Bio-evaluation of poly(lactic-co-glycolic) acid nanoparticles loaded with radiolabelled rifampicin.

AIMS: The poly(lactic-co-glycolic) acid (PLGA) nanoparticles of tubercular drugs have been demonstrated to have a sustained release profile over 7 days. There is no information on the location or mode of release of these nanoparticles in living systems. Therefore, we have planned the study to explore the pharmacokinetics and biodistribution of PLGA rifampicin nanoparticles in healthy human volunteers. We aim to study the distribution pattern of PLGA-loaded nano-formulation of radiolabelled rifampicin in humans. METHODS: Rifampicin was labelled with 99m Tc by indirect method and nanoparticles were prepared by a single emulsion evaporation method. To investigate the pharmacokinetics and biodistribution of nanoparticles, a single dose of 450 mg of rifampicin was administered orally to healthy human volunteers divided into two different groups. RESULTS: Following a single oral dosage of the rifampicin nanoformulation, the pharmacokinetic (PK) parameters were significantly different between the nanoparticle and conventional groups: area under the concentration-time curve (AUC = 113.8 vs. 58.6; P < .001), mean residence time (MRT = 16.2 vs. 5.8; P < .01) and elimination rate constant (Ke = 0.04 vs. 0.10; P < .05). Also, Single-photon emission computed tomography/computed tomography (SPECT/CT) images revealed biodistribution of nanoparticles in the distal portions of the intestine, which is consistent with our dosimetry analysis. CONCLUSIONS: Significant difference in PK parameters and biodistribution of nanoparticles in spleen and lymph nodes with maximum deposition were observed in the large intestine. The nanoparticle distribution pattern may be advantageous for the treatment of intestinal or lymph node tuberculosis (TB) and has the potential to result in a lower dose of rifampicin nanoformulation for the treatment of pulmonary TB.

Single ascending dose safety, tolerability, and pharmacokinetic study of econazole in healthy volunteers.

INTRODUCTION: Econazole has been found efficacious as antitubercular in in vitro and in vivo animal studies. However, limited information is available for its safety and pharmacokinetics in humans. In our present study we have conducted single ascending dose, safety, and pharmacokinetic evaluation in healthy human volunteers with the purpose of enabling translation for tuberculosis. METHODS: This study was conducted as a single-center, ascending-dose, placebo-controlled, double blind design. Three ascending dose were chosen (250 , 500 , and 1000 mg) to be administered as a single oral dose. The volunteers were screened for potential eligibility. Participants were randomized to receive either Econazole or Placebo in a 6:2 design. Safety assessments and pharmacokinetic evaluations were carried out for each cohort. RESULTS: Econazole was found to be safe at all dose levels. No serious or severe adverse events occurred during the study. The AUC (0-∞) showed a response relationship with a value of 49 ± 3.47 h* µg/ml, 17. 86 ± 8.40 hr* µg/ml, 35.54 ± 13.94 hr* µg/ml for 250 mg, 500 mg, and 1000 mg, respectively. CONCLUSION: Based on the findings of our study, a dose of 500 mg Econazole, once a day orally was considered as appropriate for further evaluation.

Efficacy of moxifloxacin & econazole against multidrug resistant (MDR) Mycobacterium tuberculosis in murine model.

BACKGROUND & OBJECTIVES: Studies have shown the bactericidal potential of econazole and clotrimazole against Mycobacterium tuberculosis under in vitro and ex vivo conditions along with their synergism with conventional antituberculosis drugs. These molecules were also found to be effective against different multidrug resistant (MDR) M. tuberculosis isolates in vitro. Hence the present study was designed to evaluate the in vivo antimycobacterial potential of moxifloxacin and econazole alone and in combination against multidrug resistant tuberculosis (MDR-TB) in a mice model. METHODS: Mice were infected with 2.5×10 [7] bacilli of MDR strain of M. tuberculosis by aerosol route of infection. After four weeks of infection, chemotherapy was started orally by moxifloxacin 8.0 mg/kg body wt and econazole 3.3 mg/kg alone and in combination, as well as with four first line anti-tuberculosis drugs as a positive control. The animals were sacrificed and the lungs and spleen were excised under aspetic conditions. The tissues were homogenized with sterile normal saline, an aliquot of the homogenate was plated on Middlebrook 7H11 agar supplemented with oleate albumin dextrose catalase (OADC) and incubated at 37°C for four weeks. The number of visible and individual colonies were counted. RESULTS: The first line anti-tuberculosis drugs (RIF+INH+EMB+PZA) after eight weeks of therapy had no impact as the bacillary load in lungs and spleens remained unchanged. However, econazole, moxifloxacin alone as well as in combination significantly reduced the bacillary load in lungs as well as in spleens of MDR-TB bacilli infected mice. INTERPRETATION & CONCLUSIONS: Co-administration of the two drugs (econazole and moxifloxacin) to MDR-TB strain JAL-7782 infected mice exhibited additive effect, the efficacy of the drugs in combination being higher as compared with ECZ or MOX alone. These results were substantiated by histopathological studies. This study suggests the utility of econazole for the treatment of MDR tuberculosis and warrants further work in this direction.

Development of Sustained Release "NanoFDC (Fixed Dose Combination)" for Hypertension - An Experimental Study.

OBJECTIVES: The present study was planned to formulate, characterize and evaluate the pharmacokinetics of a novel "NanoFDC" comprising three commonly prescribed anti-hypertensive drugs, hydrochlorothiazide (a diuretic), candesartan (ARB) and amlodipine (a calcium channel blocker). BASIC METHODS: The candidate drugs were loaded in Poly (DL-lactide-co-gycolide) (PLGA) by emulsion- diffusion-evaporation method. The formulations were evaluated for their size, morphology, drug loading and in vitro release individually. Single dose pharmacokinetic profiles of the nanoformulations alone and in combination, as a NanoFDC, were evaluated in Wistar rats. RESULTS: The candidate drugs encapsulated inside PLGA showed entrapment efficiencies ranging from 30%, 33.5% and 32% for hydrochlorothiazide, candesartan and amlodipine respectively. The nanoparticles ranged in size from 110 to 180 nm. In vitro release profile of the nanoformulation showed 100% release by day 6 in the physiological pH 7.4 set up with PBS (phosphate buffer saline) and by day 4-5 in the intestinal pH 1.2 and 8.0 set up SGF (simulated gastric fluid) and SIF (simulated intestinal fluid) respectively. In pharmacokinetic analysis a sustained-release for 6 days and significant increase in the mean residence time (MRT), as compared to the respective free drugs was noted [MRT of amlodipine, hydrochlorothiazide and candesartan changed from 8.9 to 80.59 hours, 11 to 69.20 hours and 9 to 101.49 hours respectively]. CONCLUSION: We have shown for the first time that encapsulating amlodipine, hydrochlorothiazide and candesartan into a single nanoformulation, to get the "NanoFDC (Fixed Dose Combination)" is a feasible strategy which aims to decrease pill burden.

In vitro and ex vivo activity of peptide deformylase inhibitors against Mycobacterium tuberculosis H37Rv.

Bacterial peptide deformylase (PDF) catalyses removal of the N-terminal formyl group of proteins and is essential for protein maturation, growth and survival of bacteria. Thus, PDF appears to be a good antimycobacterial drug target. In the present study, various well-known PDF inhibitors, such as BB-3497, actinonin, 1,10-phenanthroline, hydroxylamine hydrochloride and galardin, were selected to evaluate their inhibitory activity against Mycobacterium tuberculosis. All compounds were found to be active against M. tuberculosis, with MIC(90) values (lowest drug concentration at which 90% of growth was inhibited on the basis of CFU enumeration) ranging from 0.2 mg/L to 74 mg/L. BB-3497 and 1,10-phenanthroline exhibited potent in vitro antimycobacterial activity, and also showed synergism with isoniazid and rifampicin. All compounds showed a bacteriostatic mode of inhibition. Under ex vivo conditions and short-course chemotherapy, BB-3497 and actinonin were found to be significantly active, with BB-3497 exhibiting comparable efficacy to that of isoniazid. Collectively, promising activities of PDF inhibitors such as BB-3497 and actinonin suggest their potential use against M. tuberculosis.

Alginate-based sustained release drug delivery systems for tuberculosis.

Drug delivery systems have wide biomedical applications owing to their distinct therapeutic advantages, such as controlled release of drugs over prolonged periods, protection against premature drug degradation, reduction in drug toxicity and drug-drug interactions. All these factors are important considerations in the treatment of chronic infectious diseases such as tuberculosis. In tuberculosis, patient non-compliance is a vexing problem which is responsible not only for treatment failure, but also for the emergence of multi-drug resistant cases. Alginate, a natural polymer, has attracted researchers owing to its ease of availability, compatibility with hydrophobic as well as hydrophilic molecules, biodegradability under physiological conditions, lack of toxicity and the ability to confer sustained release potential. It is not therefore surprising that the controlled release phenomenon of this polymer has been documented for a vast array of drugs. In particular, the ability of alginate to co-encapsulate multiple antitubercular drugs and offer a controlled release profile is likely to have a major impact in enhancing patient compliance for better management of tuberculosis.

Novel chemotherapy for tuberculosis: chemotherapeutic potential of econazole- and moxifloxacin-loaded PLG nanoparticles.

The potential of econazole (ECZ) and moxifloxacin (MOX) individually against tuberculosis (TB) caused by multidrug-resistant and latent Mycobacterium tuberculosis has been demonstrated. In this study, poly-(dl-lactide-co-glycolide) (PLG) nanoparticle-encapsulated ECZ and MOX were evaluated against murine TB (drug susceptible) in order to develop a more potent regimen for TB. PLG nanoparticles were prepared by the multiple emulsion and solvent evaporation technique and were administered orally to mice. A single oral dose of PLG nanoparticles resulted in therapeutic drug concentrations in plasma for up to 5 days (ECZ) or 4 days (MOX), whilst in the organs (lungs, liver and spleen) it was up to 6 days. In comparison, free drugs were cleared from the same organs within 12-24h. In M. tuberculosis-infected mice, eight oral doses of the formulation administered weekly were found to be equipotent to 56 doses (MOX administered daily) or 112 doses (ECZ administered twice daily) of free drugs. Furthermore, the combination of MOX+ECZ proved to be significantly efficacious compared with individual drugs. Addition of rifampicin (RIF) to this combination resulted in total bacterial clearance from the organs of mice in 8 weeks. PLG nanoparticles appear to have the potential for intermittent therapy of TB, and combination of MOX, ECZ and RIF is the most potent.

Supplementation with RD antigens enhances the protective efficacy of BCG in tuberculous mice.

Different combinations of ESAT-6, CFP-10, CFP-21, MPT-64, encoded by RD1 and RD2 of Mycobacterium tuberculosis were evaluated on the basis of antigenicity in PPD positive TB contacts and immunogenicity in C57BL/6J mice immunized with the combination of all four RD antigens. The peripheral blood mononuclear cells of TB contacts showed maximum recognition in response to the combination of ESAT-6+MPT-64 in terms of predominant lymphoproliferation, IFN-gamma levels and the number of responders. On the contrary, the combination of ESAT-6+CFP-21+MPT-64 was found to be most immunogenic based on both T-cell and antibody responses in immunized mice. Prophylactic potential of the selected combinations was assessed as supplementation vaccines to BCG against intravenous challenge with M. tuberculosis in mice. BCG supplementation with the selected combinations resulted in significantly greater protection as compared to BCG alone against experimental tuberculosis and thus appears to be a promising approach to enhance the protective efficacy of the existing vaccine.

Tuberculosis subunit vaccine design: the conflict of antigenicity and immunogenicity.

The attempts to find an effective antituberculous subunit vaccine are based on the assumption that it must drive a Th1 response. In the absence of effective correlates of protection, a vast array of mycobacterial components are being evaluated worldwide either on the basis of their ability to be recognized by T lymphocytes in in vitro assays during early stage of animal or human infection (antigenicity) or their capacity to induce T cell response following immunization in animal models (immunogenicity). The putative vaccine candidates selected using either of these strategies are then subjected to challenge studies in different animal models to evaluate the protective efficacy. Here we review the outcome of this current scheme of selection of vaccine candidates using an 'antigenicity' or 'immunogenicity' criterion on the actual protective efficacy observed in experimental animal models. The possible implications for the success of some of the leading vaccine candidates in clinical trials will also be discussed.

Lung and blood mononuclear cell responses of tuberculosis patients to mycobacterial proteins.

The differences in specificity of human lung and peripheral lymphocytes for mycobacterial antigens (Ag) need to be evaluated in order to identify vaccine candidates against pulmonary tuberculosis (TB). Therefore, the present study examined the response to low molecular weight secretory proteins of Mycobacterium tuberculosis in bronchoalveolar lavage (BAL) and peripheral blood mononuclear cells (PBMCs) from minimal pulmonary TB and non-TB patients. Ag85A, Ag85B, culture filtrate protein (CFP)-31, CFP-22.5, CFP-21, M. tuberculosis protein-64 and an as yet uncharacterised 19 kDa protein were found to be predominantly recognised by BAL cells of TB patients on the basis of lymphocyte proliferation and significant interferon-gamma release. However, recognition of CFP-8, 6-kDa early secreted antigenic target, CFP-10, CFP-14.5, M. tuberculosis secretory protein-17 and five other as yet uncharacterised low molecular weight polypeptides was found to be high on the basis of lymphocyte proliferation at the level of PBMCs. Furthermore, BAL macrophages, and not blood monocytes, were found to produce nitric oxide (NO) in response to mycobacterial Ags. Among polypeptides predominantly recognised by BAL lymphocytes, only Ag85A and Ag85B were found to induce both NO and interleukin-12 (p40) by alveolar macrophages. In conclusion, the present results indicate heterogeneity in antigen recognition by bronchoalveolar lavage cells and peripheral mononuclear blood cells of minimal tuberculosis patients, and also suggest the utility of antigen 85 complex polypeptides for the development of a future mucosal antituberculous vaccine.

Antimycobacterial activity of econazole against multidrug-resistant strains of Mycobacterium tuberculosis.

This study evaluated the antimycobacterial activity of econazole against multidrug-resistant (MDR) strains of Mycobacterium tuberculosis. The minimum inhibitory concentration (MIC(90)) and minimum bactericidal concentration (MBC(>99.99)) against MDR strains were found to be 0.120-0.125 microg/mL and 0.125-0.150 microg/mL, respectively, demonstrating the antimycobacterial potential of econazole.

A multivalent combination of experimental antituberculosis DNA vaccines based on Ag85B and regions of difference antigens.

Two candidate DNA vaccines based on the proteins CFP10 and CFP21 encoded by regions of difference (RDs) of Mycobacterium tuberculosis were evaluated individually and in multivalent combination with the immunodominant protein Ag85B for induction of protective immune responses against experimental tuberculosis. Experimental DNA vaccines induced substantial levels of cell-mediated immune responses as indicated by marked lymphocyte proliferation, significant release of the Th1 cytokines IFN-gamma and IL-12 (p40), and predominant cytotoxic T cell activity. High levels of antigen-specific IgG1 and IgG2a antibodies observed in the sera of immunized mice depicted strong humoral responses generated by DNA vaccine constructs. The multivalent combination of three DNA vaccine constructs induced maximal T cell and humoral immune responses. All the experimental vaccines imparted significant protection against challenge with M. tuberculosis H(37)Rv (in terms of colony-forming unit reduction in lungs and spleen) as compared to vector controls. The level of protection exhibited by multivalent DNA vaccine formulation was found to be equivalent to that of Mycobacterium bovis BCG observed both at 4 and 8 weeks post-challenge. These results show the protective potential of the multivalent DNA vaccine formulation used in this study.

Azole antifungals as novel chemotherapeutic agents against murine tuberculosis.

The present study was designed to evaluate the in vivo antimycobacterial potential of econazole alone and in combination with antitubercular drugs against tuberculosis in mice. Econazole was found to reduce bacterial burden by 90% in the lungs and spleen of mice infected with 1 x 10(7) cells of Mycobacterium tuberculosis and was found to be equipotent to rifampicin. Further, our results indicate that econazole can replace rifampicin/isoniazid as well as both rifampicin and isoniazid in chemotherapy of murine tuberculosis. Econazole alone or in combination with antitubercular drugs did not produce any hepatotoxicity in normal or M. tuberculosis-infected mice.

Oral poly(lactide-co-glycolide) nanoparticle based antituberculosis drug delivery: toxicological and chemotherapeutic implications.

The present study reports on the detailed toxicological and chemotherapeutic evaluation of antituberculosis drug loaded nanoparticles in mice. A single oral dose administration of poly(lactide-co-glycolide) (PLG, a synthetic polymer) nanoparticles containing rifampicin+isoniazid+pyrazinamide+ethambutol could maintain drug levels in various tissues for 9-10 days and did not elicit any adverse response even when administered at several fold higher than the recommended therapeutic dose. However, dosing with conventional free drugs at the equivalent higher doses was lethal. Despite multiple oral dosing with the formulation at every 10th day, no toxicity was observed on the completion of subacute (28 days) or chronic (90 days) toxicity studies based on survival, gross pathology, histopathology, blood biochemistry and hematology. In mice harboring a high mycobacterial load (mimicking human tuberculosis), two independent chemotherapeutic regimens, i.e. 5 doses of PLG nanoparticles encapsulating (rifampicin+isoniazid+pyrazinamide+ethambutol) administered 10 days apart, or 2 doses of the 4-drug formulation followed by 3 doses of 2-drug formulation (rifampicin+isoniazid) resulted in undetectable bacilli. Further, the efficacy was comparable to 46 daily doses of oral free drugs. Therefore, the experimental evidence suggests that PLG nanoparticle-based antituberculosis drug delivery system is safe and well suited for prolonged and intermittent oral chemotherapy.

Chemotherapeutic efficacy of nanoparticle encapsulated antitubercular drugs.

Our objective was to evaluate the chemotherapeutic potential of oral poly lactide-co-glycolide (PLG, a synthetic polymer) nanoparticle encapsulated ethambutol in combination with PLG-nanoparticle encapsulated-(rifampicin + isoniazid + pyrazinamide) in a murine tuberculosis (TB) model. Our formulation was prepared by the multiple emulsion technique and administered orally to mice for the biodistribution, pharmacokinetic, and chemotherapeutic studies. A single oral administration of the formulation to mice could maintain sustained drug levels in the plasma for 5 days and in the organs (lungs, liver, spleen) for 7-9 days. There was a striking improvement in the pharmacokinetic parameters such as half-life and mean residence time as compared with free drugs. The relative/absolute bioavailability of the 4 antituberculosis drugs was enhanced several fold. Repeated administration of the formulation did not produce any hepatotoxicity as assessed on a biochemical basis. In M. tuberculosis H37Rv infected mice, just 3 oral doses of the 4-drug formulation administered at every 10th day resulted in undetectable bacilli in the organs replacing 28 conventional doses of free drugs. We concluded that polymeric nanoparticle based oral 4-drug combination bears significant potential to shorten the duration of TB chemotherapy, besides reducing the dosing frequency.

Nanotechnology based drug delivery system(s) for the management of tuberculosis.

The era of nanotechnology has allowed new research strategies to flourish in the field of drug delivery. Nanoparticle-based drug delivery systems are suitable for targeting chronic intracellular infections such as tuberculosis. Polymeric nanoparticles employing poly lactide-co-glycolide have shown promise as far as intermittent chemotherapy in experimental tuberculosis is concerned. It has distinct advantages over the more traditional drug carriers, i.e. liposomes and microparticles. Although the experience with natural carriers, e.g. solid lipid nanoparticles and alginate nanoparticles is in its infancy, future research may rely heavily on these carrier systems. Given the options for oral as well as parenteral therapy, the very nature of the disease and its complex treatment urges one to emphasize on the oral route for controlled drug delivery. Pending the discovery of more potent antitubercular drugs, nanotechnology-based intermittent chemotherapy provides a novel and sound platform for an onslaught against tuberculosis.

Expression and purification of the Mycobacterium tuberculosis complex-restricted antigen CFP21 to study its immunoprophylactic potential in mouse model.

Secreted proteins encoded by different regions of difference (RDs) from the genome of Mycobacterium tuberculosis have been considered as attractive candidates for vaccination against tuberculosis owing to their absence in most BCG strains. In this study, the structural gene for the RD2 locus encoding protein CFP21 was PCR amplified and expressed as a fusion protein with hexahistidine residues in Escherichia coli. Expression of CFP21 in E. coli under transcriptional regulation of the T7 promoter yielded a protein located within inclusion bodies. The inclusion bodies were solubilized in the presence of 8M urea and the protein was purified to homogeneity under denaturing conditions at low pH using nitrilotriacetic acid (Ni-NTA) affinity chromatography. The denatured protein was renatured by gradient dialysis against a decreasing concentration of urea. The purified protein was shown to have esterase activity. CFP21 protein was evaluated for immunogenicity in C57BL/6J mice. We observed an elevated T cell proliferative response and production of IFN-gamma and IL-12 (p40). CFP21 also induced an optimum level of cytotoxic T cell activity and induced a strong humoral response as indicated by higher levels of specific IgG1 and IgG2a antibody isotypes. In addition, a moderate level of protection was observed against experimental tuberculosis. This is the first report describing esterase activity of the M. tuberculosis complex-restricted protein CFP21 and its protective potential against experimental tuberculosis.

Oral nanoparticle-based antituberculosis drug delivery to the brain in an experimental model.

OBJECTIVES: To evaluate the potential of orally administered poly-lactide-co-glycolide (PLG, a synthetic polymer) nanoparticle encapsulated antituberculosis drugs (ATDs) (rifampicin + isoniazid + pyrazinamide + ethambutol) for cerebral drug delivery in a murine model. METHODS: The formulation was prepared using the multiple emulsion technique and administered orally to mice for biodistribution, pharmacokinetic and chemotherapeutic studies. RESULTS: A single oral dose of the formulation to mice could maintain sustained drug levels for 5-8 days in the plasma and for 9 days in the brain. There was a significant improvement in the pharmacokinetic parameters such as mean residence time and relative bioavailability as compared with free drugs. The pharmacodynamic parameters such as the ratio of area under the curve to minimum inhibitory concentration (AUC/MIC) and the time up to which MIC levels were maintained in plasma (T(MIC)) were also improved. In Mycobacterium tuberculosis H(37)Rv infected mice, five oral doses of the nanoparticle formulation administered every 10th day resulted in undetectable bacilli in the meninges, as assessed on the basis of cfu and histopathology. CONCLUSIONS: Polymeric nanoparticles bear significant potential for ATD delivery to the brain.

Protective efficacy of intranasal vaccination with Mycobacterium bovis BCG against airway Mycobacterium tuberculosis challenge in mice.

The effect of route of immunization on the protective efficacy of BCG against tuberculosis has been investigated. Immunoprotection was monitored by evaluating the bacterial burden in the lungs and spleen of mice challenged with Mycobacterium tuberculosis H(37)Rv after BCG immunization by intranasal (i.n.) and subcutaneous (s.c.) routes. Our results showed that as compared to s.c. BCG immunization, intranasal BCG vaccination induces significantly higher immune responses at local level (mediastinal lymph nodes, cervical lymph nodes and lung). Further, i.n. BCG vaccination induced significantly higher reduction in bacterial load in the lungs over s.c. BCG vaccination, whereas, the bacilli load in the spleen was comparable in both the groups. Hence, intranasal vaccination with BCG holds promise for pulmonary tuberculosis.