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1-5 SQU  Journal For  Science, 9 (2004) 
 © 2004 Sultan Qaboos University 

1 

Thermal Effects on the Body mass, 
Transpiration rate, Feeding and Food 
Conversion of the Pillbug Armadillo 
officinalis (Isopoda, Oniscidea) Fed on 
the Dry Leaf of Punica Granatum 

Abdelgader K. Youssef and G. Achuthan Nair 

Department of Zoology, Faculty of Science, University of Garyounis, P. O. 
Box 9480, Benghazi, Libya, Email: gachuthannair@yahoo.com. 

 كتلة الجسم و معدل النتح والتغذية و التحول الغذائي  للبقة المدرعة الحرارية على التأثيرات
 )Armadillo officinalis (  المتغذية على أوراق الرمان الجافة)(Punica granatum  

 عبدالقادر يوسف وأكوتان ناير 

الكفايـة اإلنتاجيـة    , اية التمثيل الغذائي    كف,  مالحظات الدراسة اشتملت على كتلة الجسم معدل النتح          :خالصة  
   المدرعة التحول الغذائي و االيضى للبقة  ,  التمثيل الغذائي,  التغذية:   من  كل معدالت و الصافية  اإلجمالية 

 )Pillbug Armadillo officinalis   (  والتى أقلمت على درجتي حرارةC °14 و C °21 يوم 15 و لمدة 
 أي قيمة معتبـرة عنـد   لم يعطيالتأقلم الحراري .  الجافة Punica granatum )(ق الرمانو غذيت علي أورا

علي أي حال درجتي الحرارة المنوه عنهمـا   )   P>0.05, t=1.09( اختالف الزيادة الوزنية للبقة المدرعة   
    (p<0.01, t=9.01)    و الرطوبـة     p<0.01, t=9.53)( وضحتا اختالفات معتبرة في معـدل النـتح      

  و معـدل التحـول الغـذائي      (p<0.05, t=3.76)  معدل التغذيـة  (p<0.05, t=5.16)كفاية التمثيل الغذائي 
(p<0.05, t=2.58) الحيوانات لوحظ عليها أنها تتغذي تغذية جيدة علي أوراق الرمان في .   بين البق المدرع 

الغذائي    التمثيل  نسبة .  C° 14فضل عند درجة حرارة      لكن كفاية التمثيل الغذائي هي أ      C°21درجة حرارة     
)Assimilated food(  عند درجة حـرارة  3.21%   أنسجة جديدة كانإلى   و المتحول C° 14 6.30%  و 

 2.05% كان   C°21  و    C° 14 االستهالك الغذائي للبقة المدرعة عند درجتي الحرارة      ,  فقط   C°21عند درجة   
 ألوراقائيـة   ي الكيم   للتركيبة   مختصرة   بنبذة   زودت  الدراسة .التوالييوميا علي    من وزن الجسم     3.79% و  

   .في البرية  A.officinalis  الحراري علي نشاط الأيضا التأثيرالرمان و ناقشت 

 
ABSTRACT: Observations were made on the body mass; transpiration rate; 
assimilation efficiency; gross and net production efficiencies; feeding, assimilation, 
conversion and metabolic rates of the pillbug Armadillo officinalis Dumeril acclimatized 
at 14º  and 21 °C for 15 days and fed on the dry leaf of Punica granatum (Pomegranate).  



ABDELGADER K. YOUSSEF and G. ACHUTHAN NAIR 

 2

A brief description is given on the chemical composition of P. granatum leaf.  The 
difference in body mass increments of A. officinalis between the acclimatized 
temperatures was not significant (t = 1.09; p>0.05).  However, significant differences 
were discernible on the transpiration rate (t = 9.53; p<0.01), moisture (t = 9.01; p<0.01), 
assimilation efficiency (t = 5.16; p<0.01), feeding (t = 3.76; p<0.05) and conversion (t = 
2.58; p<0.05)  rates between the woodlice acclimatized at 14º and 21 °C.  Better feeding 
of    P. granatum leaf by these animals was observed at 21° C, but better assimilation 
efficiency at 14 °C.  Only 3.21% assimilated food at 14° C and 6.30% at 21 °C were 
converted into the production of new tissues.  The food consumption of A. officinalis at 
14º and 21° C was 2.05% and 3.79% body mass/day respectively.  The effect of 
temperature on the activity of A. officinalis in the field is discussed.  

  
 KEYWORDS:  Armadillo officinalis;  Punica granatum; transpiration; body mass; 

feeding and assimilation. 

1. Introduction 

he coastal region of Benghazi (20º  10’ N, 20º   06’ E), Libya, like other Mediterranean coasts 
(Kheirallah, 1980; Warburg et al. 1984) is colonized by the pillbug, Armadillo officinalis Dumeril.  

Casual collections showed that these woodlice occurred in large numbers in shady places where the soil 
moisture was moderate.  Detailed studies were conducted by us before in Benghazi on the transpiration, 
behavior, growth and feeding habits (Nair et al. 1989), conversion of  leaf litter (Nair and Fadiel, 1991), 
relation of body dimensions and the soil factors influencing the abundance (Nair and Al-Jetlawi, 1993), 
breeding and population biology (Al-Jetlawi and Nair, 1994), thermobiology (Nair et al. 2001) and food 
preference and litter breakdown (Nair et al. 2002) of this woodlouse. The present study investigates the 
impact of temperature acclimatization (14º C and 21º C) on the transpiration rate, increment in body mass, 
moisture, feeding and food conversion of  A. officinalis fed on the dry leaves of Punica granatum  
(Pomegranate) for 15 days.  Pomegranate trees are common in Benghazi and A. officinalis forms the major 
component of the decomposer fauna of the fallen litter from these trees.   

2. Materials  and  Methods 

A. officinalis having body mass ranging from 65 to 72 mg were selected for the study.  10 pillbugs (5 
males and 5 non-gravid females) each, after starving them for eight hours to evacuate their gut contents, 
were maintained at 14º C and 21º C in a Gallenkamp incubator.  Each animal, after taking its initial body 
mass near to 0.01 mg in a Sartorius balance, was kept in a glass petridish (5 cm diameter, 2.5 cm height) 
containing a layer of wet filter paper (62 ± 2 % R.H.) at the bottom. 300 mg of the dry leaf of Punica 
granatum macerated with water for 12 hours to make it soft, was provided as food.  The experiment lasted 
for 15 days, after which the body mass of the animal was determined.  The remaining leaf and the fecal 
matter ejected by the pillbug were collected, dried and weighed.  After measuring the transpiration rates, 
they were kept at 60º C for four days, dried and weighed to determine the moisture content.  The 
experiment was repeated again and there was not much variations in the values between the replications, so 
the data were  combined and the mean values of 20 pillbugs at each temperature were taken.  

To study the transpiration rates, the pillbugs were weighed individually to 0.01 mg and exposed 
separately for one hour over calcium chloride at the same temperature (14º  or 21º  C) in which they were 
maintained previously for 15 days, before re-weighing. The results are expressed as water-loss in      

mg/cm2 /h.  The surface area of the animal was calculated  from the formula 
2

3S = kW , where S = 
surface area, W = initial weight of the animal, k = constant.  A value of k = 12 was adopted as it has been 

T 



THERMAL EFFECTS ON A. OFFICINALIS 

 3

used by Cloudsley-Thompson  (1969) and Nair et al. (1989) for African woodlice, and Nair and Nair (1985) 
for Indian species.  This value is also the mean calculated by Edney (1951) for British species. 

Consumption of food (C )  of A. officinalis exposed to 14º  and 21º  C was estimated in terms of mg 
dry food consumed by it for 15 days, assimilation (A) was calculated by subtracting the amount of dry fecal 
matter (Fe) ejected from the total food consumed (C ).  The production rate (P) (due entirely to the increase 
in live body mass ) was determined as the difference between the body mass of the animal at the beginning 
and at the end of the experimental period.  Metabolism (R ) represents the difference between A and P.  
Assimilation efficiency (Ae) was calculated by expressing A as a percentage of C.  Gross (Ge) and net (Ne) 
production efficiencies were estimated expressing P as a percentage of C and A separately.  Rates of 
feeding (Fr), assimilation (Ar), conversion (Cr) and metabolism (Mr) were determined by dividing C, A, P 
and R  by half the sum of initial and final weights of the animal and then by the duration of the exposure 
period and expressed in terms of mg/g live wt/day. 
t-tests (Grimm, 1993) were done to find out the significance or otherwise of the data.  

3.    Results and Discussion  

Duke (1992)  reported that the leaf of P. granatum contains betulic acid, ursolic acid, corelagin, 
strictinin, tannin, granatins, casuariin, D-mannitol, 2-0-galloylpunicalin, 2-(2-propenyl)-delta-piperideine, 
1,2,3,4,6-penta-0-galloyl-beta-D-glucose and 1.2.4.6-tetra-0-galloyl-beta-D-glucose.  Our observations in 
the field revealed that the leaf of P, granatum is a preferred food for A. officinalis in the field, which was 
later confirmed through the laboratory studies on the food preference shown by them.  Also, higher 
breakdown of the dry leaf of P. granatum by these animals was observed in the field when compared with 
the breakdown of the dry leaf of Citrus limonia (lemon) (Nair et al. 2002). 
 
Table 1. Temperature acclimatization (14oC and 21oC) for 15 days on the increment in body mass, 
transpiration rate, moisture, feeding and food conversion (Mean ± SE) of A officinalis fed on Punica 
granatum dry leaf as food, t-values and their levels of significance. Total number of woodlice kept at each 
temperature: 20 
 
 

Animals exposed to the 
temperatures of 

 
SI.No 

 
Factors 

14 o C 21 o C 

 
t 

 
p 

1 Increment in body mass (mg) 0.97±  0.33 1.39±  0.21 1.09 1. >0.05 
2 Transpiration rate (mg/cm2/h) 0.71± 0.01 1.01 ± 0.03 9.53 2. <0.01 
3 Moisture (%) 52.20±  0.18 49.71  ±0.14 9.01 3. <0.01 
4 Assimilation efficiency (%) 81.16  ± 3.21 62.51 ± 1.67 5.16 4. <0.05 
5 Gross production  

efficiency (%) 
3.06   ±1.13 3.87  ±  0.54 0.65 5. >0.05 

6 Net production efficiency (%) 3.94  ±1.34 6.11  ± 0.82 1.38 6. >0.05 
7 Feeding rate (mg/g live wt/day) 23.57 ± 2.02 38.22±  3.33 3.76 7. <0.05 
8 Assimilation rate (mg/g live 

wt/day) 
19.29  ±1.97 23.66 ± 1.83 1.63 8. >0.05 

9 Conversion rate (mg/g live 
wt/day) 

0.62  ±0.20 1.49 ± 0.27 2.58 9. <0.05 

10 Metabolic rate (mg/g live 
wt/day) 

18.67±2.06 22.17 ± 1.65 1.33 10. >0.05 



ABDELGADER K. YOUSSEF and G. ACHUTHAN NAIR 

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Table 1 shows the increment in body mass; transpiration rate; moisture; assimilation efficiency; gross 
and net production efficiencies; feeding, assimilation, conversion and metabolic rates of A. officinalis at 14º   
and    21º C for 15 days fed  on the dry leaf of P. granatum, the t-values and their levels of significance.  
There was an average increase of 0.97 mg in body mass of A. officinalis at 14º  C which increased further to 
1.39 mg in those at 21º C, even though the difference in increment in body mass between acclimatized 
temperatures was insignificant (t = 1.09; p>0.05). 

The transpiration rate of 14º C acclimatized A. officinalis was 0.71 mg/cm2/h, which increased 
significantly (t = 9.53; p<0.01) to 1.01 mg/cm2/h in those at 21º C. The cuticle of land isopod is more 
permeable than that of insect (Wallwork, 1970) and it was previously believed that an oriented layer of lipid 
molecule, which functions as a water-proofing mechanism is lacking from isopods (Beament, 1961).  Later, 
however, Warburg (1965) and Edney (1968) suggested that some type of water-proofing mechanism may 
be present in some species. Measurement of transpiration rates of several species of woodlice at various 
temperatures demonstrated a sharp increase at higher temperatures suggesting that the ability of water-
proofing barrier is reduced at high temperatures (Cloudsley-Thompson, 1977; Nair and Nair, 1985).  This 
phenomenon might not have taken place in the present study since the higher temperature of 21º C was well 
within their tolerance limits and temperature acclimatization might be the sole criterion for their differences 
in transpiration rates. Our previous studies (Nair et al., 1989, 2001) on A. officinalis revealed that the 
exponential regression models fitted on transpiration in relation to temperatures were good and 
acclimatization of these pillbugs to different temperatures for a week  had marked effects on their 
transpiration and behavior, when later exposed to rising temperatures. 

A significant difference (t = 9.01; p<0.01) in moisture content was discernible in A. officinalis 
acclimatized between 14º  C (52.20%) and   21º  C (49.71%).  Significantly higher assimilation efficiency (t 
= 5.16; p<0.01) was recorded in those acclimatized at 14º  C (81.16%) than those at 21º  C (62.51%).  The 
values of gross and net production efficiencies, and also of feeding, assimilation, conversion and metabolic 
rates were higher in A. officinalis exposed at 21º C when compared with the values recorded at 14º C.  
However,  significant  differences  existed only between  their  feeding (t = 3.76; p < 0.05) and conversion 
(t = 2.58; p< 0.05) rates. 

Warburg (1987) opined that isopods in general seem to be efficient digesters but somewhat inefficient 
assimilators and that food consumption varies with species.  In the present study an inverse relationship  
was observed in A. officinalis on its feeding rate and efficiency of assimilation of the leaves of P. granatum.  
Better feeding was discernible in those kept at 21º C, but better assimilation efficiency was observed in 
those at 14º C.  Only a small percentage of the assimilated food (3.21% at 14º C and 6.30% at 21º C) was 
converted into the production of new tissues.  The food consumption of A. officinalis fed on P. granatum 
was 2.05% body mass/day at 14º  C and 3.79% body mass/day at 21º C.  These values were lower than 
those reported for Porcellio scaber (2.59% body mass/day at 14º C; 4.19% body mass/day at 21º C), 
another woodlouse which co-exists with A. officinalis in the field and were given P. granatum as food for 
15 days (unpublished data). 

In conclusion, temperature acclimatization has a significant impact on the transpiration rate, moisture, 
assimilation efficiency, feeding and conversion rates of A. officinalis fed on P. granatum, but not so on their 
increment in body mass, gross and net production efficiencies, assimilation and metabolic rates.  The effects 
of temperature on the activity of these pillbugs were confirmed in the field where they were found in large 
numbers crawling over the soil surface and actively feeding on the leaf litter when the surface temperature 
ranged between   18 and 29º  C, even though activities were restricted to shady places.  It was evident that a 
restricted grade of temperature gradient was essential for normal activity and feeding.  Except for short 
summer months of August/September, the temperature range of the habitats of these animals was well 
within their tolerance limits. 

 
 
 



THERMAL EFFECTS ON A. OFFICINALIS 

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4.  References 

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Received   4 June 2003     
Accepted  28 March 2004