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In Vivo Efficacy Evaluation of INM-4801-A Against Nosocomial Pathogens Using Escherichia Coli As The Model Organism
1. In Vivo Efficacy Evaluation of
INM-4801-A Against Nosocomial
Pathogens Using Escherichia
Coli As The Model Organism
PRESENTATED BY:
Komal Siddhartha
2. In Vivo Efficacy Evaluation of INM-4801-A
Against Nosocomial
Pathogens Using Escherichia Coli As The Model
Organism
PRESENTATED BY:
Komal Siddhartha
M. Pharm
Pharmacology- IInd Year
Roll No- 6433
SUPERVISOR
Dr. Gaurav Kaithwas
Assistant Professor
Dept. of Pharmaceutical
sciences
BBAU, Lucknow
SUPERVISOR
Dr. Raman Chawla
Scientist ‘D’
Dept. of CBRN defence,
INMAS, DRDO, Delhi
3. • Nosocomial comes
from the Greek
words “nosus”
which means
disease and
“komeion” which
means to take care
of.
• Also called as
“Hospital Acquired
Infection”
MEANING
• Infections are considered
nosocomial if they first
appear 48hrs or more
after hospital admission
or within 30 days after
discharge
• Approx 9% of patients
will suffer from an
infection whilst in
hospital – risk increases
with length of stay
DEFINITION • The host:
Immunocompromised
• Microbes:opportunistic
pathogens
• The environment:
Infected patients
• Traffic of staff and visitors
• Blood products
• Surgical instruments
• Treatment : Usage of
antibiotics
FACTORS
Its high time to demystify and combat these nosocomial pathogens by using
herbal plants and their derivatives as alternative treatment modalities
??.....
Spreads of Nosocomial
infection
1
4. The increasing trend of nosocomial infection has now become a serious
problem leading to the emergence of dreadful strains of microorganisms which
are difficult to manage.
Crude extracts of medicinal plants stand out as veritable sources of potential
antimicrobial agents as they have been found to contain wide variety of
antimicrobial secondary metabolites, such as tannins, terpenoids, alkaloids, and
flavonoids.
Thus, plant products identified for such infections by using bioprospection
evidence based matrix modelling approach and molecular docking of
phytoligands, was evaluated for their efficacy at in vivo using murine model
system.
2
5. Objectives:
In silico Bioprospection model for identification of promising antimicrobial of
herbal origin against highly virulent strain of nosocomial infection
Molecular docking analysis of predominant phytoligands for identification of
promising antimicrobial of herbal origin against highly virulent strain of
nosocomial infection
To evaluate Maximum Tolerable Dose of the given herbal extract INM-4801A
To evaluate Therapeutic Dose of INM-4801-A at in vivo level against highly
virulent strain of nosocomial infection
To conduct the Pharmacokinetics studies on the given predominant
phytoconstituent INM- 4801-A
Aim: In Vivo Efficacy Evaluation of INM-4801-A Against Nosocomial
Pathogens Using Escherichia Coli As The Model Organism
3
6. 1.BIOPROSPECTION
Selection of microorganism
Selection of bioactivity virulent factor using classical approach
Selection of herbal plants using classical bioprospection approach
Binary coefficients matrix to evaluate the presence/ absence of virulent factor in selected plants
Fuzzy set membership analysis for decision matrix
Optimization of decision matrix score
2.MOLECULAR DOCKING
Retrieval of 3D structure of OXA-23 beta lactimase Receptor
Preparation of Ligand Database
Active Site Analysis
Ligand Receptor Docking (Hex 6.8)
Toxicity Predictive Analysis
3. IN VIVO DOSE EFFICACY
Evaluation of Maximum Tolerable Dose of INM-4801-A
Evaluation of Therapeutic Dose of INM-4801-A
Pharmacokinetic study of predominant phytoconstituent INM-4801-A
Radiolabelling of pure compound using technetium-99m
Instant chromatography (iTLC) of radiolabelled drug for stability studes
In vivo pharmacokinetic studies-
I. Half life (t/2)
II. Elimination rate constant (ƛ),
III. Bioavailability
IV. Rate of clearance
4
7. INM-4801-A
Common name:
Indian barberry is medicinal plants used in various diseases. In differene
language it is commonly called darhaldi (Bengal), chitra, darhald, rasaut, (Hindi),
maradarisina, (Kerala), daruhald(Maharashtra), daruharidra, pitadaru, (Sanskrit)
Scientific Classification
Botanical name: Berberis aristata
Kingdom: Plantae
Family: Berberidaceae
Order: Ranunculales
Genus: Berberis
Species: aristata
Synonyms: B. chitria. B. coriaria
Common name: Chitra, Daru haldi Indian Barberry or
5
8.
9. The classical herbal bioprospection is a technique identification of medicinal plants based on its
ethnopharmacological importance, as testified in ancient literature or otherwise in clinical literature of various
countries. This process is time consuming, tedious, generally observation or experience based
Evolution of new techniques of deploying dynamic search protocols, priority indexing, systemic categorization
and cross-verification could be referred to as an in silico bioprospection
Procedure of in Silico Bioprospection
1.Selection of Microorganism: on the basis of some important characteristics i.e., a) either no treatment
regime/vaccine available or limited availability; b) evolving virulent forms from past e.g. A. baumannii
2.Selection of Bioactivity Parameter: Five parameters selected based on mechanistic aspects of antibiotic
resistance of A. baumannii, including Biofilm formation, MDR efflux Pump, Outer membrane protein (OmpA),
OXA-23 beta lactimase and AbaR Type resistance islands
3. Evaluation of Relevance Factor Using “Keywords hits scoring Matrix” Approach:
The analysis was conducted by PubMed as selected search engine. The random search model using
combination keyword as “Bioactivity Parameter + Antimicrobial activity” yielded ‘N’ hits. The first n=20 hits
provided by the search engine, working on the principle of priority indexing
This analysis was used to evaluate the net weightage linked to each virulence factor,
Average Percentage Relevance = No of relevance hits * N×100
(n=20)
4.Selection of Herbal Plants Using Classical Bioprospection Apporach :
The classical bioprospection approach accounts for investigation of the following variables based on literature
review to devise a logical conclusion, resultant in selection of plants
It includes a) Ethnopharmacological importance of plant; b) Relevance of Herb in traditional medicine; c)
Availability factor in localized regions; d) Any vedic literature supporting its use; e) Investigations/ prior
experience on potential of the herb; f) Indirect indications,
6
10. 5. Binary Coefficient matrix to Evaluate the presence / absence of Virulent factor in selected plants:
This methodology works on the principle of 0-1 binary code of absence/presence of a particular parameter in
selected plants from previous step. The range of outcome of matrix lies between 1 to 5 for any plants.
Based on this, all the plants having more than 03 parameters, reported in PubMed search engine (n= first 20
hits) against ‘Bioactivity Parameter + Selected Plant’ random search model, were selected
6. Weightage Matrix Based Analysis:
This step includes evaluation of overall weightage of plants (Scores > 3 in previous step) by multiplying their
binary score with weightage obtained in Step No.5. This is a primary step to screen the plants utilizable to
subsequent analysis and removes fake positive results attributed towards investigator’s
Formula = Total Parameter (5)× obtained no of parameter in selected plants( n=1,.5)
Max. % relevance of a parameter
This step identifies potential plant leads based on in silico bioprospection approach subjected to fuzzy set
membership analysis and optimization to validate the findings
7.Fuzzy Set Membership Analysis Decision matrix:
In this approach, the given mathematical relationship was used to calculate the relevance of the variety/product;
μS = S-min(S)/[max(S)-min(S)]
Where: μS represents the desirability values of members of the fuzzy set S. Min(S) and max(S) are minimum
and maximum values, respectively, in the fuzzy set S
8. Optimization of Decision Matrix Score: In this approach the numerical value of scores obtained were
converted into a leveled score by using a scaled magnitude represented by a symbol
7
11. 1.Retrieval of 3D structure of OXA-23 beta lactamase Receptor
The experimental 3D tertiary structure of OXA-23 beta lactamase of Acinetobacter baumanii was
retrieved from the RCSB Protein Data Bank as pdb file and Hydrogen atoms were introduced into
the enzyme structure using Argus Lab to customize it as the receptor molecule for rigid docking
2.Preparation of Ligand Database
The predominant phytoconstituents and standard chemotherapeutic agents were drawn using
ACD Chemsketch
Hydrogen atoms were introduced into the ligand structure using Argus Lab to customize them for
rigid docking
The hydrogenated ligand molecules were then converted into pdb format using Open Babel
interface as required for rigid docking
3.Active Site Analysis
DoG Site Scorer, was used to predict the possible binding sites in the 3D structure of OXA-23
receptor
Predictions were based on the difference of gaussian filter to detect potential pockets on the
protein surface.
Procedure:
Docking is the identification of low energy binding mode of ligand within the active site of a
receptor or macromolecule whose structure is known
Categories of Docking: 1) Protein-ligand docking 2) Protein-Protein Docking
Type of Molecular docking: 1)Rigid Docking 2) Flexible Docking
Docking Programe: MOE-DOCK; FRED; FLOG; Hex 6.2; AADS etc
8
12. 4.Ligand Receptor Docking (Hex 6.8)
Receptor and Ligand files were imported in the Hex 6.8 software. Graphic settings and Docking
parameters were customized as follows and rigid docking was performed. E values of the
docking predicted the free energy of docking, which served as the basis for ranking
phytoligands in increasing order of their docking abilities
The parameters used for the docking process were:
a. Correlation type: Shape and Electro only
b. FFT mode: 3D fast lite
c. Grid Dimension: 0.8
d. Receptor range: 180°
e. Ligand range: 180°
f. Twist range: 360°
5. Toxicity Predictive Analysis
Toxicity prediction analysis of predominant phytoconstituents was conducted using consensus
clustering prediction methodology in rat model system (www.epa.gov/nrmrl/std/qsar/TEST).
Oral Lethal Dose (LD50), Bioaccumulation factor, Developmental toxicity and Mutagenicity of
the ligand were used as the descriptors to filter the predominant phytoligands on the basis of
being toxicants or non-toxicants respectively.
Subsequently, global properties, describing the size, shape and chemical features of the
predicted pockets were calculated so as to estimate simple score for each pocket, based on a
linear combination of three descriptors i.e., volume, hydrophobicity and enclosure
For each queried input structure, a druggability score between 0-to-1 was obtained.
Higher the druggability score, higher the physiological relevance of the pocket as potential
target
9
13. FLOW CHART 1 : CALCULATION OF LETHAL DOSE (L.D. 50)
Up & Down Method
Two Rat injected
with a particular dose ‘X’
Observed for a period of 24Hrs for any mortality
Rat Dies Rat Lives
Increase the Dose
by a factor of 1.5
≈ (X + 1.5X)
Decrease the Dose
by a factor of 0.7
≈ (X – 0.7X)
Maximum Non Lethal DoseMinimum Lethal Dose
10
14. FLOW CHART 2 : TYPE I OF UP & DOWN TEST
The Limit Test – Performed when test material is expected to be non toxic
Injected with 2000mg/kg dose
Observed for a period of 24Hrs for any mortality
Rat Dies Rat Lives
Inject 4 Rats with same
dose – 2000mg/kg
Conduct the Main Test
3 or more rat dies3 or more rat survives
L.D. 50 is more than 2000mg/kg L.D. 50 is less than 2000mg/kg
Conduct the Main Test
Or More
Or More
OECD Guideline : 420 and 425 11
15. 1.Experimental groups and drug administration
Single dose, acute toxicity studies were conducted. Group 1 served as the control group (Peptone
water) and the other groups II, III, IV and V were treated with the INM-4801-A (100, 200, 500, 700,
1000 and 2000mg/kg) respectively.
Before commencing the experiment, the body weight of rats were recorded. All animals except
group I were administered with a single oral dose of INM-4801-A at 100, 200, 500, 700, 1000 and
2000mg/kg body weight.
2.Behavioral study
After dosing, all animals in this study were observed for gross behavior parameter at 1h, 2h, 3h,
24h and 48 h.
The observed result was recorded as sign of toxicity/number of animals studied. Signs of
toxicity and mortality were observed daily for 7 days and were monitored daily for change in body
weight
3. Hematological parameter
On 8th day, blood was collected from retro orbital method from all animals. The hematological
parameters were determined using an hematological analyzer.
4.Dose Efficacy Study
Efficacy studies were performed using INM-4801-A by assessing the microbial load of control
group rats (vehicle) as well as the inoculated group rats (108 CFU/mL of Escherichia coli) which
were then compared to the microbial counts obtained after treatment with a given concentration of
the herbal extract, administered orally.
This was done for different concentration of the INM-4801-A i.e. 0.5, 1, 2, 4 & 8mg/kg.
12
16. FLOW CHART 3 : ASSESSMENT OF EFFECTIVE DOSE
Collect Urine/Blood Sample of Mice
for Microbial Load Assessment
on every 24 Hrs.
Mice Lives
Herbal Extract was
effective at the
given concentration
Mice Dead
Herbal Extract was
Found to be
ineffective
Microbial Inoculum Herbal Extract Dilutions
INM-4801-A dilutions
given to different sets of mice
Observed till
Lethality
Period
Assigned as Effective Dose
17. Pharmacokinetics parameters of the given predominant phytoconstituents INM- 4801-A was
evaluated using Pharmacoscintigraphy
Pure compound was tagged with radioactive 99Tc (technetium) and its tagging efficiency was
monitored by iTLC (instant chromatography). Tagged active compound was then administered
intravenously in given sets of rats and its accumulation in vivo was assessed by calculating the
radioactivity in blood samples collected at periodic intervals
1.Radiolabelling of pure compound using technetium-99
1gm pure INM- 4801-A was weighed accurately, and then dissolved in an appropriate
solvent (0.5mL of distilled water).
200µl of stannous chloride and hydrochloric acid stock solution was added into INM-4801-A
solution.
The above solution pH was then adjusted to 7 using 1N sodium hydroxide (NaOH) solutions.
Finally, volume was made up to 1mL using distilled water.
Few drops of sodium pertechnetate solution (20mCi) were then added so as to introduce the
radionuclide into the reaction mixture and then the reaction mixture was kept aside for 30
minutes.
2.Instant chromatography (iTLC) of radiolabelled drug for stability studies
A single minute spot of the radiolabelled drug was spotted onto the iTLC strip and was
allowed to dry.
The strip was then suspended into a pre saturated beaker containing acetone as mobile
phase.
The mobile phase was allowed to run 1/3rd of the strip and then strip was removed carefully
from the mobile phase.
13
18. 3.In vivo pharmacokinetics studies
1ml of the stably radiolabelled drug was administered intravenously into the given sets of rats
(3rats).
After an interval of 30 minutes, blood sample was collected and radioactivity count was
assessed using a gamma counter and calibrator. This step was repeated after 30 minutes for 5
consecutive intervals.
Amount of radioactivity at each time interval is directly proportional to the drug present in
body.
Graph of radioactivity versus time was plotted and used to calculate t1/2, elimination rate
constant , bioavailability and rate of clearance
The strip of iTLC was divided into the upper 1/3rd and lower 2/3rd portion and cut
accordingly.
Radioactivity count was assessed for both upper and lower portions. If the lower portion
shows higher counts as compared to the upper portion then it can be said that the drug is
bound to the radionuclide , making the moiety heavier and hence the moiety reside in the
lower portion of the iTLC strip owing to an higher counts of radioactivity in the lower portion.
Same iTLC procedure was repeated after every 1hr., so as to assess the extent of drug
radiolabelling with the ensuing time
14
19.
20. 1.Keywords Hits Scoring Matrix
On the basis of the keyword hits scoring results weightage was given to various
parameters selected for screening of herbal plants with respect to antimicrobial activity
Weightage was decided according to the percentage relevance obtained for each
parameter
Table 1: Relative weightage for each parameter assigned on the basis of percentage
relevance
S.No. Parameter selected Total hits Hit score Relatives %Relevance
1 Beta lactamase inhibitor 22 20 7 35%
2 MDR pump inhibition 103 20 5 25%
3 Outer membrane protein
OmpA inhibition
26 2 4 20%
4 Biofilm formation inhibition 35 20 3 15%
5 AbaR-Type Resistance
Island
20 20 1 5%
15
21. 2.Binary (Presence-Absence) Coefficients Matrix
Out of 46 plants selected from ethanomedicinal data, 24 plants were
shown to contain either 3 or more than 3 characteristic and hence
illustrated a better score as compared to other plants e.g. Eucalyptus
globules, Thymus vulgaris, Menthe piperita, Andrographis paniculata,
Camellia sinensis, Rosmarinus officinalis, Punica granatum, Terminalia
arjuna, Lawsonia inermis and Allium sativum, Zingiber officinale
30
5
24 Plants with Binary Matrix score 1
plants with Binary Matrix score 2
Plants with Bainary Matrix score >3
Figure 1: Binary Matrix Scores for Herbal Plants
16
22. Out of 24 plants
Selected (on the basis
of binary coefficient
matrix)
In which 11 plants
has higher combined
weightage score
And show immence
potential of acting as
theraputic agents against
Nosocomial infection
3.Simple Additive Weightage Matrix
Table 2: Weightage Matrix Scores for herbal plants screened on the basis of binary matrix scores
(Scores > 3)
Herbl Plant
(Weightage)
β- lactamase
inhibition
(5)
MDR pump
inhibition
(3.57)
Outer membrane
protein inhibition
(2.85)
Biofilm
formation
inhibition (2.14)
AbaR
Resistance
Island (0.71)
Total
weightage
Thymus vulgaris + + + + _ 13.56
Mentha piperita + + + + _ 13.56
Camellia sinensis + + + + _ 13.56
Eucalyptus
globules
+ + + + _ 13.56
Rosmarinus
officinalis
+ + + + _ 13.56
Nelumbo nucifera - + + + _ 8.56
Punica granatum _ + + + 8.56
Terminalia arjuna + + + _ + 12.13
Allium sativum + + _ + _ 10.71
Lawsonia innermis + _ + + - 9.99
Andrographis
paniculata
_ + _ + + 6.42
17
23. On the basis of Decision
matrix and optimized
score value of 11 plants S.No. Herbal Plant µS* Optimized Score
1 Rosmarinus officinalis 6.67 ++++( 4)
2 Eucalyptus globules 6.67 ++++(4)
3 Thymus vulgaris 6.67 ++++(4)
4 Menthe piperita 6.67 ++++(4)
5 Camellia sinensis 6.67 ++++(4)
6 Nelumbo nucifera 6.67 ++++(4)
7 Terminalia arjuna 5.23 +++(3)
8 Allium sativum 3.83 ++(2)
9 Lawsonia inermis 3.09 ++(2)
10 Andrographis
paniculata
0.47 +(1)
4. Fuzzy Set Membership Decision Matrix & Optimized Scoring
6 plants found higher %
relevance to be chosen
as potent agents
against NI
Among these
Rosmarinus officinalis,
Eucalyptus globules,
Thymus vulgaris
Menthe piperita, Camellia
sinensis, Nelumbo
nucifera
Held topmost position
with 100% relevance
Table 3: Fuzzy Set Membership Analysis for herbal plants
screened on the basis of Weightage Matrix scores
18
24. 1.Active Site Analysis
Active site analysis using Dog Site Scorer revealed that pocket P0 of the OXA-23 beta –
lactamase enzyme was found to be energetically favorable for performing molecular
docking studies, attributed to its descriptors (Figure 3), i.e., larger surface area, greater
depth, less solvent-exposed surface, spontaneity of binding and higher hydrophobic
character than other pockets .
Table4: Pocket Discriptor Table of OXA-23 beta lactamase enzyme
19
25. Figure 3: P0 pockets of OXA-23 beta lactamase of
MDR Acinetobacter baumanii with their
descriptors (volume, surface and depth) and
scores based on Active Site Analysis using DoG
Site Scorer
Figure 2: 3D structure of OXA-23
beta lactamase of MDR
Acinetobacter baumanii
20
26. 2.Docking of Receptor and Ligand using Hex 6.8
The process of classifying phytoligands that are most likely to interact with a
particular receptor is based on the predicted free-energy of binding
Lowering the value of free energy change (E value) promotes spontaneity of
binding interaction between the predominant phytoligand and targeted receptor
Energy of docking (E values) was calculated using Hex 6.8 and revealed
predominant phytoconstituents, including Punicalin, Arjunolic acid, Epicatechin
gallate, Catechin, Andrographolide, Luteolin, ellagic acid and nuciferin; which have
an E value in the range: -309.31 to -250.99 Kcal/mol
These natural plant products exhibited significant ability (p < 0.05) to inhibit
Acinetobacter baumanii as compared to standard chemotherapeutic inhibitors
namely Meropenem (-268.02); Imipenem(-264.89); Tazobactam (-238.04 Kcal/mol)
and Clavulanic acid (-213.86 Kcal/mol), (Table 5; Figure 4)
21
28. Figure 4: 3D Ribbon structure of OXA-23 beta-lactamase docked with punicalin as most
active phytoligand from Punica granatum (Anar) with E value = -309.31Kcal/mol evaluated
using Hex 6.8
23
29. 3.In Silico Toxicity Prediction of Ligands
In silico toxicity prediction analysis revealed that 22% out of the selected
phytoligands (~13) were found to be non toxic on the basis of their higher Lethal
Dose (Oral rat LD50). Highest LD50 was found in case of Punicalin (7727.39 mg/kg)
17% of the selected phytoligands exhibited low bioaccumulation factor with
lowest in case of Andrographoloid (0.9 units)
11% of phytoligands were found to be non-toxic on the basis of their negligible
developmental toxicity while 50% were found to be non- mutagenic, as given in
Figure5.
22%
17%
11%
50%
Non Toxic (High LD50)
Negligible
Bioaccumulation
Developemental Non
Toxicant
Non Mutagenic
Figure 5: Categorization of pre-dominant Phytoligands (~13) based on Lethal Dose
(50%); Bioaccumulation Factor; Developmental toxicant; Mutagenicity
24
30. Figure 6: Optimization of identified potent leads with their respective E-values vs. LD50 as
decision-aid toxicity predictive descriptors
0
1
2
3
4
5
6
7
8
9
10
Values
E Value of Phyto-Ligands
Bioaccumulati
on
Mutagenicity
Developmental
Toxicity
Figure 7: Optimization of identified potent leads with their respective E-values vs. Bioaccumulation
Factor, Mutagenicity and developmental toxicity as decision-aid toxicity predictive descriptors.
0
1000
2000
3000
4000
5000
6000
7000
8000
9000
OralLD50
E-Value of Phyto-Ligands
LD50
25
31. 1.Gross Behavior study
No signs of toxicity were observed, in the control or treated groups.
Diarrhoea was observed in male rats at the dose of 2000 mg/kg at 1 h, 2 h and 3 h.
After 24 h all the animals were normal
Body weight changes are indication of adverse effects of drugs and chemicals
and it will be significant if the body weight loss is more than 10% from the initial
body weight occurred
Body weight changes statistically not significant when compared to the control
group
2.Body Weight
Group No Dose (mg/kg) Weight in gram
DAY 1 DAY 2 DAY 3
Group 1 0 (Vehicle) 259±4.86 262.4±8.96 263.4±5.49
Group 2 100 mg/kg 260.±1.85 263±2.28 267.2±1.72
Group 3 500 mg/kg 259.4±2.72 262.2±2.4 266.4±2.15
Group 4 1000 mg/kg 261.8±4.17 265.4±3.22 269.4±1.62
Group 5 2000mg/kg 261.8±3.0 264±2.60 267.8±2.31
Table 7: Mean body weight of rats at different doses of INM-4801-A
32. 255
256
257
258
259
260
261
262
263
264
265
Control group 2 (100mg/kg) group 3(500mg/kg) group 4 (1000mg/kg) group 5 (2000 mg/kg)
weightingm
Day 1
Day 7
Day 14
Figure 8: Mean body weight of rat at different doses of INM-4801-A
27
3.Hematological parameters
Blood parameters analysis is relevant to risk evaluation as the haematological
system has a higher predictive value for toxicity in humans (91%) when assay
involve rodents and non-rodents.
Haematological analyses (haemoglobin, red blood cell, leukocyte), HCT,
monocytes, lymphocytes, eosinophils and platelet counts) all the parameters were
statistically not significant when compared to the control group
33. Table 8: Hematological parameter of acute toxicity study of INM-4801-A in male Sprague
dawley rats
Parameters Control 100mg/kg 500mg/kg 1000mg/kg 2000mg/kg
WBC
(103/mm3)
11.06±1.38 11.70±1.67 13.32±1.15 13.04±1.91 12.69±2.67
RBC
(106/mm3)
7.77±0.36 6.29±1.62 7.65±0.53 7.65±0.55 7.28±1.62
HGB (g/dl) 14.68±1.16 14.59±0.80 14.05±1.25 13.25±2.20 14.58±0.80
HCT % 32.77±2.64 31.17±4.80 30.07±4.11 32.81±2.62 32.17± 4.80
PLT (103/ml) 700.8±51.84 700.6±16.54 705.2±37.34 709.6±27.17 700.6±16.54
LY (103/mm3) 80.74±4.21 78.35±6.63 81.15±2.85 78.76±4.90 79.35±6.63
MO (103/mm3) 4.77±0.27 3.42±0.43 3.164±0.27 3.97±0.50 3.42±0.43
EO (103/mm3) 0.68±0.24 0.74±0.21 0.692±0.23 0.63±0.23 0.64±0.21
No Adverse Effect observed up till 2000mg/Kg - Designated as Maximum Tolerated Dose
34. Table 9: List of Different Dose Efficacy Parameters Evaluated
Dose mg/kg Days Weight Body Temperature MacConky agar MHA
0.5mg/kg
Day 0 259±1.89 96±0.23 0 103± 1.63
Day 1 243.33±1.1 106±1.2 10.33±1.24 117.33±2
Day 2 245±1.56 103±0.3 8± 1.21 109±6.48
Day 3 248.6±1.4 100±0.3 7.33±1.24 106.67±6.18
Day 4 252±2.1 99± 0.22 3.67±1.24 105±5.71
Day 5 257.66±1.22 97±0.21 1±0.81 94±3.74
1mg/kg
Day 0 257.67±1.24 97±0.24 0 105.33± 2
Day 1 242.33±2 104±0.9 13±1.24 114.67±2
Day 2 247.3±1.24 100±0.3 9±1.54 109±1.63
Day 3 248±1.63 98±0.31 3.33±1.24 97±1.63
Day 4 253.67±1.24 96± 0.42 0.33±0.47 92.67±2
Day 5 256±1.63 96±0.21 0.3±0.47 82±1.63
2mg/kg
Day 0 259.33±1.24 96±0.12 0 104±1.63
Day 1 243±1.34 105±0.4 12±1.63 117.67±1.24
Day 2 246± 1.24 103± 0.4 9±1.34 110.33±1.24
Day 3 248.7±1.24 101±0.4 7±0.81 105.3±3.09
Day 4 252.1±1.24 98±0.11 3±0.81 102±2.44
Day 5 256.23±1.52 97±0.10 0.33±0.3 86.67±1.24
4mg/kg
Day 0 259.12±1.24 96±0.23 0 105±2.16
Day 1 244±1.90 106±0.2 10±1.21 116±1.24
Day 2 246±1.23 104±0.2 8±1.64 109.67±3.29
Day 3 249.1±1.24 102±0.31 6±0.81 104.33±2.62
Day 4 253.7±1.24 97±0.42 4.33±0.4 102.67±2.05
Day 5 257.11±1.24 97±0.12 0.47 90±1.63
35. Table 10: In vivo rate of clearance of INM-4801-
A of Group 1
Time
(min)
Radioactivity in
rat blood(µCi)
Radioactivity in rat blood
with background (µCi)
30min 0.82 9.62
120min 0.30 9.0
180min 0.12 8.60
240min 0.02 8.20
300min 0.0 8.00
30
120
180
240
300
y = -0.006x + 9.755
7.8
8
8.2
8.4
8.6
8.8
9
9.2
9.4
9.6
9.8
0 100 200 300 400
AmountofRadioactivity
(µCi)
Time (min)
Figure9: In vivo clearance rate of INM-4801-A in
Group 1
Table 11: In vivo rate of clearance of INM-
4801-A of Group 2
Time
(min)
Radioactivity in
rat blood(µCi)
Radioactivity in rat blood
with background (µCi)
30min 0.90 9.4
120min 0.40 9.1
180min 0.22 8.7
240min 0.12 8.3
300min 0.03 8.0
y = -0.005x + 9.638
7.8
8
8.2
8.4
8.6
8.8
9
9.2
9.4
9.6
0 100 200 300 400
AmountofRadioactivity
(µCi)
Time (min)
Figure10: In vivo clearance rate of INM-4801-A
in Group 2
29
36. Table 12: In vivo rate of clearance of INM-
4801-A in Group 3
Time
(min)
Radioactivity in rat
blood(µCi)
Radioactivity in rat blood
with background(µCi)
30min 0.85 9.8
120min 0.30 9.3
180min 0.20 9.1
240min 0.16 8.6
300min 0.07 8.2
30
120
180
240
300
y = -0.005x + 10.02
7.8
8.3
8.8
9.3
9.8
10.3
0 50 100 150 200 250 300 350
AmountofRadioactivity
(µCi)
Time (min)
Figure11: In vivo clearence rate of INM-
4801-A in Group3
Table 13: List of Different Pharmacokinetic
Parameters calculated
Parameter Rat 1 Rat 2 Rat 3 Mean±S.D
Half life(t1/2)*
(Min)
113.60 138.6 138,6 126±12.5
AUC(m2)** 3.32 3.51 4.72 3.85±0.62
Elimination
rate rate
constant***
0.141 0.149 0.10 0.13±0.02
MRT(min)***
*
7.09 6.711 10 7.93±1.47
Bioavailabili
ty in %*****
42.13 47.06 42.48 43.89±2.25
Rate of
clearance****
**(L/min/Kg)
0.1269 0.1341 0.09 0.11±0.01
30
37. Based on the results of the present studies, following conclusions can be drawn.On the
basis of bioprospection in silico modelling revealed that 11 out of 46 plants have maximum
potential to inhibit nosocomial infection caused by MDR A.baumanni.
Phytoligand of these 11 plants was further study by molecular docking and. On the basis of
Molecular docking we found that the punicalin as most active Phytoligand bind to the
same active site OXA-23 with lower binding energy ( E value = -309.31 Kcal/mol) than
standard inhibitor
.
In silico toxicity prediction analysis revealed that highest LD50 was found in case of
Punicalin (7727.39 mg/kg). Andrographaloid (0.9 units) exhibited low bioaccumulation
factor. 11% of phyto-ligands were found to be non-toxic on the basis of their negligible
developmental toxicity while 50% were found to be non- mutagenic.
In acute toxicity study we found that herbal extract INM-4801A was not toxic even at
2000mg/kg and Minimum Inhibitory concentration of INM-4810A was found to be 1mg/kg.
Overall, it may be suggested that as resistance to old antibiotics spreads, the development
of new antimicrobial agent of herbal origin may be useful as potential antimicrobial agents.
However, further research for the validation is still required
31
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