II. The circulation of the Arachnida is next to be considered; and the term applied to these becomes strictly proper. Two great tribes, in our view of the subject, constitute this Class,—the spiders (Araneidea) and scorpions (Scorpionidea): I shall give you some account of the circulating vessels of each.—In spiders, the heart in general is a long dorsal vessel as in insects, but supposed to be confined to the abdomen, growing slenderer towards each extremity, particularly the anal. In some also, as in Aranea domestica, like that of insects, it has lateral muscular appendages; but in others, as in Clubiona atrox, it is without them[414]. It exhibits a pair of vessels that appear to connect with the gills, by which the oxygenation of the blood takes place, and a number of others that ramify minutely and are lost in the analogue of the epiploon, supposed to be their liver[415]. Whether these last are to be regarded merely as veins, has not been ascertained; they seem rather to convey the blood outwards, than to return it back to the heart: but this question must be left for future investigation. I may observe, however, that though the heart of the spider has been traced only in the abdomen, it may probably extend into the trunk.
The heart of the scorpion has been examined both by Treviranus and Marcel de Serres; but I shall principally confine myself to the description of the latter, as the most clear and intelligible. The heart, then, of these animals is elongated, almost cylindrical, but attenuated at each end; it is extended from the head to the extremity of the tail, and appears to have four pairs of lateral muscles. On each side are four pairs of principal vessels, which go to the pulmonary pouches, and there ramify. These may be assimilated to veins. Besides these, there are four other vessels that cross them, forming with them an acute angle, and which, with four branches of smaller size, receive the blood from the pulmonary pouches, and distribute it to the different parts of the body,—these are the arteries. Before it enters the tail, the heart throws out two vascular branches which do not go to the gills, but distributing the blood to different parts, ought to be considered as arteries[416]. Treviranus mentions bunches of reticulated vessels, concerning the use and origin of which he seems uncertain[417]; but as they approach the gills they are probably the branching extremities of what M. de Serres considers as the veins.
I am, &c.
"The immense Class of insects," says the immortal Cuvier, "in the structure of its alimentary canal exhibits as many variations as those of all the vertebrate animals together: there are not only the differences that strike us in going from family to family and from species to species; but one and the same individual has often a canal quite different, according as we examine it in its larva or imago state; and all these variations have relations very exact, often easily estimable, with the temporary or constant mode of life of the animals in which it is observable. Thus the voracious larvæ of the Scarabæi and butterflies have intestines ten times as large as the winged and sober insects—if I may use such an expression—to which they give birth[418]."
In the natural families of these creatures, the same analogy takes place with respect to this part that is observable in the rest of the Animal Kingdom; the length and complication of the intestines are here, as in the other Classes, often an index of a less substantial kind of nutriment; while their shortness and slenderness indicate that the insect lives by prey[419].
In considering therefore the parts connected with the digestive functions of the insect world, it will not be amiss to have reference to their food, and their mode of taking it; but first it will be proper to state and define the parts of this important organ.
In general the alimentary canal[420] is composed of the same essential tunicks as that of the vertebrate animals, consisting of an interior epidermis, a papillary and cellular tunick, and an exterior muscular one[421]. The first is usually tender, smooth, and transparent; but not always discoverable, perhaps on account of its tender substance[422]. Ramdohr does not notice the papillary and cellular tunicks; they are probably synonymous with what he denominates—the flocky layer (Die flockige lage), and which he describes, when highly magnified, as appearing to consist of very minute globules or dark points, and as being of a cellular structure[423]. The exterior tunick is thicker and stronger than the interior, and composed of muscular fibres, running either longitudinally, or transversely so as to form rings round the canal. This tunick mostly begins at the mouth, and goes to the anus, changing its conformation in different parts of the above intestine. Sometimes however it originates only at the beginning of the stomach[424]. With respect to its general disposition, that canal—in its relative length, in the size of its different parts, in the number and form of its dilatations, and particularly of its stomachs and its cœcums, and in the folds of its interior—exhibits variations altogether analogous to those of vertebrate animals, and which produce similar effects[425]. As to its parts, it may be considered as consisting of two larger portions, between which the biliary or hepatic vessels form the point of separation. In the first, the most universal parts are the gullet and the stomach; and in the second, the small intestine and the large intestine[426].
1. The gullet (Œsophagus[427]) is that portion of the intestinal canal which, receiving the food from the pharynx, or immediately from the mouth, conveys it to the stomach. Though it often ends just behind the head[428], it is usually continued through the trunk, and sometimes even extends into the middle of the abdomen[429]; it therefore seldom much exceeds in length half the body. It is constantly long when the head is connected with the trunk by a narrow canal—as in the Hymenoptera, Neuroptera, Lepidoptera, &c.; but is frequently short when these parts are more intimately united[430]. It often ends in a kind of sac analogous to the crop of birds. Under this head I must mention a part discovered by Ramdohr, which he calls the food-bag (Speisesack), as he thinks, peculiar to Diptera[431]. From the mouth in these proceeds a narrow tube into the abdomen, where it expands into a blind sac having no connexion with the stomach; so that the fluid food, as blood, &c. stored in it, must be regurgitated into the mouth before it can pass into that organ[432]. Thus these animals, besides their stomach, have a reservoir in which to store up their food; the product therefore of a single meal will require several days to digest it.
2. The stomach (Ventriculus[433]) is that part of the intestinal canal immediately above the bile-vessels, which receives the food from the gullet for digestion, and transmits it when digested to the lower intestines[434]. By its admixture with the gastric juice, the food acquires in the stomach a quite different colour from what it had in the gullet. In herbivorous insects it contains no acid, but, like the gastric juice of herbivorous quadrupeds, is of an alkaline nature[435]. The chyle is forced through this organ, probably in part by the pressure of the muscular fibres during the peristaltic motion; and being pressed through the inner skin, is first collected in the intermediate cellular part, and ultimately forced through the outer skin[436]. At its posterior end it terminates in the pylorus, a fleshy ring or sphincter formed of annular muscular fibres[437]. The stomach often consists of two or more successive divisions, which are separated from each other, and are often of an entirely different conformation and shape[438]. In the Orthoptera, Predaceous Coleoptera, and several other insects, an organ of this kind precedes the ordinary stomach, which from its structure Cuvier denominates a second stomach or gizzard[439]; Posselt improperly calls it Cardia[440]; and by Ramdohr it is named the plaited-stomach (Falten-magen[441]). It is a short fleshy part consisting of two skins, placed above the opening of the stomach, and perhaps rather belongs to the gullet. The inner skin is formed into longitudinal folds, and sometimes armed with horns, teeth, or bristles. Its cavity is very small and compressed, so as to admit only small masses of food, and yet present them to a wide surface for the action of the teeth or bristles;—in this stomach therefore, as in the gizzard of birds, to which it seems clearly analogous[442], the food is more effectually comminuted and rendered fit for digestion. The muscles, by which its action upon the food is supported, in some species amount to many thousands[443]. Rudiments of a gizzard are sometimes found concealed in the gullet of many insects[444]. The idea of Swammerdam, Cuvier, &c. that grasshoppers and other insects that have this kind of stomach, chew the cud[445], Ramdohr affirms is entirely erroneous[446]. Besides its divisions, the stomach has other appendages that require notice. In most Orthoptera, a pair or more of blind intestines or cœca may be found at the point of union of the gizzard with the stomach[447], which have been regarded as forming a third stomach: they also begin the stomach in the louse[448]; they form a coronet round the apex of that organ, in the grub of the cockchafer[449]; and in that of the rose-beetle, there is one at the apex, one in the middle, and a third at the base[450]. Besides these appendages, which are formed of the skin of the stomach, there are others that are not so. In the Predaceous and some other beetles, the whole external surface of this organ is covered with small blind appendages opening into the space between its two skins, which cause it to resemble a shaggy cloth; these Ramdohr calls shags (zotte[451]), and Cuvier, hairs[452] (villi). These appendages the latter author seems to regard as organs that secrete the gastric juice and render it to the stomach[453]; but the former thinks their use uncertain[454].
3. The small intestines (Intestina parva) are the portion of intestines next the stomach, and consist often of three distinct canals;—the first is supposed to be analogous to the duodenum; it is found only in the Coleopterous genera Silpha L. and Lampyris L., and is distinguished from the succeeding intestine by being perfectly smooth[455]. Next follows the thin intestine (Dünndarm), which in the above insects is wrinkled; it most commonly immediately follows the stomach. Sometimes it is wholly wanting, as in Agrion, the Hemiptera[456], &c. Ramdohr conjectures that it is not solely destined for conveying the excrement, but that probably some juices are separated in it from the food especially for the nutrition of the gall-vessels, as their principal convolutions are mostly near this intestine[457]; which perhaps may in some cases be regarded as analogous to the jejunum in vertebrate animals. The third pair of the small intestines, which perhaps represents the ileum, Ramdohr distinguishes by the name of club-shaped (Keulförmigen Darm[458]). It may generally be regarded as only a continuation of the former thickened at the end so as to resemble a club reversed. It is however sometimes separated from the thin intestine, as in Cerambyx moschatus[459].
4. The large intestines (Intestina magna) consist sometimes of two portions. The thick intestine (Dicken-darm), which may be regarded as a kind of cœcum, is found only in the larvæ of the Lamellicorn beetles, but never in the perfect insect. In shape it is oval and folded; whence it is thicker than the rest of the intestinal canal, and is constantly filled with excrement[460]. The second portion of these intestines is the rectum (Mastdarm), which terminates in the anal passage. This part is scarcely ever wanting, except when the insect evacuates no excrement, which is the case with the grubs of bees, wasps, and the antlion (Myrmeleon). In the imago of Telephorus, at least in T. fuscus, it is also obsolete[461]: in most cases, however, it is very distinct from the preceding intestine. Sometimes it consists of only one tunick composed of muscular fibres[462]. When the gullet is wide, the rectum is usually so likewise; but when it follows a club-shaped or thick intestine, it is narrow[463]. It generally may be termed short[464]. When wide, it often contains a great quantity of excrement, as the gullet does of undigested food; but when narrow, the excrement seldom remains long in it. This intestine also in a few cases has a lateral enlargement or cœcum (Blind-darm), being a continuation of the same skin; but perhaps this enlargement is really analogous to what Ramdohr calls the thick intestine, though in these cases he regards it as an appendage of the rectum[465].
I must now call your attention to the bile-vessels of insects. These, by Malpighi[466] and the earlier physiologists, who regarded them as a kind of lacteals, were denominated varicose vessels: but Cuvier—and his opinion after some hesitation has been adopted by Ramdohr—considers them as vessels for the secretion of bile, and as analogous to the liver of animals that have a circulation[467]. As the want of blood-vessels prevents insects from having any gland, the bile is produced with them, as all their other secretions, by slender vessels that float in their nutritive fluid, and from thence secrete the elements proper to form that important product, which usually tinges them with its own yellow hue; though in the Lamellicorns and Capricorns they are of an opaque white, and in the Dytisci of a deep brown colour[468]. Their bitter taste further proves that they contain the bile[469]. They are long, slender, filiform, tortuous or convoluted, and mostly simple vessels; sometimes gradually smaller toward the base[470], at others towards the apex[471]. In some, screw-shaped[472]: in one larva, with hemispherical elevations[473]: in the cockchafer, part of them are fringed on each side with an infinity of short, blind, minute, setiform tubes, while the rest are naked[474]; they are composed of a single, thin, transparent membrane, according to Ramdohr[475]; but Cuvier thinks their texture is spongy[476]. They appear to contain a number of small, irregular, dark granules, which float in a peculiar fluid, with which, however, they are not always filled throughout, nor are they constantly permeable from one end to the other. Thus in the meal-worm beetle (Tenebrio Molitor), the common trunk by which they are attached to the intestinal canal is composed of gelatinous granules[477]. The place of their insertion is generally a little below the pylorus, but in the common cockroach they are inserted into the stomach just above that part[478]. Usually each vessel opens singly into the intestinal canal, which the whole number surround at an equal distance from each other[479]. Sometimes, however, they are connected with it by a common tube in which they all unite, as in the asparagus-beetle (Lema Asparagi[480]), and the mole-cricket (Gryllotalpa vulgaris[481]); in the house-fly (Musca domestica), and other Muscidæ, each pair unites so as to form a single branch on each side of the canal previously to their insertion[482]; in the field-cricket (Gryllus campestris) they are all inserted in one spot[483]; and when numerous, they are generally attached singly though irregularly[484]. These vessels at their base do not open into the cavity of the intestinal canal, but merely into the space between its outer and inner tunicks, the last being constantly imperforated[485].
With regard to their apex, the bile-vessels are sometimes fixed singly or connectedly to the intestine merely by a few muscular fibres; for they do not enter it, their ends having no orifice. This structure is mostly to be met with in the Coleoptera[486]. In caterpillars, the tops of these vessels perforate the outer skin of the rectum, and proceeding in dense convolutions to the anus, become at last so fine that their terminations cannot be discovered[487]. In other cases, the extremities of a pair of these vessels unite so as to form a double one: this may be seen in those of Philonthus politus[488], and probably other rove-beetles: and lastly, in others the bile-vessels are free, hanging down by the intestinal canal, without being attached to it or to each other. This structure is constantly found in the Orthoptera and Hymenoptera Orders, &c.[489].
With regard to their number, the bile-vessels vary from two to upwards of one hundred and fifty, yet so that their whole amount is constantly the product of the number two,—at least as far as they have been counted: and even when those on one side are not alike, a similar variation takes place in the other, as may be seen in Galleruca Vitellinæ, where on each side are two long ones and one shorter[490]; the most usual numbers are, four—six—or many, that is, more than twenty—
| Two bile-vessels are found in | the larva of Cetonia aurata[491]. |
| Four | most Coleoptera, Diptera, and Hemiptera[492]. |
| Six | Lepidoptera, some Coleoptera[493], &c. |
| Eight | Myrmeleon, Hemerobius[494]. |
| Fourteen | Formica rufa[495]. |
| Twenty | larva of Clavellaria Amerinæ[496]. |
| Many | Libellulina, Orthoptera, and Hymenoptera[497]. |
The bile-vessels vary considerably in length: in many cases where they are free they are short[498]; they are often very long, and perhaps those that are fixed may be generally stated as the longest. In the Lamellicorn beetles they are remarkable for their great length[499].
Having given you this general account of the intestinal canal and its parts and appendages, I shall now state some of the peculiarities that in this respect distinguish particular tribes and families.
The Coleoptera alone, exhibit as many variations in the structure of the alimentary tube as all the other Orders of insects together:—to particularize these would occupy too large a portion of this letter, I shall therefore only notice a few of the most remarkable. In general they may be stated as having universally a stomach, a small intestine and rectum, and not more than three pairs of fixed or united bile-vessels. In the Predaceous beetles, the gullet mostly widens at the base into a considerable crop, followed by a gizzard, a shaggy stomach, and two pairs of united bile-vessels. The whole alimentary canal in these, is never less than double, and sometimes treble the length of the body[500]. In the carnivorous beetles, at least the Staphylinidæ and Silphidæ, there is little or no crop, and the gizzard is hidden: in the former, the whole length of the intestinal canal is not twice, while in the latter it is more than four times that of the body[501]. In these also the intermediate portion of the large intestine is singularly annulated[502]. In the Petalocera the stomach is usually longer than all the rest of the intestines together, and often convoluted: in the cockchafer the whole intestinal canal is nearly five times the length of the body, four parts of which is occupied by the stomach[503]. In the grub the canal scarcely exceeds the length of the animal[504]. In Lampyris the stomach exhibits a remarkable appearance, having on each side a series of spherical folds or vesicles[505]. Have these any thing to do with the secretion of its phosphoric matter? Tenebrio has a gizzard armed internally with calluses, and a shaggy stomach, and Blaps does not differ materially; their entire canal is more than twice the length of the body[506]. In the vesicatory beetles (Cantharis, Meloe, &c.) there is no gizzard, and the canal is less than twice the length of the body[507]. Little is known with regard to the alimentary canal of the beetles distinguished by a rostrum (Rhyncophora). In the only two that appear to have been examined, Rhynchites Betuleti and Cryptorhynchus Lapathi, that canal is moderately long, the stomach partially shaggy, and the small intestine inversely claviform; but in other respects they differ materially[508]. In the former there is no crop or gizzard, the stomach is fringed on each side, except at its upper extremity, with a series of small cœca or shags, and there are three pairs of bile-vessels[509]; while in the latter the gullet is dilated into a crop which includes a gizzard in which the skill of a Divine artist is singularly conspicuous:—though so minute as scarcely to exceed a large pin's head in size, it is stated to be armed internally with more than 400 pairs of teeth, moved by an infinitely greater number of muscles[510]. A transverse section of this gizzard represents two concentric stars, with nine rays each[511]: the object of this structure is, the comminution of the timber which this beetle has to perforate and probably devour[512]. The stomach is very slender, but dilates in the middle into a spherical vesicle[513], and there are only two pairs of bile-vessels[514]. In the Capricorn beetles, the part we are considering varies much: in general we may observe that it is more than double the length of the body, that the stomach is long and slender, and usually naked, that the gullet terminates in a crop without a distinct gizzard, and that there are three pairs of bile-vessels[515]. In the Herbivorous beetles (Chrysomela, Cassida, &c.) the canal is more than double the length of the body, and in some much longer[516], the stomach is long, and commonly naked; but in Chrysomela violacea it is covered with hemispherical prominences[517], and in Chrysomela Populi it is shaggy[518]; in the insect last named and Galleruca Vitellinæ the rectum consists of two pieces[519]. In this tribe the intestines of the larva resemble those of the perfect insect[520].
In the Orthoptera the alimentary canal, which continues the same in every state, is short, or only moderately long; the gullet has one or two lateral pouches or crops[521], and terminates in a gizzard of curious construction, with singular folds and teeth[522]; then follows a short stomach, usually with a pair or more of cœca at its upper extremity[523]; the lower intestines are not distinct, and the bile-vessels numerous, short and free[524].
In the Neuroptera, many of the genera are distinguished by the remarkable length of the gullet, and by the lower intestines forming one short piece[525]. In the Libellulina the bile-vessels are numerous, short, and free, as in the Orthoptera[526]. In Hemerobius and Myrmeleon there is a gizzard[527], and just above it a cœcum, in the former very remarkable, is connected with the gullet[528].
The Hymenoptera appear all to be distinguished by a long slender gullet, terminating in a dilated crop forming the honey-bag; their stomach is variable, their small intestine slender, and the rectum dilated;—their bile-vessels, like those of the two preceding Orders, are numerous, short, and free[529]. In the ants and ichneumons there is an approach to a gizzard[530]. In the wasp and humble-bee the stomach is very long, with muscular rings surrounding it[531]. In this Order the larvæ at first have no lower intestines and void no excrement[532], but as they approach to the pupa state one begins to appear[533].
The next insects whose alimentary canal we are to consider, are those which, taking their food by suction, have no occasion for masticating organs: this may in part be predicated of the preceding Order, in which most of the tribes in their perfect state imbibe fluid food, and use the ordinary organs of mastication principally in operations connected with their economy; and their crop, in which the honey in many is stored up for regurgitation, may be regarded in some degree as analogous to the food-bag of the Diptera and other suctorious insects.
The two sections of the Hemiptera Order differ widely in the canal we are considering, and I shall therefore give a separate account of each. In the Heteropterous section, appended to the gullet by a long convoluted capillary tube, besides the usual saliva-reservoirs there is often a double vessel, which Ramdohr regards as discharging the same function, but which in many respects seems rather analogous to the food-reservoir of the Diptera[534]. As I have had no opportunity of examining this vessel, I shall content myself with stating this idea, and describe the vessel more fully hereafter. The gullet, in these, usually terminates in an ample crop consisting of many folds[535], followed by a long, slender, cylindrical tube, dilated at its base into a spherical tumour; these two may be said to form the first stomach: to this succeeds a second[536], which Ramdohr denominates the bug-stomach (Wanzen-magen), which varies in its figure, and in Pentatoma consists of four demi-tubes, so as to form a quadrangular canal[537]. In the Homopterous section of this Order Ramdohr seems to have examined but few; Chermes however and Aphis exhibit one remarkable feature; they have no bile-vessels, at least he could discover no trace of these organs[538]. Their intestinal canal is very simple, their stomach very long, widest above, and somewhat convoluted, with a very slender gullet[539]. In Cercopis spumaria the structure is more complex, and extremely singular. It has two or rather three stomachs; the two first of a horny substance, and the last a slender somewhat convoluted membranous tube, which becoming reversed, is attached by what should be deemed its lower extremity to the first stomach, from the other side of which emerge the lower intestines, terminating in a thick pear-shaped rectum. At the same point of the first stomach the four bile-vessels are attached, they grow gradually thicker for about a third of their length, when they become twisted like a cord, and taper towards the rectum, to which also they are attached[540]. From this structure it should seem that the food has to pass twice through the first stomach, before the process of digestion is complete, and it is rejected at the anus.
The next suctorious Order is the Lepidoptera: in these the gullet is long and slender, surrounded at the beginning with a loose transparent skin, and at the base furnished with a pair of lateral sacs, forming the honey-stomach, and probably analogous to the food-reservoirs of the Diptera, which when blown up are of an oval form; the stomach, as in the bugs, consists of two portions, the first being the longest[541]. There are three free bile-vessels on each side, proceeding from a single branch[542]. It will not be uninteresting here to abstract from Herold the progressive changes which take place in the intestinal canal in this Order, during the transition of the animal from the larva to the imago state. In the larva, the gullet, the small intestine, and the rectum, are short and thick[543], there are a pair of silk reservoirs (sericteria), as well as vessels for the secretion of saliva (sialisteria): if you examine it two days after its first change, you will find the gullet and the small intestine much lengthened and become very slender; the stomach contracted both in length and size; the rectum also changed, and the silk vessels contracted[544]. These in a pupa eight days old have wholly disappeared; the gullet is become still longer, its base is dilated into a crop or food-reservoir; the stomach is still more contracted, and instead of a cylinder represents a spindle; the small intestine also is lengthened[545]: at a still more advanced period, when it is near appearing under its last form, the gullet and small intestine are still more drawn out; and the honey-bag, though very minute, has become a lateral appendage of the gullet[546]; and lastly, in the butterfly it appears as a large vesicle[547]; the small intestine is grown very long[548]; and the rectum has changed its form and acquired a cœcum[549]. When we consider the adaptation of all these changes of form, the loss of old organs and the acquisition of new ones, to the new functions and mode of life of the animal, we see evidently the all-powerful hand of that Almighty Being who created the universe, upholding by his providence, and the law that he has given to every creature, the system that he at first brought into existence.
We now come to the Diptera. These have a very slender gullet, to which is attached on one side a long filiform tube, terminating in the food-reservoir, which in some instances is simple[550], but most generally consists of two or more vessels[551], collapsing when empty, but varying in shape and size when inflated with food: the mouth of the stomach in many cases is dilated into a kind of ring[552]; sometimes there is on each side a blind appendage or cœcum opening into it, in Bombylius covered with shags, which though not connected with the mouth by a tube, Ramdohr regards as saliva-reservoirs[553]; in Musca vomitoria the beginning of this organ below the mouth is covered with hemispherical prominences, and in Tipula it is dilated and marked with transverse folds. There are usually two pairs of bile-vessels; in the Muscidæ pedunculate and free[554]; in Tipula, Bombylius, and Leptis, sessile and united[555]; and in Tabanus sessile and fixed[556]. It is remarkable that in some of this Order—the reverse of what usually happens—the alimentary canal appears to be much longer in the larva than it is in the imago; in Musca vomitoria, its length in the former is two inches and a quarter, while in the latter it is only one inch and one third[557]. A singular organ distinguishes the imago of this species, the use of which appears not to be discovered. It succeeds the rectum, and has on each side two short club-shaped appendages, open at the end, which receive tracheæ, and terminate in a short piece that opens into the anus[558].
In Hippobosca and its affinities the canal in question differs from that of other Diptera, in having no food-reservoir; in other respects it resembles it[559].
From the above statement it appears that the principal character which distinguishes those that take their food by suction, from those that masticate it, is the faculty with which they are furnished by means of an ample crop, honey-stomach, or food-reservoir, of regurgitating the food they may have stored up. Another distinction still more striking, which will appear more evidently hereafter, is to be seen in the saliva-secretors with which the suctorious tribes are furnished, to be found in very few masticators, by which they are enabled to render the juices more fluid and fit for suction.
The only insect amongst the Aptera whose alimentary canal I shall notice, is the common harvest-man (Phalangium Opilio): in this, though the stomach and lower intestine are remarkably simple, yet their cœcal appendages are numerous and singular: the former, which has no distinct gullet, is pear-shaped[560]; and the latter, tapering downwards, and truncated at the end[561]; connected with it above are no less than twenty-three cœca or blind appendages, of various forms and dimensions; the last pair but one of which is very remarkable, being bent like a bow, and furnished externally with four short clavate processes[562]. It is probable that some of these organs are analogous to the bile-vessels of other insects.
When the Creator in his wisdom fixed the limits of the various tribes of animals, he united them all into one harmonious system by means of certain intermediate forms, exhibiting characters taken some from those that were to precede, and others from those that were to follow them, and this not only in their external structure, but likewise in their internal organization; so that we are not to wonder if in the same individual we meet with organs that belong to two distinct tribes, or if, remaining nearly the same in their prima facie appearance, they begin to exercise new functions. An instance of this we have seen in the dorsal vessel of insects, which in the Arachnida, though not materially different in situation or general form, by the addition of a small apparatus of arteries and veins becomes the centre and fountain of a regular system of circulation[563]. From the circumstances here alluded to, physiologists have been led to entertain very different sentiments with regard to the structure of the alimentary organs of the Class we are now to enter upon, the Arachnida: what some regard as a real liver, others look upon as an epiploon or caul; and what the last denominate bile-vessels are by some of the former considered as appropriated to the secretion of chyle[564]. Yet both these opinions have some foundation in nature. When, in the Arachnida, we discover a lobular substance consisting of granules filling the whole cavity of the body and wrapped round the intestines, every one will see in it no small analogy to the epiploon which in insects performs the same function: but when, upon a further examination, we detect certain vessels communicating with this substance and the intestinal canal[565], the idea that these may be hepatic ducts, and this substance analogous to the liver, immediately strikes us as not improbable. Again: when we discover pairs of other capillary and tortuous vessels connecting with the intestinal canal either at the pylorus[566] or below it[567], which in appearance strikingly resemble the bile-vessels which we so constantly find in insects, we seem warranted in concluding that they are of the same nature and use: but when a nearer inspection enables us to detect the hepatic ducts just mentioned in the scorpion, and we find that these capillary vessels in the spider are in a very different situation from those in insects which we suppose them to represent, it occurs to us as not unlikely, that their function may be different.
Let us now consider how the intestinal canal is circumstanced in the two sections into which the Class Arachnida is divided; the Scorpionidea, and Araneidea. In the Scorpions, this organ proceeds from the mouth to the anus without any flexure or convolution, so that its length is scarcely equal to that of the body[568]; it is slender, and its diameter, with the exception of an irregular dilatation here and there, is nearly the same in its whole extent; the gullet is short; the stomach long, and nearly cylindrical; the duodenum shorter and thicker than the stomach, from which, as well as from the rectum, it is separated by a valve; the latter is cylindrical, and opens at the anus above the insertion of the vesicle that secretes the poison[569]. With regard to the biliary system and its organs: The liver is of a pulpy granular consistence and of a brownish colour, fills the whole cavity of the trunk and abdomen, and serves as a bed for the other intestines. It is divided longitudinally into two portions, by the channel in which the heart reposes—its anterior part is formed into many irregular lobes, by the sinuosities of the trunk; at the other extremity, it terminates in two acute ends, which enter the first joint of the tail; its surface presents a reticular appearance, the result of the approximation of polygonous lobuli; its interior is a tissue of infinitely minute glands: in Scorpio occitanus there are about forty pyramidal lobuli detached from each other, the summits of which, by their union, form bunches that have their excretory canals, varying in number in different species, which convey the bile to the alimentary tube; in the above insect there are six pairs, three in the trunk and three in the abdomen, and in S. Europæus a smaller number[570]; these vessels run transversely from the liver, or aggregation of conglomerate glands, to the intestinal canal[571]; the bunches consist of an infinite number of spherical glands, generally filled with a brown thick fluid[572]: besides the transverse vessels, from the base of the stomach there issue two pairs of very slender tortuous ones, seemingly analogous to the common bile-vessels; one pair of which runs upwards, one on each side that organ towards the mouth, forming here and there some ramifications which enter the liver; and the other runs nearly transversely to it[573]. As the fluid contained in these vessels is different from that contained in the glands of the liver, M. Marcel de Serres supposes they may be chyliferous[574].
In the Araneidea also the alimentary canal is nearly straight, and scarcely exceeds the length of the body: the gullet is rather thick and cylindrical[575]; the stomach is distinguished anteriorly by two pairs of sacs, the upper pair being much the largest and nearly triangular, the lower linear[576]; from these sacs a narrow tube runs towards the rectum, but which is so entangled with the liver, muscles, &c., as not to be easily made out[577]; the rectum is rather tumid, and has a lateral cœcum[578]. The disposition of the liver or conglomerate glands is stated to be similar to that of the scorpion[579]; it is usually white, but in some species it is yellowish, or reddish, and its lower surface has sometimes regular excavations[580]; no transverse hepatic ducts connecting it with the alimentary canal, as in the scorpion, appear to have been at present discovered: two pairs of capillary free vessels are attached to the base of the rectum on one side, which, except in their situation, seem analogous to the bile-vessels of insects[581].
From the above detailed account of the alimentary canal of the animals whose internal anatomy we are considering, it appears that M. Cuvier's observation—that the length and complication of the intestines indicate a less substantial kind of nutriment—does not hold universally: thus, in Necrophorus and Silpha, carnivorous insects, the intestinal canal in its length and convolutions exceeds those of most herbivorous ones, and in Cassida viridis and some others of the latter tribe are not longer than those of the predaceous beetles. In herbivorous larvæ also, in general, the length of the alimentary canal does not exceed that of the body, but in those of some flesh-flies (Musca vomitoria) it very greatly exceeds it[582]. So true is the observation—that there is no general rule without exceptions.
In this letter it may not be out of place to say a few words upon the excrements of insects; which, strange as the observation may seem, but it is no less true than strange, are sometimes pleasing to the eye, from their symmetry, and to the taste, from their sweetness. In those that masticate their food they are solid, and in those that take it by suction, fluid or semi-fluid. In the caterpillars of Lepidoptera they are of the former description, and every grain wears some resemblance to an insect's egg: as the passage in many of these consists of six fleshy parts separated by channels, so the excrement represents six little prisms separated by six channels[583]. The Aphides all secrete a fluid excrement as sweet as honey, of which the ants are so fond[584], which is ejected not only at the anal passage, but, in many, by two little siphonets also above it[585]. A semi-fluid excrement is produced by some species of Chermes, as that which inhabits the Box, which often comes from the animal in long convoluted strings resembling vermicelli. Reaumur says its taste is agreeable, much more so than that of manna[586]. Under this head should be included the abundant spume with which the larva of Cercopis spumaria envelopes itself[587].
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