A smart approach for delivery of aripiprazole via oro-soft palatal mucosal route for improved therapeutic efficacy

Madhav, Nookala Venkala Satheesh; Ojha, Abhijeet; Jaiswal, Vishakha

doi:10.1590/s2175-97902018000317382

Abstract

Effective management of schizophrenia, acute mania, mixed episodes associated with bipolar disorders, and depression can be managed with aripiprazole moiety. In the present research work an attempt was made to minimize the dose related side effects thus improving the quality life of the patients. A novel biopolymer was isolated from the fruits of Trachyspermum ammi. Ten optimized nanosized aripiprazole loaded formulations were prepared in 1-5% concentration of biopolymer (FA1-FA5) and sodium CMC (FM1-FM5) by solvent casting technique. The formulated flexy films were evaluated for thickness, folding endurance, weight uniformity, surface pH, mucoadhesivity, In-vitro drug release studies, In-vivo pharmacodynamic study and stability studies. The isolated biopolymer showed inbuilt fimability and mucoadhesivity and consists of carbonyl, hydroxyl and thiocarbonyl functional groups. All formulations showed folding endurance from 153 to 170, mucoadhesion time in the range of 24-48hrs., and in-vitro drug release was performed using dynamic Franz Diffusion cell and analyzed using BIT-SOFTWARE. The experimental animals showed improved activity score on actophotometer. The formulated nanosized aripiprazole loaded bio-flexy films showed pharmacotherapeutic response. Conclusion can be drawn that optimized formulation showed effective Pharmacodynamic activity and can be used as for improving therapeutic efficacy of aripiprazole through this platform.

Keywords:
Aripiprazole/therapeutic efficacy; Nanosized; Mucoadhesive; Schizophrenia; Oro-soft palatal mucosal route

Introduction

Schizophrenia is self-disorder characterized by complementary distortions of the act of awareness i.e. hyperreflexivity and diminished self-affection (^{Sass, Parnas, 2003}14. Sass LA, Parnas J. Schizophrenia, consciousness, and the self. Schizophrenia Bull. 2003;29(3):427-44.). Studies had suggested that the etiology of schizophrenia is yet unclear but it is believed that dopaminergic neural network has major role in its pathophsiology (^{Nekovarova et al., 2014}12. Nekovarova T, Fajnerova I, Horacek J, Spaniel F. Bridging disparate symptoms of schizophrenia: a triple network dysfunction theory. Front Behav Neurosci. 2014;8:171.). The symptoms of schizophrenia are positive and negative symptoms, and cognitive effects. The positive symptoms are conceptual disorganization, abnormal thought contents and hallucinations. Negative symptoms are reduction in normal functioning, flattened emotions, decrease of social behavior and anhedonia. Cognition is affected in several arena such as vigilance, psychomotor speed, impairment of memory functioning, social cognition (^{Green et al., 2004}5. Green MF, Nuechterlein KH, Gold JM, Barch DM, Cohen J, Essock S, et al. Approaching a consensus cognitive battery for clinical trials in schizophrenia: the NIMH-MATRICS conference to select cognitive domains and test criteria. Biol Psychiatry. 2004;56(5):301-7.).

Aripiprazole is used for the treatment of schizophrenia, bipolar disorder, major depressive disorder, autism, and Tourette’s syndrome (USFDA approved label of ABILIFY). It is a second generation atypical antipsychotic which belongs to the benzisoxazole derivatives and has serotonin 5-HT1A-receptor partial agonist as well as 5- HT2A-receptor antagonist properties like a partial agonist at dopamine D2 receptors. It has a pKa value of 7.6 in 20% aqueous ethanol (^{Ardiana, Lestari, Indrayanto, 2013}1. Ardiana F, Lestari MLAD, Indrayanto G. Profiles of drug substances, excipients, and related methodology. Amsterdam: Elsevier; 2013. p. 36-37.). Aripiprazole is a poorly soluble and poorly permeable compound with BCS class IV (^{Laszcz, Witkowska, 2016}8. Laszcz M, Witkowska A. Studies of phase transitions in the aripiprazole solid dosage form. J Pharm Biomed Anal. 2016;117:298-303.). It is weak alkaline drug which thus imparts pH-dependent solubility to it (^{Xu et al., 2012}18. Xu Y, Liu X, Lian R, Zheng S, Yin Z, Lu Y, et al. Enhanced dissolution and oral bioavailability of aripiprazole nanosuspensions prepared by nanoprecipitation/homogenization based on acid-base neutralization. Int J Pharm. 2012;438(1):287-95.).

Aripiprazole is categorized under black box warning drugs as it increases the risk of death in geriatric patients having dementia-related psychosis when treated with antipsychotic drugs. This may be due to collapse, infection or stroke. Also increases suicidal thinking and behavior in children, adolescents, and young adults taking antidepressants. Depression and other serious mental illnesses are themselves associated with an increased risk of suicide (^{Kalinichev et al., 2005}7. Kalinichev M, Rourke C, Daniels AJ, Grizzle MK, Britt CS, Ignar DM, et al. Characterisation of olanzapine-induced weight gain and effect of aripiprazole vs olanzapine on body weight and prolactin secretion in female rats. Psychopharmacology. 2005;182(2):220-31.; Otsuka Pharmaceutical, 2002).

The soft palate is the soft tissue present at the back of the roof of the mouth. The soft palatal mucosa is flexible, highly vascularized, having nonkeratinized stratified squamous epithelium about 100-200 µm thick, and it is supposed to be 4-4000 times more permeable than skin. The seromucous glands secrete saliva and facilitate adhesion. The blood supply to the palatal region comes from facial artery and is 0.89 mL/min/100 cm². It is innervated through CN V (i.e. lesser palatine nerve) (^{Shankar, Madhav, 2015}16. Shankar U, Madhav S. A smart oro-soft palate mucosal drug delivery: Credentials and future trends. Marmara Pharm J. 2015;19(3):208-21.; ^{Shakya, Madhav, Shakya, 2011}15. Shakya P, Madhav NS, Shakya AK, Singh K. Palatal mucosa as a route for systemic drug delivery: A review. J Control Rel. 2011;151(1):2-9.).

The plant Trachyspermum ammi belonging to family Apiaceae, is commonly known as ajwain. The fruits are used as spice and available in the market whole year. The phytochemical analysis of plant showed 38.6% carbohydrate, 15.4% protein, 11.9% fiber and 7.1% minerals containing calcium, phosphorous, iron and nicotinic acid (^{Bairwa, Sodha, Rajawat, 2012}2. Bairwa R, Sodha RS, Rajawat BS. Trachyspermum ammi. Pharmacogn Rev. 2012;6(11):56-60.). As on date literature reveals that no attempt was made for isolating biopolymer from Trachyspermum ammi, novel approach was made for isolating biopolymer from Trachyspermum ammi.

The current objective of our research work was to improve therapeutic efficacy of aripiprazole by delivering nanosized aripiprazole through soft palatal route. This can be achieved by formulating mucoadhesive bio-flexy film.

Material and methods

Aripiprazole was received as gift sample from Sun Pharma (Mumbai), India. Trachyspermum ammi was procured from local market of Dehradun, Uttarakhand, India. Sodium CMC, D-glucose, 1,2,3-propanetriol and all other chemicals and solvents were of analytical reagent grade.

Isolation of biomaterial from the pulp of Trachyspermum ammi

250 grams fruits of Trachyspermum ammi were taken soaked in distilled water and subjected for hydro distillation using Clevenger’s apparatus for 48 h, filtered and air dried. Exhausted seeds were mixed with 250 mL distilled water in a mixer to get smooth slurry and it was filtered through a muslin cloth. The filtrate was centrifuged at 3000 rpm to remove the extraneous matter. The supernatant liquid was treated with optimized quantity of propanone and kept in refrigerator for 24 h. The bio-material was separated by centrifugation at 4000 rpm for 25 min. The bio-material was dried in desiccator for 48 h. The bio-material extraction was repeated 6 times & practical yield was reported (^{Madhav, Shankar, 2011}9. Madhav NS, Shankar MU. A novel smart mucoadhesive biomaterial from Lallimantia royalena seed coat. Sci Asia. 2011;37:69-71.).

Physico-chemical characterization and spectral analysis of the isolated bio-material

The isolated bio-material was tested for various physico-chemical properties like colour, odour, solubility, color changing point, chemical tests for carbohydrates (molisch test, benedict’s), proteins (biuret test) and starch, and spectral studies like I.R Spectra was performed using Shimadzu IR Tracer-100.

In-vitro mucoadhesivity study of isolated bio-polymer

The isolated bio-polymers were screened for mucoadhesivity. The films were prepared in the ratios of 1-5% w/v biopolymer from T. ammi. The biopolymer was accurately weighed in different ratios and triturated with 10 µL of 1,2,3-propanetriol, and 80 mg of D-glucose as flexicizer. 10 mL of distilled water added into it and subjected for mechanical stirring for 30 min. The resulting solution was poured on petridish for natural drying of about 24 h. The dried bio-flexy films were tested for mucoadhesivity by Rotating Cylinder Method using Type II Dissolution apparatus goat intestinal mucosa. The fresh intestinal mucosa was attached over the cylindrical basket. The prepared flexy films were adhered to the membrane with gentle pressing. Then the cylinders were rotated at 100 rpm in 900 mL of pH buffer 7.4 at 37±˚C. The films were observed at different time intervals and the time required for dislodgement and or disintegration was recorded (^{Madhav, Yadav, 2013}10. Madhav NS, Yadav AP. A novel translabial platform utilizing bioexcipients from Litchi chinesis for the delivery of rosiglitazone maleate. Acta Pharm Sinica B. 2013;3(6):408-15.).

Drug excipients interaction study

The drug interaction study was performed wet and dry method. The drug was physically mixed with excipients in dry method and in wet method the physical mixture was treated with 2 mL of distilled water in the ratios of 1:1, 1:3 and 3:1 and kept for a period of 3 days. Both the mixtures were dissolved in methanol and then analyzed by TLC and UV Spectrophotometric method at 221nm (^{Kalaichelvi et al., 2009}6. Kalaichelvi R, Thangabalan B, Rao DS, Jayachandran E. UV spectrophotometric determination of aripiprazole in bulk and pharmaceutical formulation. J Chem. 2009;6(S1):S87-90.).

Formulation of nanosized Aripiprazole loaded flexy films

Aripiprazole was nanosized by using Novel method. The drug was dissolved in suitable solvent and 10 µL of 1,2,3-propanetriol was added as nanosizant into it. Propanetriol has the ability to enhance the wettability of aripiprazole and serves as good dispersing agent who aids in nanosizing of the particle hence it acts as nanosizant (Nalawde, Mukherjee, Kapoor, 2013).

10 mL of distilled water was added into it and sonicated for 5 cycles (each cycle of 3 mins). The solution was micro centrifuged at 10,000rpm for 15 min and residue was dried and collected. Optimized nanosized aripiprazole loaded flexy films using biopolymer and standard film former i.e. sodium CMC were prepared by using “Solvent casting method”. In this method biopolymer from T. ammi and sodium CMC was accurately weighed in different ratios and triturated with 10 µL of 1,2,3-propanetriol, and 80 mg of D-glucose as flexicizer. 10 mL of distilled water added into it and subjected for mechanical stirring for 30 min. 10 mg of drug was dissolved separately in ethanol. The nanosized drug solution was added to the polymeric solution under stirring 4,500 rpm. The polymeric solution was poured on petridish for natural drying of about 24 h.

Nanosizing characterization by U.V spectroscopic method

It is a novel preliminary screening method for nanosizing range of particles by U.V spectroscopy and performed after each cycle of sonication. Transmittance is based on the concept of Tindal effect. When a light passes through a medium or solution which doesn’t contain solute between 200-400 nm size range 100% light gets transmitted. If a solvent contains any solute particles ranging 200-800nm then the particles may absorb a light and proportionally shows absorbance by reducing the %T 0.05 by reducing / blocking 10% of absorbance and 90% of transmittance similarly 1% absorbance with 10 % T and 90% blockage (^{Varley, 2005}17. Varley H. Introductary collection of specimens and some general techniques. In: Practical clinical biochemistry. 4th ed. New Delhi: CBS Publishers and Distributers; 2005.).

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TABLE I:
Formulation table of optimized aripiprazole loaded bio-flexy films of Trachyspermum ammi

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TABLE II:
Formulation table of optimized aripiprazole loaded flexy films of sodium CMC as Film former

Evaluation of nanosized aripiprazole loaded flexy films

Appearance, weight uniformity and content uniformity study

All the flexy films were weighed three times then weight uniformity was calculated. All formulated flexy films were evaluated for its drug content uniformity. Selected film (1 cm²) was transferred into a 100 mL volumetric flask containing 7 mL of phosphate buffer of pH7.4 and 1 mL of methanol. The contents of flask were stirred for 4 h on magnetic stirrer. The drug content was then determined after appropriate dilutions by using an UV spectrophotometer (Shimadzu 1800) (^{Madhav, Yadav, 2013}10. Madhav NS, Yadav AP. A novel translabial platform utilizing bioexcipients from Litchi chinesis for the delivery of rosiglitazone maleate. Acta Pharm Sinica B. 2013;3(6):408-15.).

The drug content was calculated by using below equation:

D r u g c o n t e n t = (A n a l y z e d \frac{c o n t e n t}{T h e o r e t i c a l} c o n t e n t) x 100

Folding endurance and surface pH

The selected films were subjected repeatedly folding a film (of area 2 cm²) at the same place until it broke and the number of folds recorded. The surface pH of flexy films was measured by using pH meter (^{Madhav, Yadav, 2013}10. Madhav NS, Yadav AP. A novel translabial platform utilizing bioexcipients from Litchi chinesis for the delivery of rosiglitazone maleate. Acta Pharm Sinica B. 2013;3(6):408-15.).

Mucoadhesion study

The mucoadhesive property of prepared films was evaluated by Rotating Cylinder method using goat soft palatal mucosa with phosphate buffer pH 7.4. After each 30 min and up to 36 h the film was observed for any dislodgement or disintegration from the soft palatal mucosal surface. The results were compared with the standard films of sodium CMC (^{Madhav, Yadav, 2013}10. Madhav NS, Yadav AP. A novel translabial platform utilizing bioexcipients from Litchi chinesis for the delivery of rosiglitazone maleate. Acta Pharm Sinica B. 2013;3(6):408-15.).

In-vitro drug release study

The In-vitro drug diffusion was carried out by using the Dynamic Franz diffusion cell method. Egg shell membrane was tied on the donor compartment and flexy film of 1 cm² area was kept on the above the membrane and the receiver compartment were filled with 7 mL of phosphate buffer pH7.4. 4 mL of sample was withdrawn at the intervals of 0, 10, 20, 30, 60, 120, 180, 300, 360, 480 and1440 min and replaced with 4 mL of fresh medium. The amount of drug released was assessed by measuring the absorbance at 221 nm using UV spectrophotometer (Shimadzu 1800) (^{Madhav, Yadav, 2013}10. Madhav NS, Yadav AP. A novel translabial platform utilizing bioexcipients from Litchi chinesis for the delivery of rosiglitazone maleate. Acta Pharm Sinica B. 2013;3(6):408-15.; ^{Kalaichelvi et al., 2009}6. Kalaichelvi R, Thangabalan B, Rao DS, Jayachandran E. UV spectrophotometric determination of aripiprazole in bulk and pharmaceutical formulation. J Chem. 2009;6(S1):S87-90.).

In-vivo pharmacodynamic study

The in-vivo pharmacodynamic study was performed by monitoring locomotor activity of Wistar albino rats using actophotometer. Rats were divided into two test groups (group I & II) and control (group III) each group containing two rats. Animals were maintained under light and dark cycle of 12 h in light and 12 h in dark under 25 °C and 70% RH. Animals were placed in actophotometer individually and basal activity score was recorded over the period of 5 min. Then the flexy film containing 1 mg of aripiprazole was applied on the soft palatal mucosa of test group I, group II received oral solution of aripiprazole and activity score was recorded after 30 min and 1 hr (^{Bhosale et al., 2011}3. Bhosale UA, Yegnanarayan R, Pophale PD, Zambare MR, Somani RS. Study of central nervous system depressant and behavioral activity of an ethanol extract of Achyranthes aspera (Agadha) in different animal models. Int J Appl Basic Med Res. 2011;1(2):104-8.).

Stability study

Optimized best flexy film was subjected to stability study as per ICH guidelines. The film were kept in an incubator (stability study chamber) maintained at 37±5 °C and 75±5%R.H. for 6 months. The change in appearance, physical characteristics and release behavior of the stored films were investigated from 0-6 months (^{Ezhumalai et al., 2011}4. Ezhumalai K, Ilavarsan P, Mugundhan RM, Sathiyaraj U, Rajalakshmi AN. Transdermal patches in novel drug delivery system. Int J Pharm Technol. 2011;3(2):2402-2419.).

Results and discussion

Isolation, physico-chemical characterization and Spectral analysis of isolated bio-material from Trachyspermum ammi

The % yield of Trachyspermum ammi was found to be 5.1±1.05%. The isolated biomaterial is carbohydrate and proteinaceous in nature. The physico-chemical characterization is shown in table IIIa and IIIb). The bio-material was purified by hot dialysis method and it was devoid of chlorides and sulfates. The functional groups of bio-material were elucidated by I.R. spectral studies.

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TABLE IIIa:
Characterization of bio-materia

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TABLE IIIb:
Characterization of bio-material

The I.R. spectral interpretation by IR Pal V 2.0 reported the presence of hydroxyl (3408 cm^-1), alkanes, alkenes, phosphonic (2668 cm^-1), phosphine (2430 cm^-1), amides (1636 cm^-1), carboxylic acid (1398 cm^-1), thiocarbonyl (1117 cm^-1) and alkyne (620 cm^-1). (Figure 1). These functional groups are responsible for the mucoadhesive property of the biopolymer.

FIGURE 1:
I.R. Spectra of Trachyspermum ammi.

In-vitro mucoadhesivity study of isolated bio-polymer

The isolated biopolymer showed maximum mucoadhesion time of 48 hrs at the concentration of 5%. The results revealed that as the concentration of biopolymer was increased there was also an increase in mucoadhesion time which can be explored for designing mucoadhesive dosage form (Figure 2).

FIGURE 2:
In-vitro Mucoadhesion study of isolated bio-polymer.

Drug excipients interaction study

The studies revealed that there was no interaction between the drug and the excipients including the bio-polymer. This was confirmed by the result of the thin layer chromatography in which no change was seen in the Rf value. Also there was no change in the ƛ max and absorbance also. Since excipients doesn’t have any reacting group hence selected for further processing. Value which was observed to be 221 nm prior to the test and after the test it was 221 nm hence confirming that there was no interaction between the drug and excipients. It was concluded that none of the excipients had a deleterious effect on the drug and could be used for the formulation of the flexy-films.

Nanosizing characterization by U.V spectroscopic method

% Transmittance was measured before and after each cycle of sonication. As the number of sonication cycles was increased there was an increase in the % transmittance indicating that the particles may be gone in nano range thus increasing the transmittance (Figure 3).

FIGURE 3:
Nanosizing charaterization by UV spectroscopic method.

Evaluation of prepared nanosized aripiprazole loaded flexy films

Nanosized Aripiprazole loaded bio-flexy films (FA1-FA5 and FA1-FA5) were prepared by using biopolymer isolated from Trachyspermum ammi as mucoadhesive film former, sodium CMC as standard polymer, D-glucose as flexicizer and other co-processing agent like 1,2,3-propanetriol as plasticizer.

All the prepared formulations were subjected for different evaluation parameters.

Appearance, weight uniformity and content uniformity study

All flexy films were transparent in nature, smooth in appearance, and flexible in nature. The weight variation and % drug content of all the flexy film formulas was in the range of 23.73 to 34.48 mg and 96.4-98.9% respectively as shown in Table IV.

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TABLE IV:
The pH, weight, folding endurance and percent of drug content in Aripiprazole loaded flexy film formulations

Folding endurance and surface pH

The results were shown in the Table IV. All the prepared formulations (FA1-FA5 and FM1-FM5) showed folding endurance in the range of 153 to 170 folds. Folding endurance study revealed that there was slight increase in the flexibility of the films as the polymeric concentration was increased in the formulations. FM5 showed maximum folding endurance of 170 times in comparison to other formulations, this may be due to the presence of optimum concentration of polymer and flexicizer. FA1 showed minimal folding endurance of 153 times. All the prepared formulations (FA1-FA5 and FM1-FM5) showed a surface pH in the range of 7.31 to 7.41 which is near to neutral in nature and devoid of irritation as formulations were prepared by using biopolymeric substance which is edible, biocompatible, economical and devoid of any mucosal irritant groups.

Mucoadhesion study

The mucoadhesion of the prepared films was assessed by in-vitro Rotating Cylinder method using goat soft palatal mucosa. All the formulations showed significant mucoadhesion time and as the concentration of polymer was increased there was proportional increase in the mucoadhesion time. (Figure 4) The In-vitro mucoadhesion study showed that formulation FA5 and FM5 had maximum mucoadhesion for a period of 48 h. This may be due to presence of mucoadhesive functional groups like carboxylic and thiocarbonyl and optimized proportion of polymer. FA1 showed least mucoadhesion time over a period of 22 h this may be due to the minimum concentration of biopolymer and/or overdhyration. Upon increasing the biopolymer and standard polymer concentration there was an appreciable increase in the mucoadhesion time.

FIGURE 4:
In-vitro Mucoadhesion Study by Rotating Cylinder Method.

In-vitro drug release study

The In-vitro drug release kinetics was analyzed by BIT-SOFTWARE. The t50% and t 80% of formulations were calculated and reported.

The comparative drug release profile of all the formulations showed that the drug released followed the descending order: FA2 > FM1 > FA4 > FM5 > FA5 > FM3 > FA1 > FA3 > FM4 > FM2 (Figure 5).

FIGURE 5:
In-vitro drug release study by franz diffusion cell apparatus.

The In-vitro drug release study revealed that formulation t50% from 3.1-4.5 h, and released drug up to 24 h. Biopolymer showed drug release retardation property and released drug for a longer period of time thus reducing the dosing frequency.

In-vivo Pharmacodynamic study

The photoactometer study showed the evidence of greater central nervous system stimulation by the nanosized drug loaded flexy film application in rats of group I in the form of increased activity score. While the rats in test group II does not showed comparable increase in activity score (Figure 6).

FIGURE 6:
Pharmacodynamic study by Photoactometer.

The results of in-vivo Pharmacodynamic study showed that there was increase in the locomotor activity of experimental animals (group I) after flexy film application, signifies the increased dopaminergic activity in brain. Comparing the results it suggested that the locomotor acitivity due to the drug was much more in the group receiving nanosized aripiprazole than the group administered with plain oral solution of drug at same dose level.

Stability study

The best formulation was stable over a period of 6 months as there was no change in the physical appearance, drug content and in-vitro release.

On comparison of the performance of all flexy films including texture, flexibility, surface pH, weight uniformity, content uniformity, folding endurance, mucoadhesivity, In-vitro drug release retardibility, in-vivo Pharmacodynamic study the FA2 formulation with R² value 0.9121 was selected as best optimized film. The above results indicated that administration of nanosized Aripiprazole via oro-soft palatal route increased its therapeutic performance

Conclusion

The isolated biopolymer from Trachyspermum ammi can serve as film former and it can be used for designing various drug loaded flexy films. Delivery of aripiprazole can be significantly enhanced by administering in the form of nanosized aripiprazole loaded bio-flexy film on soft palatal mucosa as it is enriched with nerve supply, so it showed significant Pharmacodynamic activity. Hence it was concluded that oro-soft palatal mucosa can serve as novelistic platform for effective delivery of Aripiprazole to produce significant Pharmacodynamic response.

Acknowledgements

We would like to thank Vice Chancellor and DIT University, Dehradun for their valuable support.

¹
Ardiana F, Lestari MLAD, Indrayanto G. Profiles of drug substances, excipients, and related methodology. Amsterdam: Elsevier; 2013. p. 36-37.
²
Bairwa R, Sodha RS, Rajawat BS. Trachyspermum ammi. Pharmacogn Rev. 2012;6(11):56-60.
³
Bhosale UA, Yegnanarayan R, Pophale PD, Zambare MR, Somani RS. Study of central nervous system depressant and behavioral activity of an ethanol extract of Achyranthes aspera (Agadha) in different animal models. Int J Appl Basic Med Res. 2011;1(2):104-8.
⁴
Ezhumalai K, Ilavarsan P, Mugundhan RM, Sathiyaraj U, Rajalakshmi AN. Transdermal patches in novel drug delivery system. Int J Pharm Technol. 2011;3(2):2402-2419.
⁵
Green MF, Nuechterlein KH, Gold JM, Barch DM, Cohen J, Essock S, et al. Approaching a consensus cognitive battery for clinical trials in schizophrenia: the NIMH-MATRICS conference to select cognitive domains and test criteria. Biol Psychiatry. 2004;56(5):301-7.
⁶
Kalaichelvi R, Thangabalan B, Rao DS, Jayachandran E. UV spectrophotometric determination of aripiprazole in bulk and pharmaceutical formulation. J Chem. 2009;6(S1):S87-90.
⁷
Kalinichev M, Rourke C, Daniels AJ, Grizzle MK, Britt CS, Ignar DM, et al. Characterisation of olanzapine-induced weight gain and effect of aripiprazole vs olanzapine on body weight and prolactin secretion in female rats. Psychopharmacology. 2005;182(2):220-31.
⁸
Laszcz M, Witkowska A. Studies of phase transitions in the aripiprazole solid dosage form. J Pharm Biomed Anal. 2016;117:298-303.
⁹
Madhav NS, Shankar MU. A novel smart mucoadhesive biomaterial from Lallimantia royalena seed coat. Sci Asia. 2011;37:69-71.
¹⁰
Madhav NS, Yadav AP. A novel translabial platform utilizing bioexcipients from Litchi chinesis for the delivery of rosiglitazone maleate. Acta Pharm Sinica B. 2013;3(6):408-15.
¹¹
Nalawade P, Mukherjee T, Kapoor S. Green synthesis of gold nanoparticles using glycerol as a reducing agent. Adv Nanoparticles. 2013;2(2):78-86.
¹²
Nekovarova T, Fajnerova I, Horacek J, Spaniel F. Bridging disparate symptoms of schizophrenia: a triple network dysfunction theory. Front Behav Neurosci. 2014;8:171.
13. Otsuka Pharmaceutical Co. L. Full prescribing information-Abilify (Aripiprazole), 2014. USFDA approved label of ABILIFY. [cited 2016 Nov. 08]. Available from: http://www.accessdata.fda.gov/drugsatfda_docs/label/2002/21436_Abilify_lbl.pdf
» http://www.accessdata.fda.gov/drugsatfda_docs/label/2002/21436_Abilify_lbl.pdf
¹⁴
Sass LA, Parnas J. Schizophrenia, consciousness, and the self. Schizophrenia Bull. 2003;29(3):427-44.
¹⁵
Shakya P, Madhav NS, Shakya AK, Singh K. Palatal mucosa as a route for systemic drug delivery: A review. J Control Rel. 2011;151(1):2-9.
¹⁶
Shankar U, Madhav S. A smart oro-soft palate mucosal drug delivery: Credentials and future trends. Marmara Pharm J. 2015;19(3):208-21.
¹⁷
Varley H. Introductary collection of specimens and some general techniques. In: Practical clinical biochemistry. 4th ed. New Delhi: CBS Publishers and Distributers; 2005.
¹⁸
Xu Y, Liu X, Lian R, Zheng S, Yin Z, Lu Y, et al. Enhanced dissolution and oral bioavailability of aripiprazole nanosuspensions prepared by nanoprecipitation/homogenization based on acid-base neutralization. Int J Pharm. 2012;438(1):287-95.

Financial support and sponsorship

Nil.

Publication Dates

Publication in this collection
29 Nov 2018
Date of issue
2018

History

Received
14 July 2017
Accepted
27 Oct 2017

This is an open-access article distributed under the terms of the Creative Commons Attribution License

[1] ¹
Ardiana F, Lestari MLAD, Indrayanto G. Profiles of drug substances, excipients, and related methodology. Amsterdam: Elsevier; 2013. p. 36-37.

[2] ²
Bairwa R, Sodha RS, Rajawat BS. Trachyspermum ammi. Pharmacogn Rev. 2012;6(11):56-60.

[3] ³
Bhosale UA, Yegnanarayan R, Pophale PD, Zambare MR, Somani RS. Study of central nervous system depressant and behavioral activity of an ethanol extract of Achyranthes aspera (Agadha) in different animal models. Int J Appl Basic Med Res. 2011;1(2):104-8.

[4] ⁴
Ezhumalai K, Ilavarsan P, Mugundhan RM, Sathiyaraj U, Rajalakshmi AN. Transdermal patches in novel drug delivery system. Int J Pharm Technol. 2011;3(2):2402-2419.

[5] ⁵
Green MF, Nuechterlein KH, Gold JM, Barch DM, Cohen J, Essock S, et al. Approaching a consensus cognitive battery for clinical trials in schizophrenia: the NIMH-MATRICS conference to select cognitive domains and test criteria. Biol Psychiatry. 2004;56(5):301-7.

[6] ⁶
Kalaichelvi R, Thangabalan B, Rao DS, Jayachandran E. UV spectrophotometric determination of aripiprazole in bulk and pharmaceutical formulation. J Chem. 2009;6(S1):S87-90.

[7] ⁷
Kalinichev M, Rourke C, Daniels AJ, Grizzle MK, Britt CS, Ignar DM, et al. Characterisation of olanzapine-induced weight gain and effect of aripiprazole vs olanzapine on body weight and prolactin secretion in female rats. Psychopharmacology. 2005;182(2):220-31.

[8] ⁸
Laszcz M, Witkowska A. Studies of phase transitions in the aripiprazole solid dosage form. J Pharm Biomed Anal. 2016;117:298-303.

[9] ⁹
Madhav NS, Shankar MU. A novel smart mucoadhesive biomaterial from Lallimantia royalena seed coat. Sci Asia. 2011;37:69-71.

[10] ¹⁰
Madhav NS, Yadav AP. A novel translabial platform utilizing bioexcipients from Litchi chinesis for the delivery of rosiglitazone maleate. Acta Pharm Sinica B. 2013;3(6):408-15.

[11] ¹¹
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S.No.	Test	Observation	Inference
1.	Molisch	+	Carbohydrate present
2.	Benedict	+	Carbohydrate present
3.	Biuret	+	Proteins present

Colour	Brown
Odour	Characterstic
Taste	Characterstic
Solubility	Slightly soluble in water
Melting Point	255±10˚C

Formulation Code	pH	Weight Uniformity (mg)	Folding Endurance (folds)	% Drug content
FA1	7.41± 0.05	21.89± 0.06	153± 0.5	97.1± 0.04
FA2	7.38± 0.07	24.54± 0.05	156± 0.6	98.9± 0.03
FA3	7.35± 0.08	25.73± 0.07	154± 0.4	98.3± 0.05
FA4	7.33± 0.06	24.71± 0.06	157± 0.2	97.4± 0.07
FA5	7.35± 0.05	23.98± 0.08	162± 0.3	96.8± 0.05
FM1	7.31± 0.04	22.73± 0.03	164± 0.7	98.4± 0.04
FM2	7.40± 0.06	23.56± 0.04	162± 0.2	98.5± 0.04
FM3	7.39± 0.05	24.78± 0.06	163± 0.3	96.4± 0.03
FM4	7.34± 0.06	23.01± 0.05	167± 0.4	96.8± 0.05
FM5	7.33± 0.07	24.48± 0.07	170± 0.5	97.2± 0.04

Brasil

Brasil

A smart approach for delivery of aripiprazole via oro-soft palatal mucosal route for improved therapeutic efficacy

Abstract

Introduction

Material and methods

Isolation of biomaterial from the pulp of Trachyspermum ammi

Physico-chemical characterization and spectral analysis of the isolated bio-material

In-vitro mucoadhesivity study of isolated bio-polymer

Drug excipients interaction study

Formulation of nanosized Aripiprazole loaded flexy films

Nanosizing characterization by U.V spectroscopic method

Evaluation of nanosized aripiprazole loaded flexy films

Results and discussion

Isolation, physico-chemical characterization and Spectral analysis of isolated bio-material from Trachyspermum ammi

In-vitro mucoadhesivity study of isolated bio-polymer

Drug excipients interaction study

Nanosizing characterization by U.V spectroscopic method

Evaluation of prepared nanosized aripiprazole loaded flexy films

Conclusion

Acknowledgements

Financial support and sponsorship

Publication Dates

History

Formulation	FA1 (1:1)	FA2 (1:2)	FA3 (1:3)	FA4 (1:4)	FA5 (1:5)
Aripiprazole (mg)	10	10	10	10	10
Trachyspermum ammi (mg)	1%	2%	3%	4%	5%
D-glucose (mg)	80	80	80	80	80
1,2,3-Propanetriol (µL)	10	10	10	10	10
Distilled Water (mL)	10	10	10	10	10

Formulation	FM1 (1:1)	FM2 (1:2)	FM3 (1:3)	FM4 (1:4)	FM5 (1:5)
Aripiprazole (mg)	10	10	10	10	10
Sodium CMC (mg)	1%	2%	3%	4%	5%
D-glucose (mg)	80	80	80	80	80
1,2,3-Propanetriol (µL)	10	10	10	10	10
Distilled Water (mL)	10	10	10	10	10