using electron microscopy, MTT assay, agarose electrophoresis of DNA, and flow cytometry.
2. MATERIALS AND METHODS
Chitosan was obtained from himedia and sodium tripolyphosphate (TPP), NaOH, acetic acid, NaH2PO4, were obtained from Hindustan scientific Linker, Odisha, India. SUDHL-4 (Cell Lines) was maintained in School of Biotechnology, KIIT University, Odisha, India. It was grown in medium (i.e., RPMI-1640) supplemented with 10% foetal calf serum in a humidified incubator at 37˚C along with 5% CO2. Collagen coated culture flasks were used when necessary and water was always used in demineralised form.
2.1. Isolation of LMWC
Different concentration of chitosan solution was treated with pronase in the ratio 100:1 (w/w), incubated for different periods at 37˚C followed by arresting the reaction by heat denaturing the enzyme (100˚C) and added equal volume of 2 N NaOH. The precipitated LMWC was obtained after centrifugation (3000 rpm, 10 min). Then, it was dialyzed against deionised water using a membrane and freeze dried.
2.2. Preparation of Nanoparticles
There are three different types of chitosan such as 6 kDa, 8 kDa and 10 kDa. The chitosan with 6 kDa was used more preferably as it is more compressed then the chitosan 8 kDa and 10 kDa. Chitosan nanoparticles (CHNPs) were synthesized via the ionotropic gelation [5] of chitosan with TPP anions. The synthesis of different concentrations of CH-NPs was first optimized and then dissolved in acetic acid (1%). The sodium tripolyphosphate (TPP) solution (1 mg/ml) was prepared by double distilled water. Chitosan nanoparticles were spontaneously fabricated with the drop wise addition of TPP solution (CH/TPP = 4:1) under magnetic stirring (1000 rpm) at room temperature (Figure 1(a)).
The opalescent suspension was shaped under the similar above mentioned conditions. The nanoparticles were separated by centrifugation at 20,000 g and 14˚C for 30 minutes and supernatants was discarded, freezedried and stored at 5˚C ± 3˚C. The weight of freeze-dried nanoparticles was calculated.
2.3. Characterization
2.3.1. LMW Chitosan
Three dissimilar LMW chitosan were prepared on the
(a)(b)(c)
Figure 1. (a) A schematic design for preparation of the chitosan nanoparticles using sodium tripolyphosphate (TPP); (b) Scanning electron microscopy of chitosan nanoparticles; (c) Transmission electron microscopy of chitosan nanoparticles.
basis of H NMR technique and viscosity method respectively. The Mr of chitosan used in this study was 6, 8 and 10 kDa. All chitosan grades were found to be entirely deacetylated.
2.3.2. SEM (Scanning Electron Microscopy) Analysis
To observe the morphological features, Field Emission Scanning Electron Microscopy, JEOL, JSM-6700F, Japan was used. By using sputter coated with a 5 nm thick gold, the samples were sprinkled.
2.3.3. TEM (Transmission Electron Microscopy) Analysis
TEM analysis was performed on a Hitachi H-8100 electron microscope with an acceleration voltage of 200 kV.
2.3.4. XRD (X-Ray Diffraction) Analysis
It was carried out using BEDE D-3 system with Cu Kα radiation at a generator or voltage of 40 kV and a generator current of 100 mA. The samples were scanned from scanned from 2θ = 1 – 100˚ at a scanning rate of 2˚/min.
2.3.5. Zeta Size and Potential Analysis
A Malvern Instrument, MAL 1037088, USA was used to determine the standard size of particle and zeta potential of nanoparticles. Disposable zeta cells measurement was carried with ultra pure water at 25˚C with a −50 mV latex standard calibrated frequently. The mean zeta potential was carried out using phase analysis light scattering technique.
2.3.6. FT-IR Analysis
A Perkin-Elmer Model of FTIR spectrophotometer, USA within the range of 4000 - 400 cm−1 was used for the samples analysis. Approximately, sample of 5 mg was with KBr (100 mg) and condensed into pellet using hydraulic press. The KBr pellet methods were used for all FT-IR spectra analysis.
2.3.7. Thermo Gravimetric Analysis (TGA)
Thermo gravimetric analysis (Perkin Elmer Model, USA) was used having unit of microprocessor temperature control with TA data station. The samples mass generally in the range of 2 - 3 mg was used. An equipment consist of both sample pan with balance system was placed in temperature ranges from 25˚C to 800˚C with 50 cm3/min. flow rate of nitrogen. The mass of sample pan was recorded constantly as a function of temperature.
2.3.8. Cell Viability Assay
In this case, cell (SUDHL-4) suspension with 100 µl aliquot containing 106 cells was added to every well of a 96 well plate (Corning, USA) and cultured 24 h. Then cells were treated immediately with different concentrations of CH-NPs such as 25 µg/ml, 50 µg/ml, 75 µg/ml and 100 µg/ml for another 24 or 48 h. The tetrazolium dye assay was used to know the consequence of diverse treatments on cell viability. The data in this study were expressed as mean ± SD.
2.3.9. DNA Fragmentation
First cells were treated with 100 µg/ml CH-NPs for 6 or 24 h, and then collected cells were washed using PBS followed by lyses. Then, such cells were used for extraction of DNA with phenol/chloroform/isoamyl alcohol (25:24:1) followed by chloroform. Precipitation of DNA was observed with two volumes of ethanol followed by 0.3 mol/l sodium acetate. Finally, DNA samples were obtained and visualized by agarose gel electrophoresis.
2.3.10. Determination of Mitochondrial Membrane Potential (MMP)
In this study, SUDHL-4 cells were treated with different concentrations (25 µg/ml, 50 µg/ml, 75 µg/ml and 100 µg/ml) of CH-NPs and followed by staining using rhodamine 123 (10 µg/ml) which is simply sequestered by MMP [13]. The rhodamine 123 was washed of the cells after loss of MMP. The mitochondrial membrane potential was find out using FACS calibur flow cytometer. For MMP analysis, the Cell Quest software program (BD Phar Mingen, Franklin Lakes, USA) was used.
2.3.11. Cell Cycle Analysis
Determination of DNA content and peaks of the apoptotic cells was done using flow cytometry. SUDHL-4 cells were grown in RPMI-1640 supplemented with 10% FBS. Different concentrations (25 µg/ml, 50 µg/ml, 75 µg/ml and 100 µg/ml) of CH-NPs were treated for 24h, after treatments cells were collected and stored at 4˚C. Fixation cells were washed, centrifuged and re-suspended in propidium iodine (0.05 mg/ml), RNase (100 U/ml) in PBS. The sample was incubated and analysed by Calibur flow Cytometer. The Cell Quest software and MOdFit software was used to determine the cell cycle data. In this study the negative controls were also maintained against the positive controls.
3. RESULTS AND DISCUSSIONS
3.1. Determination of LMWC
The determination of Mr (i.e., 71 ± 2 kDa) of native chitosan was done using GPC on Sepharose CL-4B and calculated its value in accordance with viscometry. In good agreement with each other, the DA was calculated from IR and 1H-NMR data. Different molecular weight (i.e., 10.5 and 6.5 kDa) values were calculated in different time intervals (i.e., 2 - 8 h) by HPLC and GPC. LMWC of free-NH2 groups and the column material showed minimum interaction using acetate buffer. The preparations of LMWC showed indicative molecular homogeneity with single symmetrical peak (Table 1) [24- 28].
3.2. Scanning Electron Microscopy and Transmission Electron Microscopy Analysis
The bare chitosan nanoparticle (CH-NP) with size
Table 1. Characteristics and percent yield of LMWC.
magnifications was done by SEM analysis (Figure 1(b)). The morphology of bare chitosan nanoparticle was shown about 78 nm in diameter with spherical in shape and found to be agreement. The particle size was decreased due to its aggregation and high specific surface energy [29].
In TEM analysis, chitosan nanoparticles exhibited round shaped due to vesicle disruption (Figure 1(c)) [30].
3.3. Stability and Biocompatible of the Nanoparticles
The biocompatibility nanoparticles with storage ability are great concern in pharmaceuitical fields. It is known that small size particles are inclined to agglomerate due to reduce free surface area and energy. Different concentrations of TPP were prepared with 2 - 90 days storage time at 4˚C to determine the size of nanoparticles (Figure 2(a)). Each and every particle was stable with neglectable fluctuated size within 15 days and some particles were shown larger in size at 90 days. The best storage stability was observed in different concentration of TPP (1.0 - 1.25 mg/ml at pH 6.0). The nanoparticles were precipitated continuously in undisturbed condition for some days and re-dispersed easily by moderate shaking.
At higher concentrations of TPP, the chitosan nanoparticles showed higher degree of cross linking whereas it is acceptable in decrease concentration of chitosan. Thus, it is resulted more compact particle structure. At the same time, particles showed smaller net charge due to neutralization of amino groups. It was also observed that smaller size particles structure due to compact and weakened charge repulsion in higher concentration of TPP.
3.4. XRD Analysis
In XRD analysis both pure and cross linked chitosans have been studied in the 2θ range of 5˚ to 60˚. The XRD profile of chitosan shows peaks at 23˚ and 50˚ 2θ (Figure 2(b)). The crystallinity of the chitosan (3.02%) in
(a)(b)
Figure 2. (a) Alteration of average size of chitosan nanoparticles with different TPP concentration during a storage time of 2 - 90 days at 4˚C; (b) XRD patterns of chitosan and developed membranes.
creases with the increase in degree of deacetylation and is attributed to enlarge in intermolecular hydrogen bonding due to the occurrence of more free NH2 groups (Higher Degree of Deacetylation) within the molecular structure, which in turn results the better packing of the macromolecular polymeric chains and consequent increase in the crystallinity.
3.5. Surface Morphology of SUDHL-4
The distraction of nuclear and cellular membrane exhibited necrosis under acute physiological stimuli condition. This important cause has been used to make a distinction necrosis from apoptosis of cellular membrane [31]. The chitosan nanoparticles treated with SUDHL-4 cells showed an ultra structure under SEM and TEM. Distinctive morphological characteristics of necrosis were observed in SUDHL-4 cells after treatment of chitosan nanoparticles. The SEM analysis showed both surface morphology and normal shape in control SUDHL-4 cells but large numbers of irregular microvilli were found in cell surface. After 30 minutes treatment of chitosan nanoparticles, cell death was induced due to leakage of early membrane and reduction of microvilli. After 2 h treatment of chitosan nanoparticles showed disintegration of microvilli and asymmetrical tiny holes with fracturing membrane solubilisation. The SUDHL-4 cells thus, damaged extensively and looked like as honeycomb shape after 4 h treatment. This type of necrotic cell death was observed due to pore forming surface morphology as well as loss of membrane integrity after the interface of CH-NP and plasma membrane. In TEM analysis, disruptions of cytoplasm and enlargement of organelles were observed in chitosan nanoparticles treated with necrotic SUDHL-4 cells whereas disrupted microvilli along with normal organelles in untreated cells. But vacuolated cells and complete disruption of plasma membrane were mainly observed after 24 h treatment with chitosan nanoparticles [32] (Figures 3(A)-(D)).
3.6. Zeta Size and Potential of Chitosan Nanoparticles
The normal chitosan nanoparticle size was 65 nm and average distribution size ranges starting 46 to 83 nm (Figure 4). In zeta potential, the stability of particle was significantly inclined on surface charge during the electrostatic repulsion among the particles. Our scanning electron microscopy studies of chitosan nanoparticles were almost coincide with the average particle size of chitosan nanoparticles (CH-NP). Measurement of zeta potential was one of the major indexes to determine the stability of nanoparticle suspension. Nanoparticles with
Figure 3. (A) Surface morphology of SUDHL-4 cells treated with 100 μg/mL chitosan nanoparticles for control cells; (B) 30 min; (C) 2 h; and (D) 4 h.
Figure 4. Size distributions of chitosan nanoparticles.
high electric surface charge showed high value of zeta potential due to repulsive forces between particles which leads to stop it from aggregation [33,34].
3.7. FTIR Analysis
In Figure 5(a), the transmission infrared spectra of powdered sodium tripolyphosphate (TPP), chitosan (CH) and ionically cross-linked chitosan/sodium tripolyphosphate (synthesized by cross-linking in TPP solution) are shown. A broad peak at 3433 cm−1 was shown in the bare CH−NP which corresponds to NH vibrational frequency. Generally, N-H stretching at 3500 - 3200 nm and N-H bend at 1550 - 1450 nm are observed in primary amino functional group. In FTIR spectrum, the region 4000 - 2000 nm was excluded due to interference of water molecules. The FTIR of TPP has both symmetric stretching and also asymmetric bending at 1022 nm and at 615 nm respectively. In such region (i.e., 615 nm and 1022 nm), two peaks were observed due to presence of phosphate in TPP chitosan [35,36]. It was also depicted the ionic bonding among the TPP and primary amine groups in TPP chitosan. Therefore, it implies that the occurrence of ammonium groups in TPP chitosan for such crosslinking reaction [37].
3.8. TGA Analysis
TGA analysis is normally used to determine the sample stability and loss of weight in diverse temperature. In this present study, TGA analysis of chitosan nanoparticles showed decomposition patterns in four stages (Figure 5(b)). In first stage, loss of weight (i.e., 6%) at 175˚C was observed because of the release of water molecules. In second stage, loss of weight (i.e., 22% approximately) at 365˚C was observed due to chitosan decomposition. In third stage, the loss of weight (i.e., 19%) was observed at 500˚C caused by decomposition. At last, in fourth stage, such decomposition of chitosan was observed at 635˚C with 16.79% of weight loss. However, the loss of weight
(a)(b)
Figure 5. (a) FT-IR spectrum of CS, bare CS-NP; (b) Thermogravimetric analysis of CS-NP.
was also examined in two stages due to decomposition of chitosan within the range of 320˚C and 470˚C [38,39]. Our result could correlate with this report.
3.9. Cell Viability Assay
The MTT cell viability assay of SUDHL-4 cells treated using different concentrations of CH-NPs ranging as of 25 to 100 µg/ml were observed. The viability cells were inhibited by CH-NPs in varied dose and time. Chitosan nanoparticles in median lethal concentration were 15 and 5 µg/ml for SUDHL-4 cells at 24 and 48 h, respectively (Figure 6). A high cytotoxicity against human lymphoma cell line could exert in chitosan nanoparticles. It was proved that the cell line is susceptible to CH-NPs by an IC50 value of 5 µg/ml after 48 h treatment and signifying that CH-NPs perhaps an excellent choice for antitumor drugs. Thus, size of the nanoparticles was mostly responsible in antitumor activity and in vivo distribution. Higher accumulation of tumour sites and makes longer half-life in vivo due to small size of nanoparticles [40- 43].
3.10. DNA Fragmentation
The cultured SUDHL-4 cells treated (i.e., 6 or 24 h) with 100 µg/ml CH-NPs were used for DNA extraction and detected necrosis by agarose gel electrophoresis. The DNA derivative with necrotic degeneration [44] was found after 6 h of incubation whereas larger DNA fragmentation was detected after 24 h of treatment with chitosan nanoparticles (Figure 7).
A series of “DNA Ladders” was observed in fragmented DNA due to formation of oligonucleosomes in apoptosis [45,46]. The fragmented DNA appears spectrum of size permanently during necrosis in contrast [43]. Thus, present study indicated that CH-NPs treated with tumour cells are mainly responsible for necrosis in fragmented DNA continuously.
Figure 6. Inhibition of chitosan nanoparticles on SUDHL- 4 cell proliferation.
Figure 7. Showing agarose gel electrophoretic analysis of DNA isolated from SUDHL-4 cells incubated with 100 μg/mL chitosan nanoparticles for 6 h (lane 2) and 24 h (lane 3) or without treatment (lane 1). M: a DNA marker.
3.11. Alternations of Mitochondial Membrane Potential (MMP)
One of the promising mechanisms concerned for mitochondrial damage which is induced by CH-NPs in the necrosis of SUDHL-4 cells. In Present study, decrease mitochondrial membrane potential in SUDHL-4 cells was observed in different concentration of chitosan nanoparticles after 4 h of treatments. It was also observed that increased percentage of cells with loss of mitochondrial membrane potential extensively with more concentrations of CH-NPs. It was 74% with 100 µg/ml concentration of CH-NPs. The possible disruption of cell mitochondrial membrane and also strong disruption in mitochondrial membrane potential was observed after the treatment of chitosan nanoparticles (Figures 8(a) and (b)).
Regulation of cell death mainly takes place by mitochondria which were already reported [47]. In high Ca2+ and oxidative stress, mitochondria forced to changes which were swelling, de-energization, decrease mitochondrial potential and inner membrane permeabilization [48]. In addition, necrotic cell death and loss of integrity in plasma membrane were observed due to dysfunction of mitochondria [49]. In this investigation, CH-NPs treated with lymphoma cells showed extreme decline of mitochondria membrane potential which indicated that the mitochondrial membrane is damaged (Figure 8(c)).
3.12. Effects of Cell Cycle
Different effects of CH-NPs treated with SUDHL-4 cells on cell cycle were determined by flow cytometry. The effects of CH-NPs were identified and a comparison was made in both treated and untreated cells on cell cycle. This finding was confirmed in the G0/G1 phase of cell cycle and also observed significant decrease of cells. The CH-NPs treatment with dose dependent manner showed apoptotic peaks and cell apoptotic incidence (9.9% in 100 µg/ml) [50]. The apoptotic incidence was increase up to 10.23% after treatment with 100 µg/ml chitosan nanoparticles (CH-NPs) (Figures 9(a) and (b)).This analysis exhibited that different concentrations of CH-NPs has major role for cell death and significant decline of cells in G0/G1 phase. This study also stated that CH-NPs showed high cytotoxicity towards lymphoma SUDHL-4 with necrotic cell death in about 52 mV positive surface charge and about 78 nm particle size. The CH-NPs and its antitumor mechanism are correlated with membrane disorderly inducing apoptosis activities.
4. CONCLUSION
In this investigation, we have developed a new method for synthesis of CH-NPs using ionic gelation technique
(a)(b)
Figure 8. (a) Histogram of untreated cells; (b) Histogram of cells treated with 100 μg/ml chitosan nanoparticles; (c) Chitosan nanoparticles-induced changes of MMP (loss of MMP).
(a) (b)
Figure 9. (a) Effect of chitosan nanoparticles on cell cycle of SUDHL-4 cells; (b) Apoptotic incidence of SUDHL-4 cells.
with TPP. The high loading competence with an efficient carrier was observed in the optimization ratio of chitosan to TPP (4:1). The present study demonstrated that a high cytotoxicity against human lymphoma SUDHL-4 cell line could exert in chitosan nanoparticles. It was proved that the cell line is susceptible to CH-NPs by an IC50 value of 5 µg/ml after 48 h action signifying that CHNPs are perhaps an excellent choice for antitumor drugs. Thus, size of the nanoparticles was mostly responsible in antitumor activity and in vivo distribution. Higher accumulation of tumour sites and makes longer half-life in vivo due to small size of nanoparticles. Here, the antitumor activity which prolongs efficiency could be controlled by using 78 nm particle size of CH-NPs. The CHNPs showed both lower as well as higher cationic charge densities which have higher cytotoxicity effects. The major factor for this cytotoxicity effect of chitosan derivatives is because of electrostatic ionic interface among the groups of negatively charged tumour cells and positively charged amino groups of chitosan. Therefore, the CH-NPs with 52 mV surface charge are responsible to make it higher cytotoxicity activity. Furthermore, the CH-NPs inhibited effectively the proliferation of Lymphoma SUDHL-4 in vitro through multiple mechanisms. These novel findings strengthen our hypothesis and can open a new path for further research against human lymphoma.
5. ACKNOWLEDGEMENTS
Authors are thanks to CSIR, Govt. of India for providing financial support. Authors are also grateful to CIPET, Bhubaneswar and Chennai of India for their help in this research. Authors have no any conflicts of interest in this manuscript. No writing assistance was utilized for preparation of this manuscript.
NOTES