In recent times, along with an increase of knowledge on internal secretion, it has been imagined by many authors that in the placenta and the decidua there should exist such a function. According to the literature which I know, Lettule and Larrier (’01) are those whose attention was first drawn to this subject. They detected in the syncytium layer a kind of granular body termed ‘Plasmoidale Kugeln.’ This body they took to be a secretion of the placenta. Subsequently, Veit (’O2) attempted to trace the cause of eclampsia, and Behm (’03) the cause of morning—sickness to the function of the syncytium,

some placental preparations. Further, Halban, supported by his plentiful clinical observations, stated that the swelling of the nipples noticeable in a newborn child, the congestion and hyperplasy of the uterus, the hypertrophy of the mammary glands of a pregnant mother, and hypertrichosis are all probably due to his so-called ‘Reizstoff,’ which is thought to be a product of the placenta. Among other things, it seemed he tried to deduce the existence of the closest functionary correlation between the placenta and the mammary glands. Since the result of Ha1ban’s studies was published, the functions of internal secretions likely to exist in the placenta drew general attention, and thereafter studies of this subject followed quickly one after the other. In the present essay I have refrained from chronologically relating all the results of these researches, but instead, with a view to giving only a general idea of what is known about this subject at present, I have confined myself to the summing up of" all the points of the investigations made by the various authors up to now, and to dividing them intoa few large sections along the lines of experimentation, biological chemistry, and histology. ‘

Now, in the early experimental investigations, it was the first attempt of the various authors to investigate chiefly the effect which the placenta has upon the mammary glands, and the methods employed were either to inject into the animal used as the subject of the experiment an extract of the placenta or to transplant the placenta, and the results in either case were for the most part positive (Feller, ’09; Lederer and ’Pribram, ’10; Aschner and Grigoriu, ’11; Cristea and Aschner, ’12; Basch, ’12; G. Kawaida, ’12; M. Dohi, ’l6). However, as it was incidentally discovered at the same time that the placenta had shown_ some strong special reaction upon the other organs, e.g., the Vascular organs (Schickele/12), the internal secretory glands (Fellner, ’13; Colle, ’13), and the uterus (Fellner, ’09; Okintschitz, ’14; Hermann, ’15), it naturally became difficult to assert that the ingredients of the placenta have such properties as react upon the mammary glands alone. And, further, as it became known generally that such changes in the mammary glands as mentioned above were not only due to pregnancy or the placental ingredients, but were also caused by extracts of the various organs, such as the embryo (Mandle, ’05; Bayliss and Starling, ’06; Foa, ’10; Biedl and Konigstein, ’ 10 ; Aschner and Grigoriu, ’10), the ovary (Ott and Scott, ’10,' Aschner and Grigoriu, ’11; Frank and Unger, ’11; Hermann,’ 15; Y. Taniguchi, ’16), the pituitary body (Hofstatter, ’11), the pineal and thyreoid glands (Ott and Scott, ’1l),the uterus while in childbed and the mammary glands which are giving suck (Schoefer and Mackenzie, ’11), the intestines, the testicles, the spleen, and the thymus (Kehrer, ’15), the decidua (Gentili and Binaghi, ’17), as well as by a certain kind of chemical matter, such as ‘Lymphagoga’ (Aschner and Grigoriu), and albumin, too (Frank and Unger, ’11; Fraenkel, ’14), the theory of internal secretion in the placenta which had begun to be adopted generally for a time began to lose its value by degrees.

In the next place, along lines of biological chemistry, there are the researches made by such authors as Higuchi (’09), Hermann (’15), and Harada (’16). These authors extracted from the placenta various kinds of chemical matter as its principal ingredients and subjected them to close examination, but they never mentioned a ‘hormone,’ which is always existent in the placenta.

Thirdly, with regard to the histological studies of the placenta, many researches have been made in the subject from earlier times, but a great majority of these researches were confined to the development or general construction of the placenta, and very few authors have given any special consideration to the internal secretion of this organ nor have they closely examined the minute construction of the tissue elements or cells of the

placenta, Already Ahlfeld (’78) had noted the appearance of‘ -vacuoles in the syncytium layer, and subsequently many authors

recognized it; however, regarding the thing itself and its physiological significance, nothing definite has yet been stated. Gottschalk (’90) deemed it a pathological product; Kossrnan (’92) took it for a kind of degeneration, while Langhans C92) interpreted it as ‘Leichenerscheinung. ’ Further, regarding the globules of fat in the same layer, demonstrations had already been made by Pela-Leusden (’97) and Marschand (’98). Bonnet (’99) deemed it a nutritious matter taken up by the embryo, and in recent times authors have generally agreed in recognizing it as nutritious matter of the embryo taken from the mother’s blood. Others, among them Halfbauer CO5), Costa C04 and ’O5), and Bondi (’11), inferred that the appearance of this matter must be due to the active functions of the cells, by which it is assimilated and absorbed. On the other hand, however, Wolff (’13), as per Letulle and Larrier as mentioned above, on comparing the granular body of the syncytium layer with the secretory grains Within the ordinary gland—cells, stated that both of them were a similar production. This theory was subsequently supported by Fraenkel, who was close to the deduction that there might be existent a certain secretory relation in the granular body of the syncytium layer. ,In short, the histological studies of this subject up to now have been confined, as mentioned above, to the construction and, consequently, the functions of the syncytium layer only, and there are even many defects in the studies and some resultant weakness in the point of the arguments, and no one can say that the opinions agree. Although there are some authors who recognized the internal secretory functions of the placenta, yet, sinceitheir arguments are based on a single part of the organ, viz., the syncytium layer, it must be stated that on the whole the basis of histological arguments for internal secretion in the placenta is very feeble indeed, and much more is still to be done to accomplish a consummate investigation of this subject. It should none the less be added that Fraenkel (’14) was one of those who were strongly opposed to the various theories given above, and he denied the effects, which, it was believed, the placental functions have upon the mammary glands, on the ground that exactly the same phenomenon as takes place in the suckling of mammals was observed in the suckling of Monotremata and Marsupialia, neither of which has the placental formation. In addition to that, Fraenkel, going so far as to discuss the‘ changes which the internal secretory glands and other organs have to undergo in consequence of the placental extract as was witnessed in the experimentations of the afore-mentioned authors, concluded that such changes were attributable to several ingredients, his so-called ‘Gift,’ contained in the extract. According to Fraenkel, who contradicted the theory which generally is in favor of the existence of internal secretion in the placenta, the internal secretory glands first respond to this ‘Gift,’ and, as a result, the other physical changes follow. In short, it may be said with regard to the existence of internal secretion in the placenta that, in spite of the numerous researches made along the lines of experimentation, biological chemistry, and histology, as I have mentioned above, the Views expressed are so varied that no conclusionhas been reached, and, therefore, regarding the real situation of this subject, it is at present not yet an established theory. M Many authors have given their attention to the existence of an. internal secretory function in the decidua, and have tried to demonstrate it, Starling (’06), Sfameni, Gentili (’13 and ’ 14), Schottlander (’14), Aschheim (’15), Gentili and Binaghi (’17) being among the number. Starling conducted experiments on the rabbit to find the effects which the juice extracted from the mucous membrane of the uterus While in pregnancy exerts upon the mammary glands, and the result was of a negative nature. Sfameni for many years past had held that in the decidual cells -there should be existent an internal secretory function, the basis of his arguments being the striking resemblance from the view—point of morphology, between the decidual cells and those of the other internal secretory glands. In order to demonstrate this, Gentili, in the same laboratory as Sfameni, carried out experiments by the use of ' the decidual juice on the dog, the rabbit, and the frog, and it was found that, similar to the luteal cells of the ovary, the decidual cells have a special action upon both the circulatory and generative organs. Schottlander also, by assuming that it may be possible for the secretion of the glandular cells in the spongious layer of the decidua in the first month of pregnancy perhaps to enter the mother’s blood directly, recognized seemingly that the uterine glands at times have the significance of an internal secretory gland. Aschheim, in 1915, by discovering plenty of lipoid in the decidual cells, imagined the existence of a special function in these cells. Lastly, Gentili and Binaghi, by conducting a Inicrochemical experiment on the various tissue elements which form the decidua of a cow, demonstrated the existence of a kind of lipoid in the tissues, as reflexive of the correlation which it seems they believed existing between a certain function, particularly an internal secretion of the decidual cells, and the lipoid. On a close examination of the result of researches made by these authors, it must be stated that even in those whose view was in favor of an internal secretion in the decidua the basis of arguments presented is in general as feeble as in the case of an internal secretion of the placenta.

It is a long time since I began to feel interested in the secretory function of the placenta and the decidua. I was ever of the opinion that both the placenta and the decidua have a certain secretory function, and the experimental method I adopted in investigating this subject was entirely different from that employed by the foregoing authors. That is to say, I conducted a serological research into the effects which the alchoholic extract of the placenta and the decidua has upon the mother’s blood, and the result was the discovery in the serum during pregnancy of, not only the well-known Abderhalden’s ‘Abbauferment,’ but also of such an antibody as has a property of the fixation of complement- with ingredients of the extract referred to. And, as in ordinary cases, the'antigen which represents the phenomenon of fixation of complement is either a proteid‘ or some such like matter, whereas in my case it is a substance which is soluble in alcohol, the latter must be deemed to be qualitatively different from the former. It makes me feel as if it were in order for me to presume that the antigens in my case are due to the lipoid substances which are peculiar to (having some relation with the secretory process of) both the placenta and the decidua. Accordingly I have become convinced that, in spite of the various authors whose arguments I have enumerated above as denying the existence of an internal secretory function in both the organs concerned, the fact must be the reverse. Needless to say, however, this argument is only along lines of reasoning, and, therefore, it must be stated that the reason why I have applied at this juncture the modern cytological methods, thus planning out a close histological investigation of the principal tissues and cells, particularly the cell bodies of the placenta and the decidua, was because I was anxious to decide more clearly the right or wrong of this hypothesis. I have also, by adopting the same methods, examined the minute structure of the principal cells as indicative of the change which the uterine mucous membrane undergoes prior to menstruation, which, being compared with that during pregnancy, has enabled me to arrive at a certain conclusion, as will be noted later, respecting the physiological significance of the menstrual changes of the uterine mucous membrane.

The materials for research were taken from a total of fortythree cases, of which twenty-five had to undergo artificial interruption during the first half of pregnancy because of the following diseases: 6 cases of morning—sickness of high degree, 12 cases of phthisis, 2 cases of laryngeal tuberculosis, 1 case each of consumption of the bowels, of peritoneal tuberculosis, and of a valvular disease of the heart, 2 cases of glucosuria.

Of the remaining 18 cases, 14 had to undergo artificial interruption during the second half of pregnancy because of the following diseases: 1 case of beriberi, 5 cases of nephritis, 2 cases of a valvular disease of the. heart, 1 case of albuminuric retinitis, 3 cases of eclampsia, 2 cases of placenta praevia.

And the remaining 4 cases had to receive a Porro’s operation because of the following diseases: 1 case of mislaid transverse position and 3 cases of the narrow pelvis.

And as to the time of pregnancy in these 43 cases, it should be noted that 4 cases were less than 1 month, 2 cases 1 month, 4 cases 2 months, 7 cases 3 months, 6 cases _4 months, 3 cases 5 months, 4 cases 6 months, 3 cases 7 months, 3 cases 8 months,

4 cases 9 months, and 3 cases 10 months. And difiicult as it was to accurately determine the exact time of pregnancy in each case, the method I adopted in determining those less than one month was to take into account the size of the egg and the degree of development of the embryo and villi, and in those one month and upward, to consider the time of menstruation, the size of the uterus, the length and weight of the embryo, the length of the navel string, and the weight of the placenta, thus arriving at the approximate time of pregnancy.

As regards the obtaining of the materials from the fetal placenta, it should be noted that in the early stage of pregnancy a few pieces of ordinary villi from the surface of the ovum were taken, while in a little more advanced a few small cuts of the chorion frondosum, and in a well-formed stage of the placenta a few small bits of the latter have been cut out. Now, as to the maternal part of the placenta, a part was taken from placenta already delivered and from that not grown up yet, in the former case, from the surface opposite the uterus of the placenta, and in the latter, the mucous membrane of the uterus concerned being scratched off quickly,ras during an operation it is quite easy for the operator to determine the insertion of the placenta. The tissues obtained in this Way have always shown“ microscopically, besides the proper decidual tissue, the existence in them of parts of villi, syncytium cells, and the deposit of fibrinoid material (‘kanalisiertes Fibrin’ ofl Langhans), all of which were proof that they were the materials I desired. In this connection it must be added that the decidual materials were always taken from the decidua Vera only, at every stage of pregnancy, by means of scratching out. All these pieces of tissues were so taken that they should not exceed a cube 3 mm. in size, and immediately after cutting they were dipped in the newly prepared fixing solutions. For the latter I have ‘used: 1, Altmann’s fluid of potassium bichromate and osmium tetroxide; 2, Flemming’s solution modified by Benda; 3, F1emming’s solution modified by Meves; 4, Levi’s mixture of formol, osmic acid, potassium bichromate, and corosive sublimate; 5, Luna’s mixture of formal, potassium bichromate, and glacial acetic acid. Each of the pieces was then treated in the usual manner being imbedded in parafiin and cut in sections of 3 to 4 pt. And as a treatment prior to staining, Rubaschkin’s method has been applied in a great majority of cases. For staining I have employed: 1, Altmann’s method of acid fuchsin and picric acid; 2, Heidenhain’s iron-alumhaematoxylin, and, 3, Benda’s alizarin—crystal-violet method, etc. All the methods which I have adopted, the fixation with Levi’s mixture, and the staining with iron—alum-haematoxylin have been found to be comparatively successful.

The chorionic villi, which are a, main component of the placenta’ consist of: 1) the syncytium cell-layer; 2) the Langhans’ cells’ and, 3) the ‘Stromazellen,’ being cells in the stroma of villi» while the components of the decidua serotina and the decidua Vera chiefly consist of, 4) the decidual cells and, 5) the epithelium of the uterine gland. In the present chapter I intend to give a detailed account, mainly from the histological standpoint, of these important tissue components, or cell groups, especially as they appear in the different stages of pregnancy. However, since the structure of all kinds of cells varies even in the same stage of pregnancy and in the same group of cells, it would be a difficult task indeed to explain clearly the correlations existing between the minute structural changes of these cells, or cellular groups, and their functional significance. Therefore, I have selected and drawn those deemed the most representative of all the structural images of the afore-mentioned tissue-cells which have been widely and thoroughly examined, as will be seen from the series of figures on the plates the object being to give a general idea of the structural changes of these cells. The explanations of each of these figures will make the pith of this chapter, as by so doing I believe the description could be much simplified and its understanding facilitated as much as possible. Thus, I " shall appreciate very much if the reader will constantly refer to those figures While reading.

As is well known, the syncytium layer is the epithelium which covers the surface of the villi, and the lack of boundaries between the cells is a feature of this layer. And it is also well known that within this layer there are several kinds of nuclei, differing in size and form and scattered here and there, besides dark-colored granular bodies and a great number of vacuoles which occasionally appeared in it. Its surface is covered with a brush—like border. This layer is generally well developed in the early stages of pregnancy, but in the second half of pregnancy it becomes thinner and looks much like an endothelium, so that, when examining its minute structure, it will be necessary to do so before the fourth month of pregnancy. Figure 1 shows that part of the anchoring villi which extends deeply into the decidua, while all the other plates show the different parts of the surface of the ordinary villi.

In figure_ 1 the syncytium presents a homogeneous protoplasmic layer generally dark-colored and contains an extremely large quantity of plastosomes (mitochondria). They are of different shapes, but mostly are rod-shaped or bacteroid and of different lengths, the longer ones being slightly curved. They arrange themselves in groups rather than being equally distributed over the layer, and in some places some of them point in the same direction, while others point in Various directions, thus in general‘ giving ‘them something of a meshy arrangement. The nuclei are clear and have in themselves a more or less conspicuous nuclear network, with one or two nucleoli.

In figure 2 the syncytium layer closely resembles figure 1 in structure, though the plastosomes contained therein differ from one another in their shape, arrangement, and number. These two figures show the simplest structure of the syncytium layer.

In figure 3 the plastosomes are generally faint and quite scattered; in the protoplasm there are some dark-colored granular bodies of different sizes and a small number of vacuoles; the smaller granules are somewhat dark in color and are generally found very near the surface, viz., the brush-like border, whereas the larger ones are light-colored and are found in other parts of the layer. The vacuoles are found close to the Langhans’ layer. The nuclei are irregular in shape, and besides the nuclear network there are one or two nuceoli.

In figure 4 the plastosomes are generally found in the deeper layer, i.e., close to the Langhans’ layer, and they are comparatively small in number. On’ the contrary, however, plenty of dark or yellowish dark—colored granules occur conspicuously all over the layer, the deeper colored ones being generally superficial. Undoubtedly, granular bodies of this kind have grown up from the dark-colored granules in a conspicuous manner such as I have shown in figure 3 above, and they are very frequently met with elsewhere in the other parts of the syncytium layer. And, moreover, granular bodies of a similar kind are found, as will be seen in the following statement, not only in the syncytium layer, but also commonly in other cell groups. These granular bodies are, of course, extremely varied in their size, quantity, and color; however, .since they have a common aflinity to certain chemical and coloring matter, e.g. osmic acid, iron-alum-haernatoxylin, and acid fuchsin, etc., I have followed, for the sake of brevity, the precedents of many histologists in including all these granular bodies under the name of ‘lipoid’ granules. In this figure there is, moreover, only one vacuole close to the brush-like border. The nuclei are less conspicuous in their network, the chromatin forming itself into a large number of lumps, each of nearly equal size.

In figure 5 there are no plastosomes to be found, but the lipoid granules occur in extremely large quantities, and their sizes are nearly the same. They are found more or less in groups and are distributed all over the layer. At the same time the vacuoles make their appearance in a conspicuous manner, sometimes on the surface, sometimes in the innermost part, and sometimes in the middle, and they are about the same size as the lipoid granules. As is well known, it is in general very difficult to stain the plastosomes every time, and, therefore, accurately to determine their existence and where they are entirely wanting, as in this figure, it would be a very difficult task indeed. I have paid the closest attention to this, and have always selected for it the most excellent preparations for staining, with a View of doing away with all the possible defects in the technique of staining. From the existence, in a very conspicuous manner, of plastosomes in the neighboring tissues, entirely in contrast to this figure, I was prompted to conclude that it was well nigh necessary for me to assert the absolute lack of plastosomes in this part of the syncytium layer. Further, I may add that, as will be noted below, the same amount of attention has been given all the other cells where there are no plastosomes to be found, and I, on this score, am convinced that my observations concerning them are not erroneous.

In figure 6, the surface is somewhat light-colored and is clear. In it there are found innumerable quantities of vacuoles which are nearly of the same size, besides a small number of Iipoid granules. The innermost part, however, is of a comparatively dark color, and it likewise contains innumerable quantities of minor lipoid granules of about the same size, with very few vacuoles which are generally of small size. Some of the nuclei are oval, while others are irregular in their shape, and there is to be found a great number of chromatin granules which make their appearance in lumps of different sizes; the nuclear networks are usually less conspicuous. There are absolutely no plastosomes to be found.

In figure 7 the syncytium layer is extremely thick, and it is difficult to demonstrate the plastosomes. Lipoid granules of extremely varied sizes are found in large quantities. These granules are irregularly arranged, and they tend more or less to occur in groups; certain lipoid granules make their appearance as contents of vacuoles, in which case the granules always have a clear halo around them, as if they constituted the nucleus of the vacuoles. Such images are frequently met with not only in the syncytium layer, but also in other cell groups and, since theylare worth recognizing as very clearly indicating the relations which exist between the lipoid granules and the formation of vacuoles, the reader’s special attention is hereby drawn to this point (vide the left-hand side of this figure). The vacuoles are abundant, and their sizes and shapes are quite irregular and, as will be seen in the middle part of this figure, a great number of them are joined together at some places without boundaries being noticeable between them. From the existence of such images I am led to infer that an extraordinarily large vacuole is in general the outcome of minor vacuoles being agglutinated and joined to one another. In this Way, it seems that the vacuoles which have grown up into tremendous sizes finally rupture toward the surface, as it will be seen in the present figure that such vacuoles open up and connect directly with the intervillous spaces, clearly supporting the interpretation that I

have given above. In figure 8, it is in general extremely deficient in its character istic dark-colored protoplasm, but then there are all over the layer numberless vacuoles of a very small size, which grow so close to one another that they have exactly the appearance of a beehive. Of these vacuoles some of the larger ones lie together close to the surface, while others, connected with one another,. mutually find their outlets to the surface through comparatively large openings. Because of these openings the surface of the syncytium layer, which is naturally level, becomes very uneven and irregular. The lipoid granules are very few, and no plastosomes are to be found. The nuclei are not only few, but being shrunken are changed into homogeneous bodies of small size, the nucleoli alone making a prominent appearance (vide the right-hand side of the figure).

In figure 9 the syncytium layer is comparatively thin, and there are comparatively few plastosomes to be found, being scattered here and there, and mostly rod-shaped. The lipoid granules'are middle-sized and are not many in number, and a few of them stay at the center of the vacuoles as if they were the nuclei of the vacuoles. The vacuoles are pretty large, and they arrange themselves close to the Langhans’ cells. The nuclei have distinct borders and masses of chromatin arrange themselves in rows, usually close to the nuclear membrane.

In figure 10 the protoplasm is, as in a majority of cases, generally dark-colored, though not homogeneous altogether and, on a close examination, it is found that it contains a great number of vacuoles, which gives the protoplasm more or less a foamy appearance, though very indistinct as compared with other foamy structures. The plastosomes are mostly rod—shaped and are very distinctly stained. They appear generally in the upper layer, though some are noticeable in the innermost layer. There are no lipoid granules to be found and no nuclei of normal conditions are to be met with, but, on the contrary, there are some curious bodies, whose size is somewhat larger than the ordinary nuclei and which are irregular in shape. Some of them are homogeneous and are quite dark-colored, while others being non-homogeneous consist of different parts which are either dark or light or somewhat clear when stained. We come across such structures very often_in other parts of the syncytium layer, but so far I have not been able to find out their original nature.

In figure 11 the protoplasm shows numberless vacuoles as its constituents. The vacuoles are somewhat varied in their size, and with the exception of some which are full and stained, a greater portion of them, particularly those which are found on the surface, are more or less loose and somewhat flattened in shape. Between these vacuoles there are extremely large quantities of plastosomes, which are mostly rod— or granula shaped and equally deep—colored as these which are found in figure 10. There are few lipoid granules to be found, and they exist for the most part in the superficial layer, scattered here and there. What is especially worth noting is that there are red blood corpuscles in the protoplasm between these vacuoles (vide the left—hand side of the figure). The nuclei are oval-shaped, and the chromatin is very peculiarly arranged, its outward appearance resembling the shape of a chrysanthemum. In the center there is a nucleolus, and it must be noted that a nuclear condition of this kind is generally very rare.

In figure 12 the protoplasm is glutted with numberless vacuoles, andit is for this reason remarkably foamy in appearance. The vacuoles are of two sizes, of which the smaller ones are mostly located in the deeper portion and make a somewhat continuous layer, though in other parts there are to be found some of these smaller-sized vacuoles also. The larger vacuoles are crowded together in the middle part of the layer, and some of them burst forth onto the surface, While others make their appearance in the innermost layer close to the Langhans’ cells. The plastosomes are quite uniform in shape with those illustrated in the preceding figure, and they are all found in the protoplasm between the vacuoles. The lipoid granules are nearly of the same size and are found at several places, some of them with the halos distinctly described. The nuclei appear to be somewhat smaller in size, but there are no remarkable change in their structure. . . These structural conditions in the syncytium layer which I have illustrated and described ‘above can be detected at almost any time and place at the different periods from the first month of pregnancy to nearly the fourth, and, therefore, there is no doubt that these structural changes cannot be taken as a measure to tell the precise time of pregnancy. At no time after the fourth month of pregnancy can we detect the plastosomes. The lipoid granules and vacuoles reach their maximum growth from the second to third month of pregnancy, and after the fourth month they gradually begin to decrease, entirely disappearing after the seventh month. The syncytium layer comes in sight a remarkable manner on the seventeenth or eighteenth day after pregnancy, reaches the maximum of growth at the end of the first month, and from the second to the third month it seems, although not very conspicuously, more or less reduced in thickness, but after the fourth month it suddenly becomes thinner, and simultaneously its structure becomes simplified, and in the seventh month it will altogether atrophy and remain simply in the form of a thin membrane like an endothelium. Moreover, in the last two months the layer will disappear in some places and will be noticeable only as a discontinuous thin cover. In other words, this layer, excepting in the early stage of pregnancy, always decays and goes out of existence in inverse proportion to the growth of the embryo, and this is the very point which should engage the careful consideration of those who are interested in the functions of this layer.

The Langhans’ cells have in general distinctly clear bodies, and are distinctly bordered with a thin membrane (pericula?) on the surface. Their sizes, shapes, and structures are extremely varied; on examination of the smallest cells (figs. 13 to 16 and 7, 8 and 10) it will be found that they are either round like a ball or oval-shaped, with foamy nuclei of corresponding shapes inside. The structures of the cell bodies consist of quite structureless stroma and a large quantity of plastosomes, of which the latter are rod-shaped in several lengths, and are usually distributed all over the cells, though sometimes they crowd together on one side of the cells. There is occasionally a small ovalshaped body somewhat dark in color close to one side of the nucleus, which might possibly belong to Meves’ so-called ‘Centrotheca;’ it, however, lacks a centriole within (fig. 13). Within the nuclei there are generally one or two conspicuous nucleoli, and in most of the cases it is difficult _to discern the nuclear network. In the large sized cell bodies (figs. 17 to 19 and 2, 3, 9, 11 and 12) we always find either a small quantity of lipoid granules or vacuoles. The lipoid granules are nearly the same in size, and, though small in number, they are scattered everywhere (figs. 17 and 11). The vacuoles are extremely varied in their size, quantity, and arrangement, and it is for this reason that the structures of the cell bodies have so many special features (figs. 18, 2, 3, and9). In such vacuolar cells the rod-shaped plastosomes are for the most part short in length, and they are arranged either along the walls of the vacuoles or crowded together in the protoplasm between the vacuoles; however, sometimes it will be found that, as will be seen in figure 18, the vacuoles are chiefly placed in order on the outskirts of the cells, and the plastosomes accumulate in the center around the nucleus. Again, it will be found that, as in figures 19 and 12, both the lipoid granules and vacuoles of various sizes are simultaneously contained in the cellbodies, in which case the plastosomes are comparatively small in number and are scattered here and there in the protoplasm between the lipoid granules and vacuoles.

In the largest cells (figs. 20 and 21) the cell bodies are in general well filled with a great number of vacuoles of various sizes, and consequently the protoplasm is noticeable only around the nucleus and between the vacuoles. There are almost no lipoid granules, which, when present, are small and are very few in number; also the plastosomes decrease in quantity and are mostly found around the nucleus.

In short, the smaller-sized cells have in general only the plastosomes as their material components, while the largersized ones still contain a number of lipoid granules and vacuoles and in the largest ones the cell bodies are commonly vacuolated in a high degree and the protoplasm decreases considerably in quantity, the plastosomes in general gradually decreasing in number as the cells grow in size, though -it sometimes happens that it is very difficult to demonstrate them, regardless of the size of the cell bodies. Of figures 22 to 26 it will be observed that figure 22 shows the lipoid granules only, figure 23 chiefly the small vacuoles and a few lipoid granules; in figure 24 it is entirely the same as the former, however, with the distinctive feature that the vacuoles are remarkably large and have lipoid granules of various sizes within; in figure 25 and 26 the bodies are vacuolated to the highest degree, and it is perfectly plain that the vacuoles which are extremely varied in size and shape mix together and grow larger, thus giving the cell bodies the appearance of a honey comb in a striking manner. The large and highly vacuolated cells such as are-illustrated in figures 21, 25, and 26 are very frequently met with in the Langhans’ islets.

The various structural images in the Langhans’ cells that I have_ described above make their appearance in a most remarkable manner from the end of the first month of pregnancy to the end of the third month ,and in the fourth month, though the plastosomes are still existent in a remarkable degree, the lipoid granules and vacuolar formations are no linger conspicuous, and in the‘ following months not only do the cells decrease suddenly, but also these materials component of the cell bodies disappear, though the cells in the Langhans’ islets retain those structures as long as they exist.

The smallest of the stroma cells of villi, as is illustrated by figure 27, are mostly ball—shaped and have the nucleus of a similar shape within. In the cell bodies there are plastosomes, mostly rod-shaped. Figures 28 and 29 are nearly the same as figure 27 in their shape, though the one contains in the cell body a somewhat large quantity of lipoid granules of different sizes, while the other has a small quantity of extremely small lipoid granules and an equally small quantity of small vacuoles. Figures 30 to 38 illustrate the cells arranged in their approximate order of size and, though their shape and structure appear extremely varied at a glance, it will be ‘found on close examination that, with the exception of figure 34, there is a structure which is common to nearly all the rest, the only difference between them being principally the size and number of vacuoles contained in the cell bodies. Generally speaking, the larger sized-cells have vacuoles which are naturally large in size and number, and the fact that large vacuoles are built up to some extent from the fusion of the smaller vacuoles which are connected with one another can be often proved in these stroma cells (fig. 38). The plastosomes are mostly rod-shaped and lie scattered in the protoplasm located between the vacuoles, though they sometimes crowd together in a somewhat larger number in certain places (figs. 31, 32, 36, and 38). The lipoid granules are generally few in number and are found between the vacuoles, though at times they are present‘ within the small vacuoles (fig. 36). The smallest of these lipoid granules, at a glance, bears a close resemblance to the granular plastosomes; however, since they are mostly very distinctly bordered, besides being stained darker, it is easy to distinguish them from the former (figs. 36, 37, and 31). Figure 34 looks somewhat different from the various cells described above in that the cell is nearly spherical, with a remarkably large nucleus within, besides a small number of somewhat large vacuoles and plenty of lipoid granules in the cell body. These granules have Various sizes, but are in general of middle size and a few of them are distinctly included in the vacuoles. The plastosomes are extremely limited in number, and lie scattered in the protoplasm between the vacuoles. It is very seldom that this kind of cells makes its appearance, and a great majority of cells in the stroma, as are chiefly illustrated by figures 35 to 38, present a distinct vacuolar formation.

The plastosomes in the stroma cells have in general a very strong staining power, and are therefore more easily detected than other cell groups. It is, moreover, very rare that the cells which have no plastosomes are met with, but in stroma cells the lipoid granules seldom appear. The stroma cells appear distinctly and are therefore most easily found during the period from the second to sixth or seventh month of pregnancy. In the eighth month, usually, numberless capillary blood vessels suddenly grow and increase within the villi, so that it is impossible to examine the cells. With every possible method it was difficult to detect the cells, and, therefore, I am inclined to believe that the stroma cells suddenly cease to exist at this stage of pregnancy.

It is a generally well-known fact that decidual cells are divided into very many kinds according to shape, size, staining properties, and structure; however, it has not as yet been definitely decided whether or not these kinds of cells should be reckoned as one and the same sort. Marschand (’04) first divided the decidual cells into two types according to the difference in size. Subsequently, Fraenkel (’14), too, who studied them chiefly from the staining standpoint, set up a similar theory, and tried to divide them into his so-called acid cells (Eckersche Form) and the neutral cells (of large type); however, he himself and others had no doubt that there was not only no distinct division between these two kinds of cells, but rather there was existent an intermediate type of cells between them.

Figures 39 to 69 illustrate the Various kinds of decidual cells placed in order. Of these, cells such as in figure 39 are the smallest and are spherical with a nucleus of a corresponding form. The protoplasm is, as compared with the interstitial cells at the time of non-pregnancy, remarkably large in quantity, and contains in it a' large number of rod-shaped plastosomes. Figures 40 and 41 are a little bit larger than the former, and the one is spherical while the other is oval, both having a nucleus of nearly corresponding shapes. The protoplasm becomes still more abundant and the plastosomes are somewhat longer rods. It is worth our noting that both cells have a kind of boraer membrane already on the superficial layer of the cell bodies. Figure 42 demonstrates the first appearance of a few lipoid granules of various sizes within the cell bodies. Figure 43 illustrates a pear-shaped cell, which holds in the body a somewhat large quantity of granules and a few vacuoles. A few plastosomes are to be found, and they make their appearance only on one side of the cell. Figure 44 resembles the former in shape somewhat, and contains in the cell body remarkably large lipoid granules, which, on a close examination, are found to have a more or less distinctly clear halo around each of them, as though they constituted the contents of vacuoles. The plastosomes are mostly rod-shaped, and they crowd together on one side of the nucleus, while on the other they appear in a remarkably long, granular string (Fadenkorner). In figures 45 to 48 the cells have exceedingly Varied shapes, and the nucleus trends toward one side of the cell close to its superficial layer. The cell bodies are filled with numerous irregular-sized vacuoles, which present a more or less distinct foamy structure. The plastosomcs are mostly short and rod-shaped and they are to be found in the proplotasm between the vacuoles. Some of them are arranged in a long row along the walls of the vacuoles, While others are found in groups in a certain section. The lipoid granules are, in general, small in number, and their sizes are irregular, some of them finding themselves distinctly at the center of the vacuoles (e.g., fig. 46). '

In the various cells described above it will be observed that the nuclei are generally dark—colored, with indistinct nuclear network in most of the cases, though the nucleoli contained are conspicuous enough. Figure 49 is extremely different in its appearance from these cells. The cell body presents a vacuolar formation in high degree and the protoplasm proper can be demonstrated in a small amount only along the surface of the nucleus, at which place only a few rod-shaped plastosomes are found. The border membrane on the surface of the cell is very distinct and the nucleus is different from that in the various cells described previously in that it is clear and presents a large foamy body. The nuclear network is somewhat distinct, and, besides, there are conspicuous nucleoli. It must be generally stated that this kind of cell appears very seldom. In figure 50 the cell body presents an equally high vacuolar formation as in the former, and, in addition to that, the vacuolar walls entirely disappear in some places and so allow the inner spaces of the vacuoles to communicate with one another, thus clearly indicating the evidence of the vacuoles having been agglutinated. A few more plastosomes than in the former are found in groups in these cells, and, besides, there is a small quantity of lipoid granules, mostly within the vacuoles. What is especially peculiar about this cell is that at the center of the cell body there appears a black colored homogeneous star-shaped lump, from the surface of which are shot forth a number of processes, which run over directly to the protoplasm between the vacuoles. The proper nucleus is hardly detected. In figure 51 the cell is longish, and the overabundance of plastosomes which are distributed densely almost all over the cell body is the feature of this cell. Between there, is a somewhat large number of vacuoles of various sizes, and no lipoid granules at all are to ‘be found.

In figures 52 to 54 thevarious cells illustrated are gradually larger than those described above, the cell bodies are filled with a large number of vacuoles and granules. The latter are extremely irregular in size and density and are sometimes found as contents of the former. The plastosomes are mostly short rods, and especially in figure 52 they are somewhat abundant, and some are found massed along one side of the nucleus. In figures 53 and 54 they are comparatively fewer and lie scattered between the vacuoles. The thin layer on the surface of the cell is thicker and more distinct in this kind of cell, to such an extent that it almost reminds us of the ordinary cell membrane. In figure 53, as in figure 50, we notice a black—colored round—shaped lump at the location of the nucleus; however, in this case, the surface of the lump is smooth and has no process. Comparatively few cells have such a black—colored lump, and, as in these cells it is always difficult to tell the whereabouts of a nucleus of normal condition, I am quite at a loss to know whether or not the dark lump described above should be deemed a modification of the nucleus or regarded as that part of the protoplasm which is just adjacent to the nucleus which has, by reason of its staining properties, obscured the nucleus. This question, along with the stained lumps in the syncytium layer as illustrated in figure 10, constitutes a puzzle, and I have mentioned it here for the sake of future investigations. However, in View of the fact that numerous plastosomes, which are the important elements of a living cell, are always demonstrated in the cells concerned, while at the same time they present no noticeable regressive phenomena. I am rather inclined to believe that it is possible to attribute a certain functional significance to these unknown lumps.

The cells illustrated in figures 55 to 57 are already exceedingly large, and they are, at a glance, recognized as Marschand’s so—called large-type of decidual cells. On the surface there is a rather thick layer, which may be divided into two of which the inner one is thick and the outer thin, and they exactly remind us of the definite cell membrane. The cell bodies consist of plastosomes, lipoid granules, and structureless stroma. The plastosomes are mostly long rods or threads, some being more or less peculiarly curved and the quantity of plastosomes is variable. The lipoids differ also in point of size, density, quantity, etc. What is worth our noting is that there is no vacuolar formation to be found in these cells. The nuclei are large, clear, and foamy. The nuclear network is especially conspicuous in figures 56 and 57. Figures 58 to 61 show the definite form commonly belonging to the- so-called decidual cells of large type. In these cells the cell membrane is remarkably thick, and the distinction between the inner and outer layers is always clear.’ What deserves our special attention at this juncture is that the outer layer contains, in most cases, ‘a kind of granular body which is somewhat large and yet irregular in sizeland stained a dark color. The cell bodies consist of a large quantity of plastosomes and homogeneous stroma. The plastosomes are mostly long rods, and they sometimes appear extremely elongated in the shape of threads (fig. 61). They are distributed equally all over the cell bodies, although they sometimes tend to appear more or less in groups. The plastosomes in these large cells have, in general, very slow staining properties, and, therefore, they are a very difficult subject to be dealt with from the technical point of view. The nuclei are foamy and dark—colored, and the nuclear networks are indistinct.

The cells illustrated in figures 62 to 69 differ from those described above, and they all lack the plastosomes. Even in the most excellent stained preparations these cells appear within the decidual tissues in small numbers, for the most part more or less in groups, scattered like islets, so that it is, as a matter of course, incomprehensible that here alone the plastosomes are hard to be demonstrated. However, as, in consideration of their structure and shape, it is premature yet to decide posi tively that there is a tendency for a retrogressive change,

among all these cells, I will here suggest provisionally that such a phenomenon is a sign of a certain functional period in the cells concerned. Now, at first, in figures 62 and 63 the cell bodies are comparatively dark, and within they contain a large quantity of vacuoles and lipoid granules of various colors; some of the vacuoles distinctly have a lipoid granule as their nucleus, while others, being placed in rows close to thecell membrane, present a peculiar image. The nuclei are clear and have a somewhat distinct nuclear network. In figure 64 the cell body is filled with numberless vacuoles of nearly the same size, and on one side of the nucleus accumulates a large quantity of protoplasm, and, besides, there are a few deep yellowish-brown lipoid granules. Figure 65 is of nearly the same type as the former, but the lipoid granules contained are by far greater in quantity than the vacuoles. The nucleus is as clear as the former, with conspicuous nuclear network. Figures 66 and 67 illustrate the cells whose bodies are filled with an exceedingly large quantity of vacuoles of various sizes, in consequence of which the protoplasm becomes comparatively scarce and faint and is mostly noticeable only around the nucleus. And, besides, there are some vacuoles which hold dark or deep yellowish-brown lipoid granules; also vacuoles and lipoids, Whose size, quantity, and distribution are as varied as will be seen illustrated in the respective figures. The nuclei are generally dark and show extremely delicate network formations.

Figures 42 to 48 and 51 may be compared, from their sizes and histological point of View, with that class of cells which is termed by many authors as ‘decidual cells of small type’ (or possibly Ecker’s type), While, on the contrary, figures 55 to 61 and 64 to 69 may be nothing but the so called ‘large-type’ or ordinary decidual cells (neutral cells). Further, the various cells illustrated by figures 49, 50, 52, 53, 54, 62, and 63, judged from their size and internal structure, should be deemed an intermediate type which may intervene between the former two, since it is a very diflicult task to determine to which one it should belong. Now, the result of my careful examination of the appearance and distribution of these cells as compared with the time of pregnancy has been that, in the material which was taken a fortnight after conception, this being the earliest I have on hand, the cellular ingredients of the decidua chiefly consist of the small-type cells described above. In a little more advanced stage (i.e., about 17 or 18 days after pregnancy) the decidua shows also the appearance of a large quantity of the ‘intermediate-type cells,’ while in the few days following (i.e., about 22 or 23 days after pregnancy) with the decidua already of definite growth, all kinds of cells, especially the large-type ones, can be detected in comparatively large quantities. One month after pregnancy the large and intermediate type cells appear as the principal ingredients of the decidua, while on the contrary the small-type cells retrograde gradually and are met with only in the interstitial tissue. Such condition is maintained until the end of. the last month of pregnancy. In short, I concludefrom the histological and histogenetical point of view, that the various kinds of cells described above all belong to one class, and consequently it follows that the division of decidual cells into large and small types, is faulty. In other words, the term ‘small-type decidual cells’ applies only to the cells which are still at the early stage of growth, while the ‘large~type cells’ are those'in the last stage of growth. The time taken in -such growth is, according to my observations at the earliest stage of ‘ pregnancy at least, comparatively small, thus the small-type cells being perfected into the ‘definite large-type cells’ in so short a time.

The appearance of lipoid. granules and vacuoles in the decidual cells is most remarkable from the end of first month to the second month of pregnancy, and they gradually decrease in the months following, though very infrequently they can be demonstrated even at the end of pregnancy. The plastosomes could no longer be demonstrated in any of the decidual cells after the seventh month of pregnancy. ' ' '

And, in the interstitium of the decidua, such extremely strangelooking productions as are illustrated by figure 70 may some times be detected. They are stained dark and consist mostly of a great number of granular bodies which are extremely varied in size. There are_ granular threads, which are the result of the granules being linked together, more or less curved large rod-shaped bodies of "different lengths, and sometimes threads which are very long and often curved like screws, besides a large number of material ingredients, which, being mixed up among them, have shapes similar to them and yet are unstained and noticeable only as a shadow. The former, which are susceptible to staining, are dyed deep red by Altmann’s method and deep black by iron-alum-haematoxylin. At a glance they look like plastosomes in their shape and staining, and yet in general excel the latter in size considerably. If aggregated, they may be quite easily detectedunder medium magnification. Moreover, the staining properties of the ingredients are much stronger than the plastosomes, and they bear a rather close resemblance to lipoids in their density and appearance. The product of this kind do not only possess exactly the same properties in shape and stain as the granular bodies in the cell membrane of large-type decidual cells to which I alluded above, but also indicate that there is often the closest relation between the two; i.e., within the cell membrane of the cells concerned there are, besides the granular bodies above referred to, often short granular threads or large rod-shaped bodies, both of which are similar to the substances in the interstitium described above. One end of the rod-shaped bodies sometimes enters deep into the cell membrane and swells into a club—like shape, while a greater part -of the other end juts out into the interstitium, thus giving itself the appearance of passing into the interstitial product. I am not able to explain the original nature and functional significance of this kind of product, and yet, according to the afore-mentioned observations, I have no doubt Whatever that in the formation of the product the large cell, and especially its cell membrane, plays an important part and, since such interstitial substances are "demonstrated in large quantities in the adjacent blood vessels as are illustrated by. figure 71, it may be inferred that they are ultimately absorbed in the vascular organs. The products of this kind are for the first time noticed at about the second month of pregnancy, appear most conspicuously from the end of the second month to the third, decreasing gradually after that, and, though the decrease is considerable after the fifth month, they may yet be demonstrated until about the sixth month. Besides the above, there are detected in certain parts of the interstitium numberless filar productions which have various length, and are sometimes long like threads or fibers, of which the smaller and shorter ones sometimes bear a close resemblance to the plastosomes, while the others usually gather in great number and often make a mass of fibrous bundles. This kind of product, so far as staining is concerned, is entirely similar to the interstitial productions described above, and yet it differs from the latter in that its shape is not so varied, its thickness is nearly always even, and, besides there is no special relation which is noticeable as existing between the products and neighboring cells.

As is generally well known, the uterine gland undergoes a certain morphological change at the early stage of pregnancy, and in my previous treatise I have drawn attention especially to the fact that the glandular cells also show a morphological change at such a time. Here I will observe and describe more thoroughly the changes of the cells concerned.

Figure 72 shows -a glandular cell which is commonly noticed at the early stage of pregnancy and which is already remarkably thickened and somewhat round. The shape of the nucleus for the most part corresponds to that of the cell. On top of the cell there are traces of cilia. The cell -body contains many slender and rod-shaped plastosomes, which latter chiefly gather closely against and surround the nucleus. In figures 73 and 74 the cell grows larger, and the plastosomes are demonstrated only in the upper half, while in the lower half which contains the nucleus, none of them are found. At this section of the cell there are plenty of lipoid granules, which are of about equal size and are stained a bright yellowish-brown color, and on top of both cells there are still the traces of the cilia. In figure 75 the cell is remarkably elongated, and within are contained a great number of lipoid granules. The nucleus is oval with a nuclear network distinctly observed; from this period on no more traces of cilia are to be found. The various cells illustrated by figures 76 to 78 gradually increase in their size and, since their swelling is remarkable, especially in the upper half, it is usual that this partsof the cell naturally juts far out into the lumen, though‘ the lower half, being comparatively narrow, is closely united with the basement membrane. Within the cell body are contained a great number of both lipoid granules and vacuoles, of which the vacuoles in figure 76 are as yet small and few and they chiefly occupy positions in the upper half of the cell body, whereas in figures 77 and 78 the vacuoles enlarge tremendously and fully occupy the upper half, in consequence of which cell bodies have the appearance of a honey comb in a high degree, and the protoplasm remains only as a thin wall which separates the vacuoles. The lipoid granules in the latter two kinds of cells chiefly crowd together at the base of the cell bodies, and only a small portion of them are left behind as contents of the vacuoles. The afore-mentioned three cells each present conspicuous nuclear network and nucleoli. And in the various cells in figures 75 to 78 no plastosomes are to -be detected.

Figure 79 illustrates a large oval-shaped cell, Which has a similar-shaped large alveolar nucleus. The cell body, because of the vacuolar formations of various sizes, presents the image of a conspicuous honey comb, while the plastosomes lie scattered somewhat plentifully in the interstice between the vacuoles. Though there are some extremely small vacuoles in jet black, no ordinary lipoid granules in coarse grains are to be found. The contents of the nucleus are nearly homogeneous, and the characteristic nuclear network is not found,’ but within the nucleus there are two nucleoli. Figure 80 is an extremely irregular-shaped cell, with the nucleus of a corresponding shape. The structure of the._cell body is nearly the same as that in the preceding figure, and the vacuoles are somewhat plentiful, but the plastosomes are very few, and, besides, there are but few yellowish lipoid granules. The nucleus has a conspicuous network. .

As the change of the glandular cells reaches a high degree, the cells leave the basement membrane in large numbers and are isolated in the glandular lumen. Such cells I call temporarily the ‘desquamated cells’ in contrast to the cells which continue to settle on the basement membrane or remain fixed on the walls. Figures 81 to 83 illustrate my so-called desquamated cells, in the inside of whose cell bodies there are many vacuoles and a small number of extremely small lipoid granules which are stained in black. At a glance they look like the ‘wall-fixed’ cells, and yet on a careful comparison we find that there is a more or less remarkable difference between them. That is to say, in the desquamated cells the cell bodies are in general somewhat turbid, and also the vacuoles look somewhat withered and decayed. No plastosomes are to be found, and, besides, the change of the nucleus is remarkable, as will be seen in figure 81. Here it is converted into a darkcolored and homogeneous lump provided with a Very irregular contour, having within a few small nucleole-like bodies. In figure 82, as before, the nucleus is simply a homogeneous and dark-colored lump; in figure 83 it has swollen somewhat remarkably, and the nuclear network‘ is extraordinarily conspicuous. In short, the desquamated cells hav_e undoubtedly began a retrogressive degeneration already, andfrom the existence of many broken pieces of cells which are always found in the glandular lumen it can be simultaneously demonstrated that the desquamated cells are doomed to break up and perish at this section sooner or later. The various changes undergone by the glandular cells described above are seen in a remarkable degree already on about the seventeenth or eighteenth day of pregnancy in the decidua serotina, while in the decidua vera it is a little bit later and the changes are noticed to about the same degree as the former only toward the end of the first month of pregnancy. Both reach the maximal changes at about the end of the first month of of pregnancy, and on the days following they gradually pass into the so-called desquamated cells and break up and perish as such.

The series of changes described above have a more or less difference of time between the decidua serotina and the decidua Vera, viz., in the formerpthey may be followed up vigorously up to the end of the second month "of pregnancy, though in the third "month they suddenly decrease, whereas in the latter such changes may be demonstrated even one month later.

THE HISTOLOGICAL STRUCTURES AND THEIR FUNCTIONAL SIGNIFICANCE (SOME REFLECTIONS ON LITERATURE)

In the preceding chapter I have given a somewhat minute account of the delicate histological structures of the various important cell groups which exist in the placenta and the decidua vera at different periods of pregnancy. Now, on a perusal of the observations given therein, it will be found that as components which are common to the various cell groups there are 1) plastosomes, 2) lipoid granules, and 3) vacuoles. As a matter of course the degree of the appearance of the three kinds'of components and their distribution in which they are present vary infinitely as the kind of cells differs or according to each individual cell. However, that which exercises the most important influence over the shape and formation of the cell is chiefly the lipoid granules and vacuoles, of which the latter often appear in a very great number and occupy the whole body of the cell, thus giving the cell a highly foamy appearance or a honey comb structure. The cell which has fallen into such highly vacuolar formations makes one feel, at a glance, that it has presented a phenomenon of collapse due to the regression of the cell concerned, as some observers ‘are apt to conclude quite hastily. However, as, on a careful examination of it, it is found that, in spite of the high degree of changes. shown by the cell, there are demonstrated for the most part within the cell body the plastosomes which are deemed an important active element in the functions, and also in consideration of the normal structure of the nucleus and of the fully stained conditions of the cell body, there is no doubt as to the cells being alive. And even if it should be conceded for a while that the cell having the fully stained vacuoles as described above is the indication of a kind of regression, who could explai11 the reason why this kind of ‘regressive’ cell actually appears in so high a degree within the tissues of the placenta ‘and the decidua at a certain period of pregnancy, and especially in the first half of pregnancy when the tissues should grow in a most vigorous manner? Therefore, I am confident that not only is it wrong to deem such vacuolar formations a death phenomenon of the cell, but also they should rather be taken for a quite significant phenomenon which shows a certain function of the cell concerned. And, as regards the actual existence of such a function, I am inclined to assert from their closest resemblance to the structures of many other glandular cells, as a result of my histological observations, that a secretory function is existent in these kinds of cells. However, as the problem is of such a provisional character I will, for the present, reject all hasty assertions, but instead will consult literature Widely and make generalreference to the previous interpretations of many authors on the structures and secretory processes of the various glandular cells in the organs in -which secretory functions are definitely known, so that the most deliberate considerations can be given my histological observations and their functional significance, which, being compared and discussed under impartial criticism, it is hoped, will help toward making the original nature of the functions clear.

Since the relations between glandular histology and secretory functions were early dwelt upon by R. Heidenhain (’68, ’75, ’80) with his penetrating eyes, the subject has aroused the interest of many excellent physiologists and histologists, and the studies of’ the subject have since followed so quickly one after_ the other, that it would be difficult to enumerate them here. The following are the principal authors who have studied the subject, and the materials chosen by them for investigations were chiefly pancreas, salivary glands, gastric glands, lacrimal glands, skin glands, and pelvic glands, all of which are usually known as representative glands in many kinds of animals classed above the amphibians: Schultze, Fr. E., ’64 and ’67; Langhans, ’69; Pfiiiger, ’7 1; Schwalbe, ’71 ; Ebner, ’73; Nussbaum, ’78 to ’82; 516 GENCI-IO FUJIMURA

Kiihne and Lea, ’82; Nicoglu, ’93; Altmann, ’94; Galeotti, ’95; Krause, ’95 and ’97; Muller, ’96 and ’98; Solger, ’96; Zimmermann, ’98; Held, ’99; Maximow, ’0l; Noll, ’01; Fleischer, ’O4; Heidenhain, ’07; Babkin, Rubaschkin, and Ssawitsch, ’09.

I will not go to the trouble of giving a detailed accountof each of the results of these research works, but will confinemyself to summarising the main points of their investigations respecting the structure and secretory phenomena of glandular cells, which are most essential to my studies, and refer to the original works for details.

In the first place, the structure of the glandular cells having a duct, or externally secreting glands, greatly differs, as is generally well known, according as they are serous or mucous. The serous cells have an exceedingly large number» of granular bodies, and consequently their characteristic is that they are generally dark. Thesegranular bodies are generally known as Cl. Bernard’s secreting granules. The .relation which the latter has to secreting functions has been generally recognized by

and it will be noted that Heidenhain, having observed a kind of slender thread-like structure which exists close to the basement membrane, of the glandular cell of a dog’s pancreas, for the first time drew general attention to a peculiar sort of organic structure which is existent in the glandular cell. This kind of

ducts and convoluted uriniferous tubules in after years, and it cannot be anything but M. Heidenhain’s so-called ‘Basalfilamente’ or our plastosomes. '

ing in these organic tissue elements of .the glandular cells which will follow the secretory functions.

Now, at first, it is universally agreed by every author that secretory granules increase or decrease according to secretory functions. According to the result of the close examination with respect to such correlation, conducted chiefly while in a fresh condition, of the pancreas of the rabbit, the oesophagus glands of the frog, and the gastric glands of the water lizard, by Langley (’79 and ’89), whose exposition of the correlation is best authenticated, it will be noted that during suspense of their functions glandular cells are generally glutted with secretory granules, whereas as secretion begins the granules gradually decrease and disappear, in consequence of which in each cell will appear a sharp demarcation between the homogeneous wide outer layer and the remaining granular inner layer. This observation of Langley has been repeatedly proved‘ by many other authors in many other glands, and its validity except in a small number of cases, has been recognized by nearly everybody.

For convenience, I defer to a later section a minute explanation of the functional significance of the thread-like production which is found in the basal part of glandular cells. n .

Even in mucous cells it has been universally acknowledged by many authors since F. E. Schultze (’64) that there are granular bodies in large numbers at a fixed period of secretion, and at the time when secretion is very high these granules gradually disappear asin the serous cells (Langley, ’7 9 ; Biedermann, ’82). It seems therefore that in the forms of secretion formation mucous cells agree, for the most part with the serous cells. However, the reason Why both differ Widely in their structure is that in the latter the secretion is, for the most part, speedily drained into the glandular lumen at the time of secretory function, whereas in the mucous cells it is formed withinthe cell bodies, besides being stored up there for a certain period, thus giving the cells a peculiar structure and a characteristic clearness.

In short, in the aforementioned two kinds of glandular cells, the large quantity of secretory granules always to be seen in both during suspense of secreting functions disappears, by degrees as the functioning begins. In View of this fact, we have no doubt whatever that, at the time of secretion, the granules always play an indispensable part as the mother-ground for the secretions and, since secretory granules are generally deemed a solid production, according to the investigations of many authors while the secretions are mostly fluid, it follows that it would be no great error to take it that, viewed simply from the histological standpoint, the so—called secretion, after all, _means, the liquefaction of secretory granules. However, the modes of liquefaction are, according to my view, so varied that they should by no means be dealt with in one and the same manner, but rather there are, roughly speaking, several forms, such as are given below, according to the kinds of glandular cells, or according as the cause which prompts secretion differs.

First form. This is observed in certain mucous cells. The secretion is brought into being simply by the melting down and growth of secretory granules which have developed in a fixed degree, and, different from many other glandular cells in which the secretory granules are mostly preproducts of secretion, the granules here in this case show the same reaction as secretion (that is, mucin) from the beginning of their appearance and find themselves already identical with the secretion as early as they appear. This fact was demonstrated by M. Heidenhain in the goblet cells of the intestine of the salamander, and it is, in general, difficult to tell definitely the time of liquefaction in what is covered by this form.

Second form. This is observed in many mucous cells. The granules, while in the first stage, appear as a certain preproduct (mucigen), and undergo a chemical change simultaneously as they have developed to. a certain degree, and are changed into the ordinary secretion (i.e., mucin). Mention has been made to this effect by Biedermann (the mucous cells of the frog); M. Heidenhain and Nicoglu, ’93 and ’98 (the skin glands of a salamander); Altmann, ’94 (the submaxillary glands of a cat); Maximow, ’01 (Glandula retrolingualis of a hedgehog).

Third form. This is often seen in ordinary serous cells. As the functions begin, the secretory granules begin to liquefy gradually on the periphery and, although it appears that the granules are imbedded for a certain period in the secretion already formed, they finally change thoroughly into secretion, and then appear as simple vacuoles within the cell bodies. The

‘clear halos around the granules referred to by Langley ('34), Corlier (’96) and Maximow (’01) were it seems, deemed by these authors-an essential ingredient in the formation of glandular cells; however, M. Heidenhain with Nicolas (’92) attributed one part of them rather to artificial production, while the other was brought into being in the form it appears in, possibly becausethe granules were reduced in size in connection with secreting functions.‘ And in recent times the researches regarding pancreas cells, conducted by Babkin, Rubaschkin, and Ssawitsch CO9), have proved the above mentioned views of Heidenhain with more force and accuracy; that "is, in the opinions of these authors, clear halos around the granules are, after all, nothing else but secreted matter which appears as a liquefied product of the granular substance. And that such an image should be a sign of an important period in secretion formation within the cell bodies will be clear in the statement made by the three authors mentioned above on the changes which zymogene granules undergo at the period of a pancreas secretion: “Wir erhalteh den Eindruck, als ob das (Zymogene) Kornchen sich allmahlich auflost, in dem es sich immer mehr und mehr Verkleinert und in em kleines verwandelt” (p. 92). Fourth form. According to the views of Babkin, Rubaschin, and Ssawitsch above referred to, this presents an appearance somewhat like a modification of the third form. That is to say, many secretory granules together with the intergranular substance concerned form themselves into somewhat large masses, which latter slowly begin to liquefy from the periphery, and are then gradually changed entirely into secretion in rather large drops, to be drained out into the glandular lumen. Compared with the third form, in which each individual granule becomes liquefied separately, this type differs from the former in that a number of granules coagulated together in lumps are transformed gradually into drops of secretion. This form is distinctly demonstrated at a time when the function of pancreas cells is very greatly increased, especially by means of stimulating the vagus nerves or of soap infusion in the duodenum, it being characteristic of the secretion at such a time that the latter is very dense, and is rich in albumen and ferments. And the three authors mentioned above are of the opinion that the several bodies which are revealed by this secreting form may be compared with the small bodies which are often known as ‘Nebenkerne,’ ‘parasome,’ ‘corpusculus paranuclaires,’ and ‘noyau accessoir’ in the pancreas cells of the lower vertebrates.

Fifth form. This points to a case in which the substance of secretory granules changes its quality at a certain period, becomes soluble, and is only dissolved in the watery part of the secretion alone, as was instanced by Babkin, Rubaschkin, and Ssawitsch, in the experiment of the pancreas secretion after pouring acid in the duodenum. As a proof thereof, the secretion always shows in this case the same coloring reaction as do the zymogene granules.

The three forms (the third to the fifth) described above are together met with in the pancreas cells, and it deserves special attention that accordingas the cause differs for the rise of secretion, even in one and the same glandular organ, there is a difference in the forms of secretion, and consequently in the nature of the secretion produced.

Sixth form. Certain secretory granules sometimes have two extreme developments. As an instance, M. Heidenhain observed the skin glands of a salamander and he found that, as the development of the granule reaches a certain degree, one part of it is liquefied and passes into a viscous secretion, while the other goes on growing in size, and is perfected into the characteristic poison grains.

Seventh form. A certain organic structure is presented in the secreting granules; at the beginning it is not different

accomplished, every granule is divided into a crescent—shaped section (Kapuze) which is stainable, and into an unstainable section (Trager) within the crescent-shaped section, thus forming the ‘Halbmondkoperchen’ so termed by M. Heidenhain. This latter as it grows in size is considerably enlarged, especially in the Trager, and consequently the Kapuze is flattened gradually and is only stuck like a plate on its one side. Then the Trager is at last dissolved altogether and is changed into secretion, while at the same time the Kapuze is also condensed, and forms itself into secondary granules, later on to be drained out along with the secretion, thus bringing about an entirely granule free condition of the cells. This form of secretion was first detected and examined closely by M. Heidenhain in the pelvic gland of a salamander and in the lacrimal gland. Subsequently, Nicolas (’92), in a man’s lacrimal gland, Held (’99), in a rabbit’s submaxillary gland, and Fleischer (’O4), in a coW’s lacrimal gland, observed and proved the appearance of the crescent-shaped small bodies described above.

The above does not cover all the forms of granular liquefication at the time of glandular secretion, and yet it will be quite clear how varied the modes of liquefication are. . "

Now, I will discuss a little further the origin, and therefore the manner in which supply is made of secretory granules, this problem being the second in importance with respect to glandular secretion. _

With regard to the origin of secretory granules, the problem itself is a very difficult one indeed, but it should be noted that, along with the sudden increase of studies on plastosomes in recent years, many authors have attempted a solution of this troublesome question.

Below I give a general account of the result of these researches. Generally speaking, every author equally agrees in the argument that every glandular cell always has within the cell body plastesomes as constant ingredients and, though the quantity and arrangement of the latter are certainly varied, it is the usual condition that while the serous cells are in a state of rest the numerous plastosomes are chiefly arranged in rows along the long axis of the cells. These plastosomes, however, generally decrease in quantity considerably during the period of secretion, especially when the cells are filled, and they are then found largely, close to the basement membrane of the cell, while near the lumen, they are either entirely absent or, if they are found, they are

between the granules in a very small number. And in mucous cells, in contrast to serous cells, the plastosomes are found largely 522 GENCI-IO FUJIMURA

near the nucleus, though some lie scattered in the protoplasm between the secretory granules, all being arranged in an irregular order. With regard to the functional significance of the plastosomes contained in these glandular cells, there are various theories, such as the theory of secreting mechanism by Benda (’O3, p. 780), that of water-secreting apparatus by M. Heidenhain (’O7), and that of prop system by Bruntz (’08); however, these are either the historic ones, having been refuted experimentally by Meves and Regaud (’08) already, or mere assumptions.

What is believed by a great majority of authors at present is that plastosomes are very closely related to the formation of secretory granules. And the first man who published his views with'regard to this was Altmann (’94), who’ thought that his so-called ‘vegetative Faden’~a greater part of which agrees with our plastosomes of to-day~being split up in small pieces are formed into granular bodies in large numbers and make the beginning of secretory granules. Quite recently the researches of Laguesse (’99 a, b, ’05, ’11), Regaud (’O9), Regaud and Mawas (’09), Hoven (’10, ’11,-’12), Champy (’11), Schultze (’11), have followed one after the other, and, though their observations may differ a little from one another, either in trifling points or in the form of description, they none the less fall entirely into line with Altmann’s View that the formation of secretory granules has its origin.in plastosomes. And, moreover, the fact that, as is generally acknowledged, the number of plastosomes in glandular cells always increases or decreases according to the changes of secreting functions is nothing if not forcibly proving the validity of such a theory. l

are opposed to it. Especially M. Heidenhain, taking his stand on the ‘Protomeren-Theorie’ which he set forth, states that secretory granules should have their origin in extremely faint and extraordinarily small bodies in the protoplasm which are beyond our sight; these bodies growing up and increasing should gradually develop into the ‘smallest granules-—his ‘Primargranula’—which are seen microscopically to gradually bring about the growth of definite secretory granules. Thus it seems he denies the-histogenetical correlation between plastosomes and secretory granules. His theory, though most dex-_ terously proposed on the most profound proofs, is after all a mere hypothesis. Besides, in consideration of the following quotation, it will be quite clear how he holds the views that his so-called ‘Primargranula’ have a close. relation with the genuine cytomicrosomes in their formation, and that the _latter do correspond to a section of his ‘Basalfilamente,’ and, further, that the filaments are identical with F1emming’s M.itom:

Ich bin daher mit Solger der Meinung, dass auch in den serosen Driisenzellen die Basalfilamente Teil eines Fadensystems sind, welches nach der Bezeichnungsweise Fle_mming’s dem sogennanten Cytomitom zugehoren wfirde. . . . . Nicht ganz ausschliessen darf manjedoch zur Zeit die Moglichkeit, dass die Drfisengranula evéntuell von den genuinen Plasmamikrosomen sich ableiten, welche nach unseren allgemeinsten Erfahrungen immer innerhalb der Protoplasmafilamente liegen, also verdichtete Teile feiner Fadchen sind. . . . . Da nun die Korperchen beiderlei Art (Primialrgranu-lis und genuine Mikrosomen) morphologisch schwierig unterscheidbar sind, so kanneine verwandschaftliche Beziehung zwischenbeiden zur Zeit wenigstens nicht abgelehnt wervden, besonders da wir fiber die positive Bedeutung der genuinen Plasmamikrosomen noch sehr im Unklaren sind (p. 390).

And since it has already been clearly, proved by the researches of Meves (’07) that F1emming’s Cytomitom agrees with our plastosomes, it would appear that M. Heidenhain does not only maintain the View that his ‘Basalfilamente’ exists as a watersecreting apparatus as mentioned above, but at the same time also supports, instead of disproving, the argument which regards basal filaments as being the matrix forthe formation of secretory granules, as Altmann and others do. As regards Mislawsky’s view, it will be noted that he, in line with ‘Levi, takes the ground that as between plastosomes and secretory granules there were no conspicuous conditions to be detected in support of the existence of a formative relation between the two. However, anent Mislawsky, it will be noted that the invalidity of such a view has been exhaustively pointed out by a Belgian cytologist, Duesberg, in comments noted for their profundity and thoroughness. The following phrase is there employed by him: “Ein negatives Resultat beweist nichts gegen eine Reihe positiver Resultat und man kann nur schliessen, dass Mislawsky die Bilder nicht beobachtet hat, die seine Gegner unter Augen hatten” (p. 785). This should incidentally prove to be a pertinent comment on the theory of the excellent Italian author, Levi.

If we summarize the observations of the various authors respecting the structures and functions of the glandular cells described above, we may enumerate as constituents of the glanduar cells, 1) plastosomes, 2) secretory granules, and, 3) secretions (vacuoles), besides the protoplasmic stroma proper, and it would be superfluous to state that of these constituents secretory granules have a directly important relation to the glandular secreting functions. The secretions are nothing else than a liquefication or modified product of the latter and there is no alternative but to assume that the secretory granules, once lost at secretion, take their matrix mostly from the plastosomes, which latter, being split up and separated in small pieces, gradually meet the deficit so caused. Thus, the real state of glandular secreting functions is already a thing which can be largely followed up and made clear by means of minute histological investigations to-day.

Also the histological studies of the ductless glands—~internally secreting cells—have become very active of late years, and, especially among those which have been carried on by the methods of plastosomic study, we may enumerate the thyreoid and parathyreoid glands, suprarenal capsules (chiefly its cortex), Langhans’ islets of thepancreas, and the ovary. Of these organs, the ovary has been used more often than the rest as the object of study, and consequently, comparatively speaking, much is known about it. I will therefore give a general summary of the observations of the various investigators respecting this organ, consider its structure and the relations of its internal secretory functions, and then glance at the structures of the other organs, thus contributing toward a histological account of internal secretion in general.

That the corpus luteum is a kind of internally secreting organ (from the histological point of view) was advocated by Prenanas early as 1898 and by Born in 1900. Subsequently, the argument has been advanced with more certainty by a close histological study conducted by Regaud and Policard (’01), Fr. Cohn (’O3), Mulon (’09), Athias (’l1), Van der Stricht (’ 12), Tsukaguchi (’12, ’13), and Levi (’13). And the main grofind of this argument lies in nothing but that the luteal cells contain as formative ingredients of the cell bodies plastosomes and lipoid granules, and often demonstrate a very large quantity of vacuoles which may be deemed their secreted matter, and also that the close correlation between these ingredients functionally is plainly apparent in the same manner as it is seen in external secretory cells. Of the various ingredients mentioned above, lipoid granules certainly have the most important significance in internal secretion; however, since the latter is not only characteristic of luteal cells, but is also widespread among the other kinds of internal secreting cells, Tsukaguchi has already argued that it would be proper, in view of its functions, rather to compare them with the secreting granules of ordinary glandular cells. '

In the next place, Cohn first regarded the vacuoles in a rabbit as a secreted matter of the luteal cell, and he saw them simply as a dissolved product of lipoids; subsequently Tsukaguchi also studied the same animal, and likewise deemed them a modified product of lipoids. However, vacuoles differ exceedingly in the degree of their development in all kinds of animals. For instance, Van der Stricht did not notice any vacuoles in the luteal cell of a bat, and subsequently Levi’s observations regarding the same animal nearly agreed with those of Van der Stricht. _ In the guinea-pig, however, Levi noticed a small number of vacuoles, which he attributed to a retrogressive phenomenon of the cell concerned, and he stated that this phenomenon, by means of a chemical change of lipoids following it, could cause possibly the substance of the latter to be dissolved by the benzol and xylol which had been used by him, as clearing media. In short, whenever the vacuoles appear, the lipoid granules first make their appearance as their forerunners, and the former pass into the latter in succession, as has been entirely agreed upon by many observers.

With regard to the origin of lipoid granules, the Zoyas (’91) pointed out that there was a certain quantitative relation between granules and plastosomes, and this fact was acknowledged by Mulon, Athias, and Tsukaguchi, though Levi alone tried to deny it, as in the case of external secretory granules.

With regard to the secreting phenomena of luteal cells, Van der Stricht argued that in the order Chiroptera it was possible to divide them into two forms, viz., serous secretion and lipoid secretion. By serous secretion is meant that the follicular epithelium, being the antecedent of the luteal cells, secretes liquor folliculi, and, according to him, the Graafian follicle, after rupturing, still keeps on secreting in this manner for a fixed period, it being characteristic of this secretion that in the peripheral part of protoplasm of the young luteal cell some serous infiltration appears, and for that reason gives that part generally a somewhat transparent appearance. Already at this period a large quantity of small lipoid granules appears within the cell bodies; however, since these granules do not as yet per ‘form any functions, he called this stage the serous secreting

period of the luteal cells; then, as the ovum settles,.the corpus luteum has already reached its highest degree of development, and he termed it the second stage of corpus luteum formation.

At this stage the cell body is already filled with numberless lipoid granules, which, undergoing a chemical change, cause the cell body to keep on discharging secreted matter until the end of pregnancy. This is what the lipoid secretion means. This theory seems to have been afterward accepted in the main also by Levi. However, the condition is entirely different in the Rodentia, and especially in the rabbit. According to the observations of Cohn and Tsukaguchi, lipoids chiefly appear in a high degree only in the early part of pregnancy, then disappear rather speedily. In the second half of pregnancy the lipoids change into vacuoles almost as transparent as water, the cell bodies present a highly distinctive vacuolar structure, such condition being still more conspicuous toward the last period of pregnancy. N ow comparing this with what is observed in the Chiroptera mentioned above, this period of lipoid secretion, so-called by Van der Stricht, in the rabbit passes away in a comparatively short time, and then slowly passes to the stage of the characteristic vacuolar image; thus, it appears, it presents a certain stage of secretion which is peculiar to itself. In short, it is interesting to note that, in consideration of the changes in the forms of secretion in external secretory cells, the structure, and therefore the form in the secreting functions even in the same luteal cells, differ according as the class of animals differs.

That the interstitial cells of the ovary possess the same internally secreting functions as luteal cells, by reasongof the close resemblance which they bear to the latter in shape and structure, has been universally acknowledged in the researches made, in various kinds of animals, including the Rodentia, Chiroptera, and Carnivora, by Regaud and Policard (’01), Limon (’02, ’03), Fr. Cohn (’03), Regaud and Dubreuil (’O6), Mulon (’11), Athias (’11, ’12), Van der Sticht (’12), Tsukaguchi (’12, ’13), Levi (’ 13) . Now, according to these observers, the interstitial cells also contain, as do the luteal cells and many other glandular cells, important constituents, such as plastosomes, lipoid granules, and vacuoles. The vacuoles are especially very plentiful, and they, for the most part, present a minute, delicate, and peculiar vacuolar image, the protoplasm proper being barely noticeable around the nucleus. The lipoid granules, as compared with the luteal cells, are generally small in quantity and, moverover, it is sometimes difficult to detect them. It is customary for the lipoid granules more or less to increase in quantity at the time of pregnancy. It has been equally acknowledged by many observers that the lipoids of the interstitial cells generally appear for a comparatively short period, commonly fade away in color and change in quality speedily, thus gradually passing into the vacuolar substance. And then, many authors, except Levi, have proved and recognized, even in this case, that plastosomes have a direct relation in the formation of lipoids.

Entering into details, Mulon stated that in the rabbit the plastosomes, granular in form at first, change into minute siderophil granules, and then diffuse siderophil substance, and the lipoids will be formed from the latter. Athias (’12), who examined a newborn bat, also seconded the argument of Mulon for the most part, and argued that plastosomes produce the lipoid first at their center and accumulate it there, and in support of his argument he stated that occasionally the cortex, which has the same staining properties as plastosornes, could be detected around the lipoid granules. Tsukaguchi certified to an intermediate type of granules between the plastosomes and the lipoid in the young interstitial cells, thus arguing that the granular plastosomes develop and grow in size directly into the lipoid granules, as are seen in the case of the luteal cells. In short, the various investigators have not as yet come to an agreement in their views as to the correlations between the two, and yet it has been universally acknowledged by them that as the cells grow and increase and the lipoids or vacuoles appear plentifully, the plastosomes decrease in quantity in inverse ratio.

With regard to the organs other than the ovary, Mulon (’10 a, b) closely examined the suprarenal capsules of a guinea-pig and rabbit, and stated that by the conglutination of the granular plastosomes was produced directly a ‘substance (possibly our lipoids) which has affinity for osmic acid (osmophil) or ironalum-haematqxylin (siderophil), and is introductory to the formation of a vacuolar secreting matter to follow. Celestino da Costa (’07), Champy (’O9), and Colson (’10), also having experimented on the cortical cells of the suprarenal of a cat, guinea pig, toad (Bombinator) and bat, have proved the same fact as

above. Bobeau (’11) also argued that when the parathyreoid glandular cells of a horse form a certain effective product the plastosomes should play an important part. And, besides, Engel (’09), Mawas (’11), and Schultze (’11), each demonstrated the plastosomes in the thyreoid and parathyreoid glands of a man, a rabbit, and a frog, and, according to Duesberg, it was stated that the plastosomes could be detected in the Langhans’ cells of the pancreas. It should none the less be stated that a majority of the facts enumerated above are merely preliminary. Many future investigations must be looked forward to for a further enlightenment of the secretion of these organs.

In summarizing the histological knowledge We have at present of the internal secretory cells described above, almost every cell has, as its constant ingredients, plastosomes, lipoids, and vacuoles. Now, the plastosomes are not regular either in their shape or‘ arrangement while the lipoids are not quite regular in their size, quantity, and color, but the smaller ones bear a resemblance to granular plastosomes, while the larger ones, agglutinating with one another, form larger fatty droplets. The contents of the vacuoles probably consist of watery, transparent droplets, which are separated from one another by a very thin partition wall. The cell body should present a more or less conspicuous alveolar structure in proportion to the quantity hf vacuoles contained. The quantitative correlation by which these formative ingredients are connected to one another is not free from considerable variations. Occasionally only one or two of them exist to the absolute exclusion of all the rest._ It must be very often the case that such phenomenon-may. be partly due to the difference in the order of animals chosen for the subject of study and partly to the functional relation of the cell concerned. In short, it may be said that the various formative ingredientsdescribed above as being seen_in internal secretory cells constitute equally necessary constant elements, the same as with external secretory cells, as has been minutely dwelt upon previously. Now, it is a marvelous sight indeed to compare, histologically these two kinds of cells, and to look at the perfect agreement, not only in their structures, but also in the various histological changes which follow their functions. On this score, I am convinced that should there be a structure like the two kinds, of cells described above, besides the functional changes which very nearly correspond to the above, it would be no error to bring such cells under the category of glandular cells, regardless of the existence of a duct in them. And, if we look at the various cells of the placenta and the decidua, we will find that all of them are well furnished with various conditions which mark the glandular cells above referred to, and that naturally we should assert the existence of secretory processes in them , also. In the following section, I will give a detailed account of. the secretory phenomena of the various cell groups.

It is too plain to need argument that in-all cases the real state of the life processes of any cell cannot be made clear unless all the phenomena in the living condition of the cell concerned be followed up closely with the microscope. However, since it is certainly difficult to attain such an object by the histological method employed by us at the present time, by noting the phenomena of internal secretion it is possible to denote each of the extremely varied structural images obtained from the preparations fixed and stained as indicating a certain period in the phenomena of secretion; to compare carefully and consider the correlations between the different periods, and thus to infer the whole of the process of secretion. Therefore, I must ask the reader to take this point into consideration.

Now, at first, in figures 1 and 2 only plastosomes are present, M and lipoid granules and vacuoles are entirely absent, so that we may conclude that this shows the early stage at which secretion is not yet in appearance or when secretion is at rest. In the next place,‘ in figures 3 and 4, more or less lipoids appear, and vacuoles are either barely found at one part or not formed as yet; the lipoids, in general first appear on the superficial