Abstract
Previous studies demonstrated that drug effects on the movement sequences of rats in unconditioned motor activity paradigms can be quantified by scaling measures that describe the average relationship between a variable of interest and an experimental parameter. However, rats engage in a wide variety of geometrically distinct movements that can be influenced differentially by drugs. In this investigation, the extended scaling approach is presented to capture quantitatively the relative contributions of geometrically distinct movement sequences to the overall path structure. The calculation of the spectrum of local spatial scaling exponents,f(d), is based on ensemble methods used in statistical physics. Results of thef(d) analysis confirm that the amount of motor activity is not correlated with the geometrical structure of movement sequences. Changes in the average spatial scaling exponent,d, correspond to shifting the entiref(d) function, and indicate overall changes in path structure. With the extended scaling approach, straight movement sequences are assessed independently from highly circumscribed movements. Thus, thef(d) function identifies drug effects on particular ranges of movement sequences as defined by the geometrical structure of movements. More generally, thef(d) function quantifies the relationship between microscopically recorded variables, in this paradigm consecutive (x, y) locations, and the macroscopic behavioral patterns that constitute the animal's response topography.
This is a preview of subscription content, log in via an institution to check access.
Similar content being viewed by others
References
Badii R (1989) Conservation Laws and thermodynamic formalism for dissipative dynamical systems, Rivista Del Nuovo Cimento 12:1–71
Barnsley MF (1988) Fractals everywhere. Academic Press, Boston
Bauman WA, Hashim A, Sershen H (1989) Cerebral cortical concentrations of bioamines and their metabolites during arousal and after feeding in the little brown bat (Myotis lucifugus), Brain Res 500:156–160
Berlyne DE (1960) Conflict, arousal, and curiosity McGraw Hill, New York
Buzsaki G, Gage FG (1989) The cholinergic nucleus basalis: a key structure in neocortical arousal. Experientia Supp 57:159–171
Callaway CW, Wing LL, Geyer MA (1990) Serotonin release contributes to the locomotor stimulant effect of 3,4-methyl-enedioxymethamphetamine (MDMA) in rats. J Pharmacol Exp Ther 254:456–464
Chandler D (1987) Introduction to modern statistical mechanics. Oxford University Press, New York
Feder J (1988) Fractals. Plenum, New York
Fray PJ, Sahakian BJ, Robbins TW, Kobb GF, Iversen SD (1981) An observational method for quantifying the behavioural effects of dopamine agonists contrasting effects ofd-amphetamine and apomorphine. Psychopharmacology 69:253–265
Geyer MA (1990) Approaches to the characterization of drug effects on locomotor activity in rodents. In: Adler MW, Cowan A (eds) Testing and evaluation of drugs of abuse. Alan R Liss New York, pp 81–99
Geyer MA, Russo PV, Masten VL (1986) Multivariate assessment of locomotor behavior: Pharmacological and behavioral analyses. Pharmacol Biochem Behav 25:277–288
Halsey TC, Jensen MH, Kadanoff LP, Procaccia I, Shraiman BI (1986) Fluctuation spectrum of an experimental system. Physics Rev A 33:1141–1151
Harvey JA (1987) Behavioral pharmacology of central nervous system stimulants, Neuropharmacology. 26:887–892
Hebb DO (1955) Drives and CNS (conceptual nervous system). Psychol Rev 62:243–254
Hull C (1949) Stimulus intensity dynamism (V) and stimulus generalization. Psychol Rev 56:67–76
Kernan WJ, Mullenix PJ, Kent R (1988) Analysis of the time distribution and time sequence of behavioral acts. Int J Neurosci 19:1–17
Ljungberg T, Ungerstedt U (1977) A method for simultaneously recording of eight behavioral parameters related to monoamine neurotransmission, Pharmacol Biochem Behav 8:483–489
Lyon M, Robbins TW (1975) The action of central nervous system stimulant drugs: a general theory concerning amphetamine effects. In: Essman W, Valzelli L (eds) Current developments in psychopharmacology, Vol. 2. Spectrum, New York, 79–163
Mandelbrot B (1977) Fractals: Form, chance and dimension. Freeman, San Francisco
Nickolson VJ (1981) Detailed analysis of the effects of apomorphine and d- amphetamine on spontaneous locomotor behaviour of rats as measured in a TV-based automated open-field system. Eur J Pharmacol 72:45–56
Paulus MP, Geyer MA (1991a) A temporal and spatial scaling hypothesis for the behavioral effects of psychostimulants. Psychopharmacology 104:6–15
Paulus MP, Geyer MA (1991b) A scaling approach to find order parameters quantifying the effects of dopaminergic agents on unconditioned motor activity in rats. Prog Neuro-psychopharmacol Biol Psychiatry 15:903–919
Paulus MP, Geyer MA (1992) The effects of MDMA and other methylenedioxy substituted phenylalkylamines on the structure of rat locomotor activity, Neuropsychopharmacology 7:15–31
Paulus MP, Geyer MA (1993) Three independent factors characterize spontaneous rat motor activity. Behav Brain Res 53:11–20
Paulus MP, Geyer MA, Gold LH, Mandell AJ (1990) Application of entropy measures derived from the ergodic theory of dynamical systems to rat locomotor behavior. Proc Natl Acad Sci 87:723–727
Paulus MP, Geyer MA, Mandell AJ (1991) Statistical mechanics of a neurobiological dynamical system: the spectrum of local entropies (S(α)) applied to cocaine-perturbed behavior. Physica A 147:567–577
Paulus MP, Callaway CW, Geyer MA (1993) Quantitative assessment of the microstructure of rat behavior: II. Distinctive effects of dopamine releasers and uptake inhibitors. Psychopharmacology (in press)
Reiter LW, MacPhail RC (1979) Motor activity: a survey of methods with potential use in toxicity testing. In: Geller I, Stebbins WC, Wayner MJ (eds) Test methods for definition of effects of toxic substances on behavior and neuromotor function, Vol 1, Suppl 1. Ankho International New York, pp. 53–65
Rempel NL, Callaway CW, Geyer MA (1993) Serotonin-1B receptor activation mimics behavioral effects of presynaptic serotonin release, Neuropsychopharmacology 8:201–211
Robbins TW (1977) A critique of the methods available for the measurement of spontaneous motor activity. In: Iversen LL, Iversen SD, Snyder SH (eds) Handbook of psychopharmacology Vol 7. Plenum, New York, pp 37–82
Robbins TW, Everitt BJ (1990) Psychopharmacological studies of arousal and attention. In: Stahl S, Iversen SD, Goodman E (eds) Cognitive Neurochemistry. Oxford University Press, Oxford, p 135
Ruelle D (1989) Chaotic evolution and strange attractors: the statistical analysis of time series for deterministic nonlinear systems. Cambridge University Press, New York
Sanberg PR, Zoloty SA, Willis R, Ticarich CD, Rhoads K, Nagy RP, Mitchell SG, Laforest AR, Jenks JA, Harkabus LJ, Gurson DB, Finnefrock JA, Bednarik EJ (1987) Digiscan activity: automated measurement of thigmotactic and stereotypic behavior in rats. Pharmacol Biochem Behav 27:569–572
Stahle L (1987) Pharmacological studies on behavioral changes induced by dopamine agonists in the rat: a multivariate approach Stockholm, Department of Pharmacology, Karolinska Institut (Doctoral Thesis)
Stanley HE (1987) Introduction to Phase Transitions and Critical Phenomena. Oxford Univrsity Press, New York
Szechtman H, Eilam D, Teitelbaum P, Golani I (1988) A different look at measurement and interpretation of drug induced behavior. Psychobiology 16:164–173
Teitelbaum P, Szechtman H, Sirkin DW, Golani I (1982) Dimensions of movement, movement sub-systems and local reflexes in the dopaminergic systems underlying exploratory locomotion. In: Spiegelstein MY, Levy A (eds) Behavioral models and the analysis of drug action. Elsevier, Amsterdam Oxford New York, pp 357–385
Author information
Authors and Affiliations
Additional information
Exemplary calculations of path segments with different geometrical characteristics can be obtained from the authors. Questions regarding the computational implementation of this method should be addressed to MPP preferably via email (martin@rat.ucsd.edu) or FAX (619-543-2493)
Rights and permissions
About this article
Cite this article
Paulus, M.P., Geyer, M.A. Quantitative assessment of the microstructure of rat behavior: I.f(d), The extension of the scaling hypothesis. Psychopharmacology 113, 177–186 (1993). https://doi.org/10.1007/BF02245695
Received:
Revised:
Issue Date:
DOI: https://doi.org/10.1007/BF02245695