Isobolographic Method and Invertebrate (Planarian) Model for Evaluating Combinations of Waterways Pollutants

doi:10.4236/pp.2012.34051

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Pharmacology & Pharmacy, 2012, 3, 381-387

http://dx.doi.org/10.4236/pp.2012.34051 Published Online October 2012 (http://www.SciRP.org/journal/pp) 1

Isobolographic Method and Invertebrate (Planarian)

Model for Evaluating Combinations of Waterways

Pollutants

Robert B. Raffa1*, Deborah A. Gallo2, Christopher S. Tallarida1,3, Scott M. Rawls3,

Ronald J. Tallarida3

1Department of Pharmaceutical Sciences, Temple University School of Pharmacy, Philadelphia, USA; 2United States Public Health

Service, Tsehootsooi Medical Center, Fort Defiance, USA; 3Department of Pharmacology, School of Medicine, Center for Substance

Abuse Research, Temple University, Philadelphia, USA.

Email: *robert.raffa@temple.edu

Received July 5th, 2012; revised August 13th, 2012; accepted September 14th, 2012

ABSTRACT

Agricultural, pharmaceutical, and other biologically active substances are emptied or leach into waterways and ground-

water, where they can dose-relatedly cause pharmacologic or toxic effects on the resident or dependent animal species.

Standard methods can be used to evaluate the effects of individual substances, but evaluation of combinations of sub-

stances is more difficult. The mathematically rig orous method of isobolographic analysis was coupled with a simple in

vivo invertebrate model. Planarians were selected because they are the lowest extant species with a centralized nervous

system. Neostigmine bromide and monopotassium phosphate (KH2PO4) were selected as representative of two types of

potential pollutants. Neostigmine bromide and KH2PO4 individually produced dose-related lethality over a 60-minute

observation period with LD50 values of 122 an d 70 mM, respectively. The LD50 value of a 1:1 combination of the two

was significantly different (p < 0.05) from the isobologr aphic line of additivity. We used planarian s as a representative

fresh-water species and joint-action (“isobolographic”) analysis to examine possible interaction between pollutants. In

the demonstrative example reported here, there was a subadditive interaction between a 1:1 fixed-ratio combination of

neostigmine bromide (as a representative acetylcholinesterase inhibitor used in pesticides) and potassium phosphate

(used in fertilizers and detergents).

Keywords: Combinations; Isobolographic Analysis; Methods; Pollutants; Planarians

1. Introduction

The extent to which active pharmaceutical ingredients

(APIs) are present in aquatic environments was revealed

in 2004 during the first nationwide survey of pharmaceu-

tical compounds detected in surface waters (rivers, lakes,

and marine waters), groundwater, and drinking water [1].

The problem is widespread throughout the world [2-15].

APIs can enter waterways by several routes, including

excretion following therapeutic use, discharge of treated

wastewater from manufacturing facilities, or disposal of

unused medications [16]. Agricultural substances, deter-

gents, and a host of other biologically active chemicals

are dumped into or leach into these same waterways

[5,17-29]. Unfortunately, there is very minimal amount

of information regarding potential effects on human and

aquatic ecosystems from exposure to combinations of

APIs and other chemicals.

The nature of the interaction between the components

of a combination can lead to additive, sub-additive, or to

supra-additive (synergistic) pharmacological or toxico-

logical effects. A mathematically rigorous method to

evaluate combinations (known as joint action analysis)

has been developed and has been applied to pharmacol-

ogical systems [30-40].

We report a convenient model for the measurement

and quantitative assessment of the toxicity of water pol-

lutant combinations using a fresh-water species that has a

primitive nervous system, including neurotransmitter and

2nd messenger systems [41-50] and that are useful for

study of drug action and physiological processes associ-

ated with drug abuse, such as physical dependence and

withdrawal [51-61]. We cho se for illustrative p urposes of

the method the combination of a representative of sub-

stances used as insecticides (an acetylcholinesterase in-

hibitor, neostigmine bromide) and a representative of

substances used in detergents and fertilizers, potassium

*Corresponding autho

Isobolographic Method and Invertebrate (Planarian) Model for Evaluating Combinations of Waterways Pollutants

382

monophosphate.

2. Materials and Methods

2.1. Animals and Chemicals

The planarians (Dugesia dorotocephala) were purchased

from Carolina Biological Supply Co. (Burlington, NC).

They were acclimated to laboratory conditions, at room

temperature (21˚C), and tested within 48 h. Neostigmine

bromide and potassium monophosphate (KH2PO4) were

obtained from commercial sources and prepared at the

desired concentration in tap water.

2.2. Testing

Planarians were placed individually into a four-quadrant

plastic Petri dish (diameter = 100 mm) containing 10 mL

of neostigmine bromide (6 doses), KH2PO4 (6 doses), or

1:1 combination of neostigmine bromide and KH2PO4 (6

doses). Percent lethality at the end of a 60-min exposure

was determined.

2.3. Isobolographic Analysis

Isobolographic analysis and pharmacologic applications

have been described (for a comprehensive review, see

monograph [39]). An isobolograph is a plot of dose (or

concentration) pairs in the combination that produce the

same effect, which is often selected as the half maximal

effect (ED50 value). If drug B of combination A and B

acting alone gives effect in concentration B, pairs (a, b)

are related to b plus the b-equivalent of a such that b +

beq = B. This may be written baR B and rear-

ranged to the form 1bB aA. If substances A and B

produce equal maximal effects, the concentration pairs (a,

b) are points that constitute a straight line. If the experi-

mental combination yields a result that plots as a point on

this line, it is additiv e. If it plots as a point below the line

of additivity (i. e ., a lower dose of each is needed), the

combination is greater than additive (synergistic). If it

plots as a point below th e line of additivity (i.e., a higher

dose of each is needed to produce the same effect), the

combination is sub-additiv e. Numerous studies have used

the isobolographic approach [62-69]. In the illustrative

example used here, constituent doses were used in fixed

ratio, which allows simple determination of combination

doses that produce the specified level of effect (ED50 in

the example). This is acco mplished by fitting dose-effect

data using an appropriate regression procedure and the

intersection of this line with the additive isobole gives

the dose pair that is additive. It also allows quantitative

assessment and statistical testing of any departure from

additivity.

2.4. Statistics

The linear isobole of additivity, applicable in the present

study because of constant relative potency, is convenient

for estimating the variance of the additive total dose. All

points (a, b) on this line can be expressed as fractions (f

and (1 – f )) of the respective potencies A and B, that is, a =

fA and





1bf B, and thus any combination with

constituent amounts chosen such that





dose fBfAdose 1BA has a total quantity given





1TfA fB. The variance of the additive total

T is therefore given by ,

where f and

 

21VTfVAf VB





 are reasonably estimated from the

mean A and mean B. The total additive variance calcu-

lated from the above allows a comparison with the ex-

perimentally determined total dose variance.

3. Results

3.1. Substances Alone and in Combination

Planarians (N = 18 per dose) were placed individually in-

to each of the four quadrants of the Petri dish. At 60 min,

the number of planarians dead was counted and % lethal-

ity was determined. Neostigmine bromide by itself pro-

duced dose-related lethality (% lethality = 1617.4 dose –

146.7). The LD50 value for neostigmine bromide alone

was 122 mM. KH2PO4 also produced dose-related lethal-

ity alone (% lethality = 1572.5 dose – 61.5). The LD50

value for KH2PO4 by itself was 70 mM. The fixed-ratio

combination (1:1) of neostigmne bromide plus KH2PO4

produced dose-related lethality (% lethality = 1 535. 2 d ose

– 76.2). The LD50 value for the 1:1 combination was 82

mM. The data are plotted in Figure 1.

Figure 1. Dose-related lethality at 60 minutes produced by

monopotassium phosphate alone, neostigmine alone, or a

1:1 combination of monopotassium phosphate plus neostig-

ming bromide. N = 18 planarians.

Isobolographic Method and Invertebrate (Planarian) Model for Evaluating Combinations of Waterways Pollutants 383

3.2. Isobolographic Analysis

An isobologram was constructed using the percent le-

thality data and is displayed in Figure 2. The LD50 value

for neostigmine bromide alone (i.e., 122 mM) is plotted

on the ordinate and the LD50 value for KH2PO4 alone

(i.e., 70 mM) is plotted on the abscissa. A straight line

connecting the LD 50 values of the individual agents is

the line of additivity. The LD50 value of the fixed-ratio

combination of neostigmine bromide plus KH2PO4 is

plotted as the point. The LD50 value of the combination

is significantly (p < 0.05) above the line of additivity.

This is indicative of a sub-additive interaction.

4. Discussion

Pharmaceutical and agricultural substances increasingly

are being found in waterways in concentrations that

produce deleterious biological effects [70-72]. Evaluation

of the toxicity of individual substances is a common

practice, however evaluation of the contribution of

potential interactive effects in combinations of pollutants

is increasingly being appreciated and investigated

[73-77]. In combinations, the possibility of non-additive

interaction arises. Thus three outcomes are possible:

additive, sub-additive, and supra-additive (synergy). For

the non-additive interactions, the determination of statistical

significant difference from additivity requires a thorough

evaluation using rigorous proc edu res (re view ed in [39] ).

Figure 2. Isobologram of the LD50 values obtained from the

data shown in Figure 1. The LD50 values for potassium

monophosphate or neostigmine exposure alone are plotted

on the ordinate and on the ordinate and abscissa. The LD50

value of the combination is significantly different (p < 0.05)

(the error bars are within the dimension of the circle) from

the line of additivity.

The present work investigated the use of a simple in

vivo planarian model. Planarians have a simple nervous

system and mammalian-like neurotransmitter systems

(e.g., [41,48,50]). Thus, they are the lowest form of

animal that would display relevant neurotoxicity. They

respond with quantifiable dose-related behavioral ch anges

to drug exposure and withdrawal (e.g., [41,43,45,46,49-

51,54,57,58,61]). And receptor-mediated mechanisms

can be verified using receptor-selective antagonists. We

have previously used planarian models for investigating

drug action and the physiological processes involved in

physical dependence (for review, see monograph [55]).

Like-wise, we have previously developed and used iso-

bolographic analysis for a variety of biological endpoints

(for review, see [39]).

In the present study, the two substances were selected

for illustrative purposes: one (neostigmine bromide) as

representative of acetylcholinesterase inhibitors, a class

of substances that have been common ingredients of

insecticides; the other one (potassium monophosphate) as

a representative of chemicals that have been common

ingredients in fertilizers and detergents. Both substances

produced dose-related lethality (reaching 100%) when

they were tested alone. The dose-response curves were

parallel, thus relative potency was constant throughout

the range of doses. The straight-line isobole of additivity

applies if and only if the relative potency is a constant, as

was the case in this study.

The 1:1 fixed-ratio combination of neostigmine bromide

and KH2PO4 produced dose-related and maximal let h al i t y.

Compared to the toxicity of exposure to the agents tested

individually, the toxic effect of the combination was

sub-additive. This was a surprising finding. We had anti-

cipated an additive or possibly even synergistic inter-

action. Thus the importance of actually testing combina-

tions was unintentionally emphasized. It should be noted

that the demonstration of sub-additivity in the present

study applies to the conditions used. It is possible that the

use of other fixed-ratios would have yielded additive or

supra-additive interactions. Likewise, lethality is only

one adverse effect and should not be used as the only

measure of safety. Multiple more subtle sub-lethal adv er s e

effects of combinations might result from particular com-

binations of pollutants. Each case requires careful and

rigorous ev aluation. The present study offers an example

of rigorous mathematical joint action analysis applied in

a convenient in vivo model.

5. Acknowledgements

The authors thank Timothy Shickley, Ph.D., for sug-

gesting Planaria as a model. This work was supported by

NIDA grants DA15378 (RBR), DA022694 (SMR) and

DA09793 (RJT).

Isobolographic Method and Invertebrate (Planarian) Model for Evaluating Combinations of Waterways Pollutants

384

REFERENCES

[1] P. D. Anderson, V. J. D’Aco, P. Shanahan, S. C. Chapra

M. E. Buzby, V. L. Cunningham, B. M. Duplessie, E. P.

Hayes, F. J. Mastrocco, N. J. Parke, J. C. Rader, J. H.

Samuelian and B. W. Schwab, “Screening Analysis of

Human Pharmaceutical Compounds in US Surface Wa-

ters,” Environmental Science & Technology, Vol. 38, No.

3, 2004, pp. 838- 849. doi:10.1021/es034430b

[2] S. Mompelat, O. Thomas and B. Le Bot, “Contamina-

tion Levels of Human Pharmaceutical Compounds in

French Surface and Drinking Water,” Journal of Environ-

mental Monitoring, Vol. 13, No. 10, 2011, pp. 2929-2939.

doi:10.1039/c1em10335k

[3] J. L. Martinez, “Environmental Pollution by Antibiotics

and by Antibiotic Resistance Determinants,” Environ-

mental Pollution, Vol. 157, No. 11, 2009, pp. 2893-2902.

doi:10.1016/j.envpol.2009.05.051

[4] S. Zheng, X. Qiu, B. Chen, X. Yu, Z. Liu, G. Zhong, H.

Li, M. Chen, G. Sun, H. Huang, W. Yu and D. Free-

stone, “Antibiotics Pollution in Jiulong River Estuary:

Source, Distribution and Bacterial Resistance,” Chemo-

sphere, Vol. 84, No. 11, 2011, pp. 1677-1685.

doi:10.1016/j.chemosphere.2011.04.076

[5] B. Meyer, J. Y. Pailler, C. Guignard, L. Hoffmann and A.

Krein, “Concentrations of Dissolved Herbicides and Phar-

maceuticals in a Small River in Luxembourg,” Environ-

mental Monitoring and Assessment, Vol. 180, No. 1-4,

2011, pp. 127-146.

[6] J. Martin, D. Camacho-Munoz, J. L. Santos, I. Aparicio

and E. Alonso, “Monitoring of Pharmaceutically Active

Compounds on the Guadalquivir River Basin (Spain):

Occurrence and Risk Assessment,” Journal of Environ-

mental Monitoring, Vol. 13, No. 7, 2011, pp. 2042-2049.

doi:10.1039/c1em10185d

[7] Q. Sui, J. Huang, S. Deng, W. Chen and G. Yu, “Seas-

onal Variation in the Occurrence and Removal of Phar-

maceuticals and Personal Care Products in Different Bio-

logical Wastewater Treatment Processes,” Environmental

Science & Technology, Vol. 45, No. 8, 2011, pp. 3341-

3348. doi:10.1021/es200248d

[8] S. Kleywegt, V. Pileggi, P. Yang, C. Hao, X. Zhao, C.

Rocks, S. Thach, P. Cheung and B. Whitehead, “Pharm-

aceuticals, Hormones and Bisphenol A in Untreated

Source and Finished Dri nking Water in Ontario, Canada—

Occurrence and Treatment Efficiency,” Science of the

Total Environment, Vol. 409, No. 8, 2011, pp. 1481-1488.

doi:10.1016/j.scitotenv.2011.01.010

[9] D. Fatta-Kassinos, S. Meric and A. Nikolaou, “Pharma-

ceutical Residues in Environmental Waters and Waste-

Water: Current State of Knowledge and Future Research,”

Analytical and Bioanalytical Chemistry, Vol. 399, No. 1,

2011, pp. 251-275. doi:10.1007/s00216-010-4300-9

[10] W. J. Sim, J. W. Lee, E. S. Lee, S. K. Shin, S. R. Hwang

and J. E. Oh, “Occurrence and Distribution of Pharma-

Ceuticals in Wastewater from Households, Livestock

Farms, Hospitals and Pharmaceutical Manufactures,” Che-

mosphere, Vol. 82, No. 2, 2011, pp. 179-186.

doi:10.1016/j.chemosphere.2010.10.026

[11] A. Y. Lin, X. H. Wang and C. F. Lin, “Impact of Waste-

Waters and Hospital Effluents on the Occurrence of Con-

trolled Substances in Surface Waters,” Chemosphere, Vol.

81, No. 5, 2010, pp. 562-570.

doi:10.1016/j.chemosphere.2010.08.051

[12] D. G. Larsson, “Release of Active Pharmaceutical In-

gredients from Manufacturing Sites—Need for New Man-

agement Strategies,” Integrated Environmental Ass ess me nt

and Management, Vol. 6, No. 1, 2010, pp. 184-186.

doi:10.1002/ieam.20

[13] Y. Valcarcel, S. Gonzalez Alonso, J. L. Rodriguez-Gil, A.

Gil and M. Catala, “Detection of Pharmaceutically Active

Compounds in the Rivers and Tap Water of the Madrid

Region (Spain) and Potential Ecotoxicological Risk,”

Chemosphere, Vol. 84, 10, No. 2011, pp. 1336-1348.

doi:10.1016/j.chemosphere.2011.05.014

[14] M. S. Kostich, A. L. Batt, S. T. Glassmeyer and J. M.

Lazorchak, “Predicting Variability of Aquatic Concentra-

tions of Human Pharmaceuticals,” Science of the Total

Environment, Vol. 408, No. 20, 2010, pp. 4504-4510.

doi:10.1016/j.scitotenv.2010.06.015

[15] S. Terzic, I. Senta and M. Ahel, “Illicit Drugs in Waste-

Water of the City of Zagreb (Croatia)—Estimation of Drug

Abuse in a Transition Country,” Environmental Pollution,

Vol. 158, No. 8, 2010, pp. 2686-2693.

doi:10.1016/j.envpol.2010.04.020

[16] T. Heberer, “Occurrence, Fate, and Removal of Pharma-

ceutical Residues in the Aquatic Environment: A Review

of Recent Research Data,” Toxicology Letters, Vol. 131,

No. 1, 2002, pp. 5-17.

doi:10.1016/S0378-4274(02)00041-3

[17] A. Baba and G. Tayfur, “Groundwater Contamination and

Its Effect on Health in Turkey,” Environmental Monitor-

ing and Assessment, Vol. 183, No. 1-4, 2011, pp. 77-94.

doi:10.1007/s10661-011-1907-z

[18] K. Mishra, R. C. Sharma and S. Kumar, “Contamination

Levels and Spatial Distribution of Organochlorine Pesti-

Cides in Soils from India,” Ecotoxicology and Environ-

mental Safety, Vol. 76, 2012, pp. 215-225.

doi:10.1016/j.ecoenv.2011.09.014

[19] T. A. Edge, A. El-Shaarawi, V. Gannon, C. Jokinen, R.

Kent, I. U. Khan, W. Koning, D. Lapen, J. Miller, N.

Neumann, R. Phillips, W. Robertson, H. Schreier, A.

Scott, I. Shtepani, E. Topp, G. Wilkes and E. van Bochove,

“Investigation of an Escherichia coli Environmental

Benchmark for Waterborne Pathogens in Agricultural

Watersheds in Canada,” Journal of Environmental Qual-

ity, Vol. 41, No. 1, 2012, pp. 21-30.

doi:10.2134/jeq2010.0253

[20] F. Zan, S. Huo, B. Xi, J. Su, X. Li, J. Zhang and K. M.

Yeager, “A 100 Year Sedimentary Record of Heavy Metal

Pollution in a Shallow Eutrophic Lake, Lake Chaohu,

China,” Journal of Environmental Monitoring, Vol. 13,

No. 10, 2011, pp. 2788-2797. doi:10.1039/c1em10385g

[21] M. H. Pham, Z. Sebesvari, B. M. Tu, H. V. Pham and F.

G. Renaud, “Pesticide Pollution in Agricultural Areas of

Northern Vietnam: Case Study in Hoang Liet and Minh

Dai Communes,” Environmental Pollution, Vol. 159, No.

12, 2011, pp. 3344-3350.

doi:10.1016/j.envpol.2011.08.044

Isobolographic Method and Invertebrate (Planarian) Model for Evaluating Combinations of Waterways Pollutants 385

[22] S. S. Kaushal, P. M. Groffman, L. E. Band, E. M. Elliott,

C. A. Shields and C. Kendall, “Tracking Nonpoint Source

Nitrogen Pollution in Human-Impacted Watersheds,” Envi-

ronmental Science & Technology, Vol. 45, No. 19, 2011,

pp. 8225-8232. doi:10.1021/es200779e

[23] A. E. Khater, “Uranium and Trace Elements in Phosphate

Fertilizers—Saudi Arabia,” Health Physics, Vol. 102, No.

1, 2012, pp. 63-70. doi:10.1097/HP.0b013e3182289c17

[24] E. U. Cantu-Soto, M. M. Meza-Montenegro, A. I. Valen-

zuela-Quintanar, A. Felix-Fuentes, P. Grajeda-Cota, J. J.

Balderas-Cortes, C. L. Osorio-Rosas, G. Acuna-Garcia and

M. G. Aguilar-Apodaca, “Residues of Organochlorine Pes-

ticides in Soils from the Southern Sonora, Mexico,” Bulle-

tin of Environmental Contaminati on and Tox ico log yl, Vol.

87, No. 5, 2011, pp. 556-560.

doi:10.1007/s00128-011-0353-5

[25] P. Nila Rekha, R. S. Kanwar, A. K. Nayak, C. K. Hoang

and C. H Pederson “Nitrate Leaching to Shallow Ground-

water Systems from Agricultural Fields with Different

Management Practices,” Journal of Environmental Moni-

toring, Vol. 13, No. 9, 2011, pp. 2550-2558.

doi:10.1039/c1em10120j

[26] S. E. Lewis, J. E. Brodie, Z. T. Bainbridge, K. W. Rohde,

A. M. Davis, B. L. Masters, M. Maughan, M. J. Devlin, J.

F. Mueller and B. Schaffelke, “Herbicides: A New Threat

to the Great Barrier Reef,” Environmental Pollution, Vol.

157, No. 8-9, 2009, pp. 2470-2484.

doi:10.1016/j.envpol.2009.03.006

[27] F. Licciardello, M. L. Antoci, L. Brugaletta and G. L.

Cirelli, “Evaluation of Groundwater Contamination in a

Coastal Area of South-Eastern Sicily,” Journal of Envi-

ronmental Science and Health, Part B: Pesticides, Food

Contaminants, and Agricultural Wastes, Vol. 46, No. 6,

2011, pp. 498-508.

[28] V. Babu, P. Unnikrishnan, G. Anu and S. M. Nair, “Dis-

tribution of Organophosphorus Pesticides in the bed Sedi-

ments of a Backwater System Located in an Agricultural

Watershed: Influence of Seasonal Intrusion of Seawater,”

Archives of Environmental Contamination and Toxicol-

ogy, Vol. 60, No. 4, 2011, pp. 597-609.

doi:10.1007/s00244-010-9569-3

[29] S. Burgert, R. B. Schafer, K. Foit, M. Kattwinkel, L. Met-

zeling, R. MacEwan, B. J. Kefford and M. Liess, “Model-

ling Aquatic Exposure and Effects of Insecticides—Ap-

plication to South-Eastern Australia,” Science of the Total

Environment, Vol. 409, No. 14, 2011, pp. 2807-2814.

doi:10.1016/j.scitotenv.2011.02.042

[30] S. Loewe, “The Problem of Synergism and Antagonism

of Combined Drugs,” Arzneimittelforschung, Vol. 3, No.

6, 1953, pp. 285-290.

[31] S. Loewe, “Antagonisms and Antagonists,” Pharmaco-

logical Reviews, Vol. 9, No. 2, 1957, pp. 237-242.

[32] R. J. Tallarida, “Statistical Analysis of Drug Combina-

tions for Synergism,” Pain, Vol. 49, No. 1, 1992, pp. 93-

97. doi:10.1016/0304-3959(92)90193-F

[33] R. J. Tallarida and R. B. Raffa, “Testing for Synergism

over a Range of Fixed Ratio Drug Combinations: Re-

placing the Isobologram,” Life Sciences, Vol. 58, No. 2,

1996, pp. PL23-PL28.

[34] R. J. Tallarida, H. L. Kimmel and S. G. Holtzman, “Theory

and Statistics of Detecting Synergism between Two Ac-

tive Drugs: Cocaine and Buprenorphine,” Psychopharma-

cology (Berl), Vol. 133, No. 4, 1997, pp. 378-382.

doi:10.1007/s002130050417

[35] R. J. Tallarida, F. Porreca and A. Cowan, “Statistical Ana-

lysis of Drug-Drug and Site-Site Interactions with Isobo-

lograms,” Life Sciences , Vol. 45, No. 1989, pp. 947-961.

doi:10.1016/0024-3205(89)90148-3

[36] R. J. Tallarida, D. J. Stone, Jr. and R. B. Raffa, “Effi-

cient Designs for Studying Synergistic Drug Combina-

tions,” Life Sciences, Vol. 61, No. 26, 1997, pp. PL417-

PL425.

[37] R. J. Tallarida, D. J. Stone Jr., J. D. McCary and R. B.

Raffa, “Response Surface Analysis of Synergism between

Morphine and Clonidine,” Journal of Pharmacology and

Experimental Therapeutics, Vol. 289, No. 1, 1999, pp. 8-

13.

[38] R. J. Tallarida and R. B. Murray, “Manual of Pharmaco-

logic Calculation with Computer Programs,” 2nd Edition,

Springer Verlag, New York, 1987.

[39] R. J. Tallarida, “Drug Synergism and Dose-Effect Data

Analysis,” Chapman & Hall/CRC Press, Boca Raton, 2000.

doi:10.1201/9781420036107

[40] R. J. Tallarida, U. Midic, N. Lamarre and Z. Obradovic,

“Searching for Synergism among Combinations of Drugs

of Abuse and the Use of Isobolographic Analysis,” arXiv:

1202.4742v1[q-bio.QM], 2012.

[41] S. Algeri, A. Carolei, P. Ferretti, C. Gallone, G. Palla-

dini and G. Venturini, “Effects of Dopaminergic Agents

on Monoamine Levels and Motor Behaviour in Planaria,”

Comparative Biochemistry and Physiology Part C: Com-

parative Pharmacology, Vol. 74, No. 1, 1983, pp. 27-29.

doi:10.1016/0742-8413(83)90142-1

[42] F. R. Buttarelli, F. E. Pontieri, V. Margotta and G. Pal-

ladini, “Acetylcholine/Dopamine Interaction in Planaria,”

Comparative Biochemistry and Physiology—Part C: Toxi-

cology & Pharmacology, Vol. 125, No. 2, 2000, pp. 225-

231.

[43] A. Carolei, V. Margotta and G. Palladini, “Proposal of a

New Model with Dopaminergic-Cholinergic Interactions

for Neuropharmacological Investigations,” Neuropsycho-

biology, Vol. 1, No. 6, 1975, pp. 355-364.

doi:10.1159/000117512

[44] G. Palladini, V. Margotta, A. Carolei, F. Chiarini, M. Del

Piano, G. M. Lauro, L. Medolago-Albani and G. Venturini,

“The Cerebrum of Dugesia Gonocephala s.1. Platyhel-

minthes, Turbellaria, Tricladida. Morphological and Fun-

ctional Observations,” Journal für Hirnforschung, Vol.

24, No. 2, 1983, pp. 165-172.

[45] G. Palladini, S. Ruggeri, F. Stocchi, M. F. De Pandis, G.

Venturini and V. Margotta, “A Pharmacological Study of

Cocaine Activity in Planaria,” Comparative Biochemistry

and Physiology—Part C: Toxicology & Pharmacology,

Vol. 115, No. 1, 1996, pp. 41-45.

doi:10.1016/S0742-8413(96)00053-9

[46] F. Passarelli, A. Merante, F. E. Pontieri, V. Margotta, G.

Venturini and G. Palladini, “Opioid-Dopamine Interac-

tion in Planaria: A Behavioral Study,” Comparative Bio-

Isobolographic Method and Invertebrate (Planarian) Model for Evaluating Combinations of Waterways Pollutants

386

chemistry and Physiology—Part C: Toxicology & Phar-

macology, Vol. 124, No. 1, 1999, pp. 51-55.

doi:10.1016/S0742-8413(99)00048-1

[47] P. Ribeiro, F. El-Shehabi and N. Patocka, “Classica l Trans -

mitters and Their Receptors in Flatworms,” Parasitology,

Vol. 131, Suppl. 1, 2005, pp. S19-S40.

[48] G. Venturini, A. Carolei, G. Palladini, V. Margotta and M.

G. Lauro, “Radioimmunological and Immunocyto-Che mica l

Demonstration of Met-Enkephalin in Planaria,” Compara-

tive Biochemistry and Physiology Part C: Comparative

Pharmacology, Vol. 74, No. 1, 1983, pp. 23-25.

doi:10.1016/0742-8413(83)90141-X

[49] G. Venturini, F. Stocchi, V. Margotta, S. Ruggieri, D.

Bravi, P. Bellantuono and G. Palladini, “A Phar m a co lo gi c al

Study of Dopaminergic Receptors in Planaria,” Neuro-

pharmacology, Vol. 28, No. 12, 1989, pp. 1377-1382.

doi:10.1016/0028-3908(89)90013-0

[50] J. H. Welsh and L. D. Williams, “Monoamine-Contain-

ing Neurons in Planaria,” The Journal of Comparative

Neurology, Vol. 138, No. 1, 1970, pp. 103-115.

doi:10.1002/cne.901380108

[51] R. B. Raffa and P. Desai, “Description and Quantifica-

tion of Cocaine Withdrawal Signs in Planaria,” Brain Re-

search, Vol. 1032, No. 1-2, 2005, pp. 200-202.

doi:10.1016/j.brainres.2004.10.052

[52] R. B. Raffa, K. E. Finno, C. S. Tallarida and S. M. Rawls,

“Topiramate-Antagonism of L-Glutamate-Induced Par-

oxysms in Planarians,” European Journal of Pharmacol-

ogy, Vol. 649, No. 13, 2010, pp. 150-153.

doi:10.1016/j.ejphar.2010.09.021

[53] R. B. Raffa, L. J. Holland and R. J. Schulingkamp,

“Quantitative Assessment of Dopamine D2 Antagonist

Activity Using Invertebrate (Planaria) Locomotion as a

Functional Endpoint,” Journal of Pharmacological and

Toxicological Methods, Vol. 45, No. 3, 2001, pp. 223-226.

doi:10.1016/S1056-8719(01)00152-6

[54] R. B. Raffa and A. F. Martley, “Amphetamine-Induced

Increase in Planarian Locomotor Activity and Block by

UV Light,” Brain Research, Vol. 1031, No. 1, 2005, pp.

138-140. doi:10.1016/j.brainres.2004.10.051

[55] R. B. Raffa and S. M. Rawls, “Planaria: A Model for

Drug Action and Abuse,” Landes Bioscience, Inc., Austin,

2008.

[56] R. B. Raffa, M. J. Robinson and R. J. Tallarida, “Ultra-

violet Light-Induced Photorelaxation of Agonist-Con-

tracted Rabbit Aorta: Further Characterization and the Es-

timation of Drug-Receptor Rate Constants,” Drug Devel-

opment Research, Vol. 5, No. 4, 1985, pp. 359-369.

doi:10.1002/ddr.430050409

[57] R. B. Raffa, G. W. Stagliano and S. Umeda, “Kappa-

Opioid Withdrawal in Planaria,” Neuroscience Letters,

Vol. 349, No. 3, 2003, pp. 139-142.

doi:10.1016/S0304-3940(03)00814-0

[58] R. B. Raffa and J. M. Valdez, “Cocaine Withdrawal in

Planaria,” European Journal of Pharmacology, Vol. 430,

No. 1, 2001, pp. 143-145.

doi:10.1016/S0014-2999(01)01358-9

[59] R. B. Raffa, J. M. Valdez, L. J. Holland and R. J. Schul-

ingkamp, “Energy-Dependent UV Light-Induced Disrup-

tion of (-)Sulpiride Antagonism of Dopamine,” European

Journal of Pharmacology, Vol. 406, No. 3, 2000, pp.

R11-R12. doi:10.1016/S0014-2999(00)00730-5

[60] S. M. Rawls, T. Thomas, M. Adeola, T. Patil, N. Ray-

mondi, A. Poles, M. Loo and R. B. Raffa, “Topiramate

Antagonizes NMDA- and AMPA-Induced Seizure-Like

Activity in Planarians,” Pharmacology Biochemistry and

Behavior, Vol. 93, No. 4, 2009, pp. 363-367.

doi:10.1016/j.pbb.2009.05.005

[61] S. Umeda, G. W. Stagliano and R. B. Raffa, “Cocaine and

Kappa-Opioid Withdrawal in Planaria Blocke d by D-, but

Not L-, Glucose,” Brain Research, Vol. 1018, No. 2,

2004, pp. 181-185. doi:10.1016/j.brainres.2004.05.057

[62] D. Bian, M. H. Ossipov, M. Ibrahim, R. B. Raffa, R. J.

Tallarida, T. P. Malan, Jr., J. Lai and F. Porreca, “Loss of

Antiallodynic and Antinociceptive Spinal/Supraspinal

Morphine Synergy in Nerve-Injured Rats: Restoration by

MK-801 or Dynorphin Antiserum,” Brain Research, Vol.

831, No. 1, 1999, pp. 55-63.

doi:10.1016/S0006-8993(99)01393-1

[63] E. A. Bolan, R. J. Tallarida and G. W. Pasternak, “Syn-

ergy between Mu Opioid Ligands: Evidence for Func-

tional Interactions among Mu Opioid Receptor Sub-

types,” Journal of Pharmacology and Experimental T h era -

peutics, Vol. 303, No. 2, 2002, pp. 557-562.

doi:10.1124/jpet.102.035881

[64] E. E. Codd, R. P. Martinez, L. Molino, K. E. Rogers, D. J.

Stone and R. J. Tallarida, “Tramadol and Several Anti-

convulsants Synergize in Attenuating Nerve Injury-In-

duced Allodynia,” Pain, Vol. 134, No. 3, 2008, pp. 254-

262. doi:10.1016/j.pain.2007.04.019

[65] C. A. Fairbanks, K. F. Kitto, H. O. Nguyen, L. S. Stone

and G. L. Wilcox, “Clonidine and Dexmedetomidine Pro-

duce Antinociceptive Synergy in Mouse Spinal Cord,”

Anesthesiology, Vol. 110, No. 3, 2009, pp. 638-647.

doi:10.1097/ALN.0b013e318195b51d

[66] M. J. Field, M. I. Gonzalez, R. J. Tallarida and L. Singh,

“Gabapentin and the Neurokinin(1) Receptor Antagonist

CI-1021 Act Synergistically in Two Rat Models of Neu-

ropathic Pain,” Journal of Pharmacology and Experimen-

tal Therapeutics, Vol. 303, No. 2, 2002, pp. 730-735.

doi:10.1124/jpet.102.033134

[67] D. Mukherjee, S. E. Nissen and E. J. Topol, “Risk of

Cardiovascular Events Associated with Selective COX-2

Inhibitors,” JAMA: The Journal of the American Medical

Association, Vol. 286, No. 8, 2001, pp. 954-959.

doi:10.1001/jama.286.8.954

[68] R. B. Raffa, D. J. Stone, Jr. and R. J. Tallarida, “Dis-

covery of ‘Self-Synergistic’ Spinal/Supraspinal Antinoci-

ception Produced by Acetaminophen (Paracetamol)” Jour-

nal of Pharmacology and Experimental T he ra p eu t ic s , Vol.

295, No. 1, 2000, pp. 291-294.

[69] R. B. Raffa, R. Clark-Vetri, R. J. Tallarida and A. I. Wer-

theimer, “Combination Strategies for Pain Management,”

Expert Opinion on Pharmacotherapy, Vol. 4, No. 10,

2003, pp. 1697-1708. doi:10.1517/14656566.4.10.1697

[70] D. W. Kolpin, E. T. Furlong, M. T. Meyer, E. M. Thur-

man, S. D. Zaugg, L. B. Barber and H. T. Buxton, “Phar-

maceuticals, Hormones, and Other Organic Waste-Water

Isobolographic Method and Invertebrate (Planarian) Model for Evaluating Combinations of Waterways Pollutants

387

Contaminants in US Streams, 1999-2000: A National

Reconnaissance,” Environmental Science & Technology,

Vol. 36, No. 6, 2002, pp. 1202-1211.

doi:10.1021/es011055j

[71] P. E. Stackelberg, E. T. Furlong, M. T. Meyer, S. D. Zaugg,

A. K. Henderson and D. B. Reissman, “Persistence of

Pharmaceutical Compounds and Other Organic Waste-

water Contaminants in a Conventional Drinking-Water-

Treatment Plant,” Science of the Total Environment, Vol.

329, No. 1, 2004, pp. 99-113.

doi:10.1016/j.scitotenv.2004.03.015

[72] K. A. Kidd, P. J. Blanchfield, K. H. Mills, V. P. Palace, R.

E. Evans, J. M. Lazorchak and R. W. Flick, “Collapse of

a Fish Population after Exposure to a Synthetic Estro-

gen,” Proceedings of the National Academy of Sciences of

the United States, Vol. 104, No. 21, 2007, pp. 8897-8901.

doi:10.1073/pnas.0609568104

[73] M. E. Ortiz-Santaliestra, M. J. Fernandez-Beneitez, M.

Lizana and A. Marco, “Influence of a Combination of

Agricultural Chemicals on Embryos of the Endangered

Gold-Striped Salamander (Chioglossa lusitanica),” Ar-

chives of Environmental Contamination and Toxicology,

Vol. 60, No. 4, 2011, pp. 672-680.

doi:10.1007/s00244-010-9570-x

[74] R. A. Relyea and N. Mills, “Predator-Induced Stress Makes

the Pesticide Carbaryl More Deadly to Gray Tree Frog

Tadpoles (Hyla versicolor),” Proceedings of the National

Academy of Sciences of the United States, Vol. 98, No. 5,

2001, pp. 2491-2496. doi:10.1073/pnas.031076198

[75] M. D. Boone, C. M. Bridges, J. F. Fairchild and E. E.

Little, “Multiple Sublethal Chemicals Negatively Affect

Tadpoles of the Green Frog, Rana Clamitans,” Environ-

mental Toxicology and Chemistry, Vol. 24, No. 5, 2005,

pp. 1267-1272. doi:10.1897/04-319R.1

[76] M. D. Boone, R. D. Semlitsch, E. E. Little and M. C. Doyle,

“Multiple Stressors in Amphibian Communities: Effects

of Chemical Contamination, Bullfrogs, and Fish,” Eco-

logical Applications, Vol. 17, No. 1, 2007, pp. 291-301.

doi:10.1890/1051-0761(2007)017[0291:MSIACE]2.0.CO

[77] P. T. Johnson, E. R. Preu, D. R. Sutherland, J. M. Roman-

sic, B. Han and A. R. Blaustein, “Adding Infection to In-

jury: Synergistic Effects of Predation and Parasitism on

Amphibian Malformations,” Ecology, Vol. 8 7 , N o . 9 , 2006,

pp. 2227-2235.

doi:10.1890/0012-9658(2006)87[2227:AITISE]2.0.CO;2