Since 1838 it has been known that all plants and animals are composed of small structural elements called cells (Latin, cellula; Greek, *vros). The lowest forms of animals and of plants are alike in being single cells throughout life. The more complex organisms are groups of cells, which have been derived by process of repeated division from a single cell, the fertilized ovum. Thus the human body, which begins as one cell, becomes in the adult an aggregation of cells variously modified and adapted to perform special functions. Since the liver is a mass of essentially similar cells, the problems of its functional activity are the problems of the functions of a single one of its cells. The diseases of the liver are the result of changes occurring in these cells, which must be restored to a normal condition to effect a cure. As this is equally true of other organs, it is evident that cytology, the science of cells, is a basis for both physiology and pathology.

A cell may be defined as a structural element of limited dimensions, which under certain conditions can react to external stimuli and perform the functions of assimilation, growth, and reproduction. Because of these possibilites a cell may be considered an elementary organism. It is described as a mass of protoplasm containing a nucleus. A third element, the centrosome, is found in the cells of animals, but it is doubtful whether it exists in the cells of the higher plants. It becomes prominent when a cell is about to divide. Some authorities regard the centrosome as a temporary structure, which forms shortly before division begins and disappears after it is completed. Others consider it as a permanent and essential part of a cell, which accordingly consists of protoplasm, nucleus, and centrosome.

Protoplasm is the living substance of which cells are composed. More specifically the term is applied to this living substance exclusive of the nucleus, or to the corresponding dead material, provided that death has not changed its physical properties. It has been proposed to substitute the name cytoplasm for protoplasm in the restricted and earlier sense of the term, to call the nuclear substance karyoplasm, and to consider both cytoplasm and karyoplasm as varieties of protoplasm. Although these names are often employed, the cell substance apart from the nucleus is ordinarily called protoplasm.

Protoplasm is a heterogeneous mixture of substances forming a soft viscid mass of slightly alkaline or neutral reaction. ("The terms may be used interchangeably for an alkalinity which is so slight" Henderson.) It is ordinarily more than three-fourths water, and the remainder consists of salts and organic substances, some in solution and some in a colloidal state. The organic bodies are classed as proteins, glycogen or some allied carbohydrates, and lipoid (fat-like) bodies. Protoplasm may exist in a numberless variety of forms.

In the four quadrants different types of protoplasmic structure are represented namely, homogeneous, granular, foam-like, and fibrillar.

Even the ground substance of protoplasm, in which the fibrils or granules are imbedded, is not necessarily homogeneous. According to Biitschli's interpretation it has the structure oj foam or of an emulsion that is, it consists of minute droplets of one substance completely surrounded by walls of another substance. In these walls, granules and filaments may be lodged, as seen at the margins of the upper right quadrant of Fig. i. The complex chemical activities of a cell are said to be manifestly impossible in any homogeneous mass; but in such a heterogeneous medium as an emulsion, they are conceivable (Alsberg). In other words, the vital qualities of protoplasm may not depend so much on hypothetical complex and unstable living molecules, as upon the interaction of various substances, made possible by their arrangement in droplets and investing films.

The various structures commonly observed in protoplasm may be grouped as follows:

i. Granules. Ultra-microscopic granules doubtless exist in protoplasm, since the smallest of those observed approach the limit of visibility. The minute granules, if abundant, give the

Xissl's bodies.

protoplasm a dark color. Often they are absent from the peripheral layer of protoplasm, or exoplasm, which is then clear, somewhat firmer, and chemically different from the inner endoplasm (Fig. i). In addition to minute granules such as may be found in most preserved protoplasm, certain cells contain larger granules, which are important secretory products elaborated by the cell. In active gland cells these granules are well defined and abundant, and F JG . 2 . CLUMPS OF~GRANULES

.ij..., ., IT i i j (NissL's BODIES) IN A NERVE

they diminish as the cell becomes exhausted. CELL.

be distinguished by the size and staining reaction of the granules imbedded in their protoplasm. In certain nerve cells (Fig. 2) granules occur in large groups, known as Nissl's bodies. As Crile has shown, these become disorganized as a result of surgical shock or muscular

Reticular apparatus. FIG.. 6. RETICULAR NETWORK (Fig. 3).

3. Vacuoles. Protoplasm often contains large or small drops of clear fluid, fat, or some other substance less highly organized than the surrounding material (Fig. 4). In preserved cells the spaces which were occupied by these droplets appear clear and empty, and are known as vacuoles.

tiey vary greatly in size, and one or several of them may be found in a single cell. 4. Canals. The protoplasm of certain cells is said to contain fine tubes or clefts which communicate with lymphatic spaces outside of the cell

(Fig. 5). Prolongations from the surrounding capsule-cells have been described as entering these canals and as performing, together with the lymph, a nutritive function. Hence the network of canals has been called trophospongium. But it has not been shown conclusively that these canals open to the exterior of the cell. They may be similar to the closed networks or "reticular apparatus" lying wholly within the protoplasm, shown in Fig. 6. Such networks have been described in nerve cells, cartilage cells and gland cells. The network is said to be of a thick fluid consistency. In certain gland cells there are canals within the protoplasm, which convey the secretion to the free surface of the cell. These may be simple, branched, or arranged in a network. Like the other forms of intracellular canals, they can be studied only in special preparations.

5. Inclusions. Various foreign bodies, such as other cells or bacteria, which may have been ingested by the protoplasm, are grouped as inclusions. This term is applied also to crystalloid substances formed within the protoplasm (Fig. 7), and to coarse masses of pigment granules which appear extraneous.

NUCLEUS.

The nucleus (Latin, nucleus, "the kernel of a nut"; Greek, Kdpvov, "a nut") is typically a well-defined round body, situated near the center of the cell, appearing denser or more coarsely granular than the surrounding protoplasm (Fig. i). There are characteristic variations in the shapes of nuclei, in their position within the cells and in their structure.

Ordinarily the karyoplasm, or nuclear substance, is sharply marked off from the cytoplasm by the nuclear membrane. Sometimes, in preserved tissues, the cytoplasm has shrunken away from the nuclear membrane, so as to leave a narrow space partially encircling it; and in certain living cells, the nucleus migrates through cytoplasm, as if it were an independent body. But there are phases of cell-development in which the nuclear membrane disappears and no line can be drawn between karyoplasm and cytoplasm. At all times they have a common structural basis. The ground substance of the nucleus, corresponding with the hyaloplasm, is the nuclear sap; and it contains, for spongioplasm, a meshwork of delicate linin fibrils. These help to form the nuclear membrane, in which they terminate. The nuclear membrane, nuclear sap, and linin reticulum do not stain deeply, and are therefore grouped together as the achromatic constituents of the nucleus.

The principal chromatic constituent of the nucleus is known as chromatin. It stains deeply, since it contains a large amount of nucleic acid, which has a marked affinity for basic stains. Chromatin occurs in the form of granules, which are bound together in strands or masses by the

Certain nuclei contain one or more round bodies, which belong with the chromatic elements because of their deep staining, but which are chemically different from chromatin. These bodice, known as nucleoli, are stained with acid or neutral dyes. They are said to be composed of paranuclein, whereas chromatin is composed of nuclein. In distilled water the structures formed of nuclein disappear, but those consisting of paranuclein remain. The nuclei of nerve cells contain typical nucleoli (Figs. 3 and 5). Sometimes a nucleolus, lodged in the nuclear reticulum, is more or less covered with chromatin (Fig. 9, A), but the term should not be applied to irregular knots of chromatin, even when most of the chromatic material within a nucleus is gathered into one or two such bodies. These are the so-called false nucleoli (pseudonucleoli).

Every nucleus, therefore, consists of ground substance or nuclear sap, a network of linin, and granules and masses of chromatin. Usually it is surrounded by a membrane, and sometimes it contains a nucleolus. Most cells contain a single nucleus; but occasionally a single cell contains two nuclei, as is frequent in the liver, or even several nuclei, as in certain cells associated with bone. Non-nucleated bodies, like the mammalian red blood corpuscles, and the dead outer cells of the skin, have lost their nuclei in the course of development.

Functionally the nucleus is regarded as a center for chemical activities necessary for the life of the cell. It is believed to produce substances which pass out into the cytoplasm, where they may be further elaborated. Evidences of nuclear extrusions into the cytoplasm have been frequently recorded. But the interactions between nucleus and cytoplasm, of such nature that they cannot be observed under the microscope, are presumably of far greater biological importance.

CENTROSOME.

The centrosome is typically a minute granule in the center of a small sphere of differentiated protoplasm. Often the term is applied to this entire structure, but it refers particularly to the central granule; the enveloping sphere is known as the attraction sphere, and it is composed of archoplasm^ When a cell is about to divide, delicate fibrils, either rearranged from the protoplasmic reticulum or formed anew, radiate from the archoplasm toward the periphery of the cell. The central granule becomes subdivided into two, which then move apart. In resting cells,

Centrosomes have been detected in many forms of resting cells, and it is assumed by some authorities that the centrosome is an invariable constituent of the cells of the higher vertebrates. According to this opinion the centrosome may become inconspicuous but it never loses its identity. Often they are found very close to the nuclear membrane, which may be indented to accommodate them; and rarely, as in certain cancer cells and in one form of the worm Ascaris, they have been reported as within the nucleus. They may occur near the free surface of certain cells, usually in the form of diplosomes, as shown in cell a, Fig. 8. Just above the diplosome, such cells may send out contractile projections of protoplasm (pseudopodia), with the activity of which the! diplosome may be in some way associated.j Pseudopodia, with an underlying diplosome, have been observed in the columnar cells of the human large intestine. In cell b of Fig. 8 there are four diplosomes, one of which lies beneath the protoplasmic projections. It is believed that the diplosomes may multiply

by fission, and that thus they may give rise to the numerous motile hairs, or cilia, which project from certain cells. Of these they form the basal bodies (Fig. 8, c). In many gland cells the centrosome lies in the midst of the protoplasm where the secretion accumulates. The discharge of the secretion is accomplished by the contraction of the protoplasmic strands in which the centrosome is lodged. In all these relations the centrosome appears to be a center for motor activities, and it is described as the kinetic or dynamic center of the cell.

To show diplosomes, and (in c) cilia with basal bodies.

The protoplasm at the surface of certain cells floating in the blood or lymph forms a thin pellicle, apparently as a result of protoplasmic concentration, or other reaction to the surrounding medium. Cells which line the greater part of the digestive tube, and have only one surface directed toward the intestinal contents, are provided with a thick wall on the exposed surface. Such a wall is called a cuticular border, or cuticula. On the other sides of these cells, the membrane is much thinner, and on the basal surface it is sometimes lacking. In such cases the protoplasm appears to be continuous with that of the underlying cells. In other cases

In examining a group of cells, it will be important to determine whether they are merely in contact, or actually continuous. Sometimes cells are so completely fused that their nuclei are irregularly distributed through a single mass of protoplasm. Such a formation is a syncytium in which the position of the nuclei is the only means of estimating the territory of a single cell. A syncytium may arise from the fusion of cells, or, as in striated muscle fibers, it may be due to the multiplication of nuclei in an undivided mass of protoplasm. Instead of being completely fused, cells are often joined to one another by protoplasmic processes of varying length and width, thus forming cellular networks. Fibrils within such a syncytium may pass continuously from the protoplasm of one cell into that of another.

Although cell membranes are often inconspicuous in animal cells, they cannot be overlooked in plants. Thus cork is a mass of dead cells from which nuclei and protoplasm have disappeared, leaving only the cell walls. In describing cork, Robert Hooke introduced the name "cell," in 1664. He wrote: "I took a good clear piece of Cork and with a Pen-knife sharpen'd as keen as a Razor, I cut a piece of it off, and thereby left the surface of it exceeding smooth, then examining it very diligently with a Microscope, me thought I could perceive it to appear a little porous. . . . These

pores, or cells, were not very deep, but consisted of a great many little Boxes ."

In this way one of the briefest and most important of scientific terms was introduced.

Cells are regarded as primarily spherical in form. Spherical cells are comparatively numerous in the embryo, and in the adult the resting white blood corpuscles, which float freely in the body fluids, assume this shape. Such cells are circular in cross section. When spherical cells are subjected to the pressure of similar neighboring cells, they become polyhedral and usually appear six-sided in cross section. Such cells, as a whole, may be cuboidal, columnar, or flat. Certain cells become fusiform (spindle-shaped) or are further elongated so as to form fibers; others send out radiating processes and are called stellate. Thus the form of cells is extremely varied. The shape of the nucleus tends to correspond with that of its cell. It is usually an elliptical body in elongated cells, and spherical in round or cuboidal cells. In stellate cells it is either spherical or somewhat elongated. Crescentic nuclei, and others more

The size of cells ranges from that of the yolks of birds' eggs which are single cells, at least shortly before being laid down to microscopic structures four thousandths of a millimeter in diameter. The thousandth of a millimeter is the unit employed in microscopic measurements. It is called a micron, and its symbol is the Greek letter /*. The small cells referred to are therefore four microns (4 ju) in diameter. The size of any structure in a section of human tissue may be roughly estimated by comparing its dimensions with the diameter of a red blood corpuscle found in the same section. These red corpuscles are quite uniformly 7.5 p. in diameter.

CYTOMORPHOSIS.

Cytomorphosis is a comprehensive term for the structural modifications which cells, or successive generations of cells, undergo from their origin to their final dissolution. 1 In the course of their transformation, cells divide repeatedly, but the new cells begin development where the parent cells left off. Cell division, therefore, is an unimportant incident in cytomorphosis.

Cytomorphosis is a continuous advance in which four successive stages are recognized first, the stage in which the cells are undifferentiated ;_ second, the stage of specialization or differentiation: third, the stage of degeneration; and fourth, the stage in which the cells die and are removed. These may be considered in turn.

Undifferentiated cells, as can be seen in sections of young embryos, are characterized by large nuclei and little protoplasm. They multiply rapidly, but the rate of division declines with the gradual increase of the protoplasm and the consequent functional differentiation of the cell. In the adult, relatively undifferentiated cells are found in many situations, as, for example, in the deepest layer of the epidermis. As the cells at the surface die and are cast off, new ones come up from below to take their places. But since the basal cells can produce only epidermal cells, they are themselves partly differentiated. From this point of view the fertilized ovum, which can produce all kinds of cells, must be regarded, in spite of its size and great mass of yolk-laden protoplasm, as the least differentiated cell.

Differentiated cells may preserve a round or cuboidal form, but usually they are elongated, flattened, or stellate. The cytoplasm usually contains coarse granules, fibrils, masses of secretion or other special forma 1 The term cytomorphosis was introduced by C. S. Minot in 1901 in a lecture entitled "The Embryological Basis of Pathology" (Science, 1901, vol. 13, p. 494). Cytomorphosis is further discussed by Professor Minot in "The Problem of Age, Growth, and Death," published by G. P. Putnam's Sons, 1908.

Although the differentiation of cells is chiefly cytoplasmic, there is some evidence of corresponding nuclear changes. Thus while the muscle

cells of the salamander are elaborating complex fibrils, the nuclei become modified as shown in Fig. 9. The significance of the nuclear changes is unknown.

Degeneration is the manifestation of the approaching death of the cell. In nerve cells this process normally takes place very slowly. These cells remain active throughout life, and if destroyed, they can never be replaced. In many glands, in the blood and in the skin, however, the cells are constantly dying and new ones are being differentiated. In a few organs the cells perish, but no new ones form, so that the organ to which they belong atrophies. Thus a large part of the mesonephros (Wolffian body) disappears during embryonic life; the thymus becomes vestigial in the

adult; and the ovary in later years loses its chief function through the degeneration of its cells.

The optical effects of degeneration cannot at present be properly classified. In a characteristic form, known as "cloudy swelling," the cell enlarges, becoming pale and opaque. In another form the cell shrinks and stains deeply, becoming either irregularly granular or homogeneous and hyaline. The nucleus may disappear as if in solution (karyolysis, chromatolysis) ; or it may become densely shrunken or pycnotic, and finally break into fragments and be scattered through the protoplasm (karyorhexis). If the process of degeneration is slow, the cell may divide by amitosis. It may be able to receive nutriment which it cannot assimilate, and thus

A, From a 7 mm. embryo; B, from one of 26 mm.; ch, chroma tin knot; g. s, ground substance; 1, linin fibril; n, nucleolus; n.m, nuclear membrane.

The removal of dead cells is accomplished in several ways. Those near the external or internal surfaces of the body are usually shed or desquamated, and such cells may be found in the saliva and urine. Those which are within the body may be dissolved by chemical action or devoured by phagocytes.

Every specimen of human tissue exhibits some phase of cytomorphosis. In some sections a series of cells may be observed from those but slightly differentiated, to those which are dead and in process of removal. Because of the similarity and possible identity of this normal "physiological" regression, with that found in diseased tissues, such specimens should be studied with particular care.

VITAL PHENOMENA.

The vital properties of cells are fully treated in text-books of physiology. They include the phenomena of irritability, metabolism, contractility, conductivity, and reproduction. Under irritability may be grouped the response of cells to stimuli of various sorts, such as heat, light, electricity, chemical reagents, the

' V, 1 2 2,

nervous impulse, or mechanical inter tt**^ f^'f-t *-!.$ gL A cm

ference. Metabolism, in a wide sense, ,yp> i^L %M.

^ ^Vj" ' ^"* WT&f~

includes the ingestion and assimilation of food, the elaboration and secretion of desirable products, together with the elimination of waste 3 "*

.!. t, FIG. 10. LEUCOCYTES OF A PROG. * au.

products. Contractility may be Changes in form observed during ten minutes;

r ,v i r 4.v,_ o, at the beginning of the observation;

manifest m the locomotion Of the J.a half minute later, etc.

entire cell, in the vibratile action of

slender hair-like processes, the cilia, or in contraction of the cell body. Conductivity is the power of conveying impulses from one part of the cell to another. Reproduction is seen in the process of cell division. Many phases of these activities are observed in microscopic sections and as such they will be referred to in later chapters. A few which are of general occurrence will be described presently.

The unicellular animal, Amoeba, exhibits a type of motility known as amoeboid, which has been observed in many sorts of cells in the verte

the process may terminate with the multiplication of nuclei. If carried to completion, the protoplasm also divides, and a cell membrane develops between the daughter nuclei. The role of the centrosome in amitosis has not been determined. Maximow finds it in a passive condition between the two halves of the nucleus, or beside the stalk connecting these halves if the division is not complete (Anat. Anz., 1908, vol. 33, p. 89). He states that certain mesenchymal cells which divide by amitosis in the rabbit embryo are not degenerating, but may later divide by mitosis, and thus he confirms Patterson's similar conclusion in regard to certain cells in the pigeon's egg. These instances are regarded as exceptional. In the human body the detachment of a portion of the lobate nucleus of certain leucocytes has been described as amitotic division, but the superficial cells of the bladder furnish more typical examples. E. F. Clark has found many cells dividing by amitosis hi the degenerating parts of a human cancer. The occurrence of two nuclei within one cell by no means indicates this form of division. Associated with such cells, others containing nuclei of the dumb-bell shape, or those partially bisected by clefts must be found, in order to prove that amitotic division is taking place.

Mitotic figures are found hi all rapidly growing tissues, but especially favorable for preliminary study are the large cells in the root tips of plants. In longitudinal sections of root tips, the cells are cut at right angles to the plane of cell division, which is desirable; and often in a single section 5 mm. long, all the fundamental stages may be quickly located. The following general description of mitosis is based upon such easily obtained preparations, and the plant selected is the spiderwort (Tradescantia virginiana). 1 They may be satisfactorily stained with saffranin, or with iron haematoxylin and a counter stain such as orange G. There are many descriptions of mitosis in root tips, among them the following:

Rosen, (Hyacinthus oriental/is) Beitr. zur Biol. der Pflanzen, 1895, vol. 7, pp. 225-312; Nemec, (Allium cepa} Sitz.-ber. kon. Ges. der Wiss. Prag, 1897, No. 33, pp. 25-26, and Jahrb. fur wiss. Bot., 1899, vol. 33, pp. 313-336; Schaffner, (Allium cepa) Bot. Gaz., 1898, vol. 26, pp. 225-238; Hof, (Ephedra major) Bot. Centralbl., 1898, vol. 76, pp. 63-69, 113-118, 166-171, 221-226; Gregoire and Wygaerts, (Trillium grandiflorum) La Cellule, 1904, vol. 21, pp. 1-76; Farmer and Shove, (Tradescentia mrginiana) Quart. Journ. Micr. Sci., 1905, vol. 48, pp. 559-569; Richards, (Podophyllum peltatum] Kansas Univ. Sci. Bull., 1909, vol. 5, p. 87-93.

The cells to be described are found in the interior of the root tip, just back of the protecting cap of cells which covers its extremity. They are oblong in shape and their long axis corresponds with that of the root. The walls are very distinct, and the cells consist of granular vacuolated protoplasm, which in preserved specimens is generally irregularly shrunken.

The resting cells (Fig. 12, A) contain large round nuclei in which the chromatin is in the form of fine granules evenly distributed throughout the nucleus. A nucleus usually contains from two to five round nucleoli, each of which, when in focus, is seen to be surrounded by a clear zone. The nuclear membrane is distinct.

1 Good specimens may be obtained from any rapidly growing root tip. Those starting from hyacinth bulbs placed in water are very favorable. Onion root tips have been extensively used, and also those of bean and corn seedlings. The pointed ends are snipped off and dropped into Flemming's stronger solution

In the stage shown in Fig. 12, D, which may be regarded as the end of the prophase, the nuclear membrane and the nucleoli have disappeared, and the spireme thread has become divided into a number of segments or chromosomes. These are straight or curved rods of different lengths. Sometimes they appear as bent V-shaped bodies, but these often represent two chromosomes with their ends together. J-shaped forms, with one long and one short arm, have been described in various plants. The chromosomes become so arranged that one end of the rods, or the apices of the V's, are situated in the equatorial plane, which extends transversely across the middle of the cell. Often it is temporarily tilted (as in D and E) as if the mitotic apparatus had shifted to a position in which it obtained more space. It may do this mechanically if the contents of the cell are under pressure. When the chromosomes are gathered at or in the equatorial plane, they constitute collectively the equatorial plate. Because of their stellate arrangement at this stage, which is best seen in transverse sections of the cell, this mitotic figure is known as the aster.

The manner in which the chromosomes are formed from the spireme thread is difficult to determine. According to Gregoire and Wygaerts, the linin and chromatin, which have often been regarded as closely related

At this stage an achromatic figure, known as the spindle, is evident in plant cells, but it is more sharply defined in those of animals. As seen in the diagram (Fig. 13), it consists of fibrils which pass from the equatoria

Polar radiation. Nuclear spindle.

Telophase. After the chromosomes have reached the opposite poles, they form two dense masses. They are generally said to unite end to end, thus forming a spireme thread. But in the root tips of Trillium, Gregoire and Wygaerts state that they come into contact with one another laterally; and as they separate, transverse connections are retained, which, with the vacuolization of the chromosomes, restore the nuclear reticulum. This may not be the correct interpretation, but immediately after the anaphase the chromosomes form a very compact mass, easily overstained so that it appears solid. Subsequently the mass enlarges (Fig. 12, H), and the chromosomes become coarsely granular, taking the form of wide bands. Nucleoli reappear, and according to Richards, "it is a general rule that they arise on the side of the nucleus nearest the new cell wall." This accords with Nemec's statement that they form from the outer fibers of the spindle. Nemec and Rosen agree that they first appear outside of the nucleus, which they enter before the nuclear membrane develops. These are details which require confirmation.

The new cell wall arises in plants as a series of thickenings of the interzonal spindle fibers, which at this stage form a barrel-shaped bundle (Fig. 12, G). The thickenings coalesce to form a membrane which does not at first reach the sides of the cell. While this wall is developing the nuclei are in a condition resembling the spireme stage of the prophase. The entire mitotic figure is therefore called the double spireme or dispireme. The cell wall is soon completed and the nuclei return to the resting condition (Fig. 12, I).

The time required for mitotic cell division varies from half an hour (in man) to five hours (in amphibia). After death, if the tissues are not

Number and individuality of the chromosomes. It is now generally believed that every species of plant or animal has a fixed and characteristic number of chromosomes, which regularly recurs in the division of all

As a result of mitotic cell division, it is evident that every new cell regularly receives one-half of each chromosome found in the parent cell, and thus the number of chromosomes remains constant. But in the germ cells the number is invariably reduced, and hi some animals it becomes exactly one-half of the number found elsewhere in the body. In such a case, when the male sexual cell, or spermatozoon, unites with the female sexual cell, or mature ovum, in the process of fertilization, the original number is restored. Each parent thus contributes one-half of the chromosomes found in the cell which gives rise to a new individual; and since each of these divides with every subsequent cell division, it is evident that one-half of the chromatin in every cell of the adult body is of maternal origin and one-half of paternal origin. The process by which the sexual cells acquire the reduced number of chromosomes and become ready for fertilization is known as maturation. The production of the sexual cells in the male is called spermatogenesis and in the female ob'genesis.

shape of the abdomen. In males it is more rounded (Fig. 16)