Part 26

ABDOMINAL RECTI │ PECTORAL │ PSOAS ═══════════════╤═══════════════════════╪═══════════════╪═══════════════ TOXIC │HEMORRHAGE INTO RECTUS │ TOXIC │ TOXIC DEGENERATION │ │ DEGENERATION │ DEGENERATION ───────────────┼───────────────────────┼───────────────┼─────────────── 745 on 10th day│745 both on 10th day │756 on 8th day│756 on 8th day 749 on 4th │752 both on 13th │770 on 11th │792 on 6th 752 on 13th │756 both on 8th │ │ 756 on 8th │764 both on 9th │ │ 757 on 6th │765 both on 9th │ │ 762 on 10th │778 both on 23d │ │ 763 on 11th │————————————————— │ │ 764 on 9th │ RUPTURE OF │ │ 765 on 9th │ RECTUS │ │ 767 on 10th │ │ │ 770 on 11th │745 right on 10th day │ │ 778 on 23d │756 both on 8th day │ │ 783 on 8th │778 right on 23d day │ │ 791 on 6th │ │ │ ───────────────┴───────────────────────┴───────────────┴───────────────

We have convinced ourselves that the marked hemorrhage taking place in the muscle tissue follows upon a primary degeneration of this tissue and its spontaneous rupture. The amount of hemorrhage is in proportion to the degeneration and fracture of the muscle elements. The hemorrhage does not precede the muscular change, nor does it have any antecedent relation to the actual tearing of the muscle fibers.

A much better appreciation of the muscle degeneration was obtained in the _microscopic_ studies of these tissues. The various gradations of tissue change could be followed, which was not possible in the naked-eye examinations. Some points respecting this degeneration were quite noteworthy. Firstly, the process of degeneration in its early stages and advancing through the acute destructive periods was not accompanied by any inflammatory reaction. Evidence of inflammatory exudate was obtained only when the degeneration had proceeded to a degree permitting of rupture with hemorrhage, or in the late stages when the areas of marked muscle dissolution were undergoing repair. We have no evidence to indicate that bacteria were present during the beginning of the degenerative process. Bacteria could not be demonstrated in section. The appearance of the tissue suggested a purely toxic process which was selective in its action, picking out voluntary striped muscle tissue and attacking certain muscle groups in preference to others. It was also interesting to observe in the early stages of the degeneration that individual fibers lying amidst healthy and unchanged muscle elements would show degeneration in many of its stages. This appearance was often unique, particularly when in the early stages of the process the involved fiber would still retain its normal position and shape though markedly altered in its staining and chemical qualities.

The degeneration as observed in these cases showed many of the characters like that of waxy degeneration seen in typhoid fever. Similar appearances to these have also been described in connection with the toxic degenerations which occur in the vicinity of infections by the gas bacillus. In fact, all the stages observed in the one can be seen in the other. They differ, however, only in the degree to which final destruction takes place and in the speed with which the degeneration is accomplished. The character of the degeneration is well studied in sections stained with hematoxylin and eosin, eosin-methylene blue, and best of all in the phosphotungstic acid hematoxylin. By the latter method one is able to follow clearly the grade of degeneration as it effects the muscle striations. On the other hand, the peculiar waxy appearance of the early degenerating fibers is best seen in sections stained with eosin or fuchsin, where the striated muscle fibers are found to be changed to a more intensely staining red body of homogeneous character and devoid of all evidence of their original internal architecture. These bland waxy fibers were often of the size and shape like the normal. On the other hand, the fibers are also not uncommonly swollen, stretching the sarcolemma to almost the bursting point. Following this primary bland degeneration the fiber takes on irregular shapes, becoming constricted and collapsed at irregular intervals, so that islands of the waxy contents lie within the sarcolemma, being separated from each other by constricted areas in which the original myoplasm has undergone decomposition and sometimes complete absorption. This irregular destruction of the muscle contents often has a granular stage in which the original muscle substance has become disintegrated. The sarcolemma follows the condition within it, stretching when the fiber is swollen and shrinking, or even becoming collapsed when the inner substance is becoming liquified and absorbed. The sarcolemma does not suffer the degenerative changes of the inner fiber, nor can one observe nuclear changes in this sheath which are significant.

When first studying this process of degeneration it appeared to us that the earliest change was a loss of the transverse striations and the subsequent disappearance of the longitudinal fibrillæ. We have subsequently found that this is incorrect and that the changes observed in the markings of the fibers were not constant. At times the muscle substance would progress through stages of degeneration up to the point of disintegration and dissolution while the transverse striæ were still discernible in the altered fiber. The one constant change that we have observed in the degenerating fibers was the early loss of staining qualities as obtained by the phosphotungstic acid hematoxylin. In such preparations the earliest effect of the intoxication upon the muscle fiber was a change in reaction to this stain. Sometimes within a given fiber small irregular and poorly staining blotches could be observed, while the remaining portion of the fiber was normal in its appearance. Later these poorly staining areas became larger, occupying the entire width of the fiber and being distributed at irregular intervals in its length. Finally the characteristic staining quality was entirely lost, although in the poorly colored cell transverse striations were still discernible and a true waxy stage had not yet taken place.

At times the waxy degeneration advanced into the stage of disintegration by an irregular destruction within the fiber. When this occurred the fragments of waxy substance took on curious coiled and grotesque shapes, while a granular destruction was taking place in their periphery. Neither inflammation, œdema nor a vascular reaction could be determined in these tissues of mild or severe change. The reaction as is indicated in the table occurred quite acutely and was not accompanied by fatty products commonly seen in the slower forms of degeneration.

Gradually the debris of the degenerated fibers is absorbed and the sarcolemma shrinks and collapses upon itself. During this stage a reaction occurs in the sarcolemma with nuclear proliferation. At times the last vestiges of the muscle fiber are seen to be surrounded by a crown of nuclei and cells reminding one of the appearance of the degenerating nerve cells in the Gasserian ganglion in hydrophobia. The involved area becomes active in appearance, showing proliferation of fibroblasts and the appearance of occasional lymphocytes and plasma cells. Scar tissue continues to develop in proportion to the amount of damage done. In areas where hemorrhage had taken place the amount of scar tissue is exaggerated, owing to a process of organization which is taking place quite apart from the muscle degeneration. Thus not a few scars scattered through the voluntary striped muscles are the final outcome of this toxic degeneration occurring in epidemic influenza. Some of these lesions may account for the indefinite pains and symptoms of which the patient complains for so many months after his acute illness. I refer particularly to lesions occurring in the psoas and muscles of the back as possible explanations for the partial invaliding of some individuals.

In a certain number of cases of acute influenza the patients complain of severe abdominal pain, in the absence of any localizing symptoms or evidence of intestinal derangement. Such was the case with a number of the above cases coming to autopsy, and the sole evidence we could offer was muscle degeneration with or without massive hemorrhage. The abdominal pains complained of were more of the nature of dull aches with occasional exacerbations and shooting or lancinating “stitches.” Rarely was the patient able to define the position of the pain, not being able to state whether it was within the abdomen or in the parietes. Most frequently they claimed it was internal. We have on no occasion demonstrated an intra-abdominal lesion which could account for such pains. None of our cases was of the type of “intestinal influenza.” We are, therefore, led to the conclusion that the muscle degenerations of the various degrees, from the slight with few muscle elements involved to the severe with rupture and hemorrhage, account for a proportion of the clinical symptoms of (muscle) pains and aches as well as weakness. We cannot claim that coughing was a necessary factor in inducing rupture of the abdominal recti. In some of the cases with rupture severe coughing had not been observed during the illness.

_Upper Respiratory Tract_

The pathological changes found in the nose, pharynx and larynx were of relatively slight importance and most variable in their severity and incidence. The majority of individuals had few clinical manifestations of disease in these parts. Some, however, complained of dryness of the pharynx with slight feeling of fullness. An examination of these parts revealed some congestion, varying from a red injected mucosa to a bluish cyanosis. In the nose the reaction was rarely as acute as is seen in infectious coryza, but even where relatively little change was to be seen in the tissues hemorrhage from the erectile tissue was not uncommon during the acute stages. No particular lesion was to be found associated with nose bleed. There was an unusual absence of excessive secretion from nose and pharynx in the majority of cases. One was also struck with the infrequency with which the larynx was involved. A certain number of individuals complained of hoarseness, and in them injection of the vocal cords with some swelling was found. In many others, however, even where an intense infectious process was present in the lower respiratory tract the larynx was almost without change. It was from the level below the larynx that the acute reaction in the respiratory system was found.

In all of our cases the trachea showed definite inflammatory reaction. Of the 32 cases there were 26 having an acute tracheitis, 5 with an acute mucopurulent inflammation and 1 with a reaction in the subacute stage. In the majority of the cases with acute tracheitis there was a thin layer of exudate lying upon the mucosal surface. At times the trachea was filled with a frothy serous fluid, the greater part of which had its origin in the lung. Nevertheless, as we shall point out later, we did obtain microscopical evidence indicating that during the early acute stage of the tracheitis a considerable serous exudate escapes from its mucosa. This serous inflammatory reaction is an important one for all of the mucosal structures upon which the virus of influenza obtains a footing. This we have found true for the trachea, bronchi and alveoli of the lungs. In some cases the exudate was grey and lay in close contact with the injected tissues. At first sight this grey exudate suggested necrosis, but it was readily wiped from the underlying structure. Some leucocytes and cell debris with many bacteria made up the content of this grey exudate.

The macroscopic appearance of the trachea was that of an intensely injected structure which had largely lost its normal lustre. The naked eye could distinguish that anatomical change had occurred in the surface tissue of the trachea and that there was unusual evidence of intensely injected vessels lying in the submucosa. In only one instance was there an appearance of a true necrotic membrane lying upon the surface of this intensely inflamed layer. This apparent membrane was found to consist of a wide patch of desquamated epithelial cells which was lying as a delicate necrotic plate upon the surface. This thin layer was devoid of a meshwork of fibrin threads as usually accompanies a true false membrane of other sources.

The early intense inflammatory reaction of the surface membrane of the trachea was characteristic, and in our experience was never exceeded in intensity by other infections. A desquamation of the lining membrane was also a common finding. Naturally this intense reaction so commonly found in the trachea extended without interruption into the main bronchi and their divisions. The finding of this continuous surface inflammation is good evidence of the mode of spread of the infectious process along these membranes, beginning in the upper portions and by direct continuity involving more and more of the respiratory tubes toward the lung.

The varying grades in the intensity of the inflammatory reaction upon the inner surface of the trachea was well illustrated in the microscopic sections. Even with the different degrees of the reaction there was a fairly constant character to the inflammation. In this way the response was found to differ from that commonly observed in ordinary infections of the respiratory tract. The first striking feature is the marked response of the vascular channels, both blood and lymphatic. The vessels lying in the submucosa were found intensely engorged so that their walls were stretched to the point of bursting. In fact, not a few vessels were seen whose walls, probably under the stress of intoxication and dilatation, had given way leading to a flooding of the neighboring tissue with their contents. Where such vessels lay close underneath the surface the hemorrhage escaped into the lumen of the trachea. Accompanying this early vascular response there was found a marked serous exudate leading to a stretching of the submucosal tissues by distention of the interstitial spaces. This reaction resembled an acute inflammatory œdema and occupied the area between the mucosa and the inner border of the cartilage rings. Beyond this region no response was found. Thus in the earliest stages, and where the mucosa was still intact, the main reaction was of the nature of an intense serous inflammation with congestion of the blood vessels and frequent interstitial hemorrhages.

Shortly following the development of the serous exudate in the submucosal tissues, the epithelial lining is found to suffer from the reaction. The serous exudate does not remain confined to the interstitial tissues, but is poured out through the mucosa into the trachea. It would appear that the amount of this clear exudate may become greater than can be dealt with by the mucosa, with the result that an accumulation of this serous fluid takes place between this epithelial layer and its basement membrane. We have repeatedly seen considerable stretches of the mucosa lifted from the basement membrane and shed in large plaques into the lumen. These mucosal cells at the time of their desquamation retain fairly well their morphological characters, and do not show evidence of necrosis prior to their removal. Disintegration of these cells naturally occurs while lying in the secretion of the trachea, and a variable cellular mass in stages of disintegration may often be found both in smears and sections. When the epithelial cells are lifted in wide plates, a type of bleb develops which is easily broken and then disintegrates.

The desquamation of the lining membrane is a fairly constant occurrence in the cases coming to autopsy. In the majority of those which we have examined the greater portion of the trachea was completely denuded, save for small islands lying in the recesses near the mouths of the mucous ducts. In one case this lesion was accompanied by a process of ulceration, due in all probability to the invasion by other micro-organisms. The denuded tracheal surface usually shows a further inflammatory reaction in which a cellular exudate then makes its appearance. This reaction is mainly one in which lymphocytes and plasma cells infiltrate the spaces previously occupied by the serous fluid. The reaction is limited to the submucosa and does not extend into the tissues beyond the cartilages. We have found only occasional polymorphonuclear leucocytes lying close below the surface. During this period, however, varying grades of degeneration may occupy the upper layers. The basement membrane particularly seems to suffer by losing its characteristic outline and staining qualities. This membrane becomes swollen, softened and indefinite. At times a homogeneous precipitate occurs along its free surface giving rise to an appearance resembling a false membrane. This deposit is, however, distinctively different from the diphtheritic membrane of other infections. It is interesting, however, that where such deposits and degeneration occur in the basement membrane more or less degeneration and necrosis also occur in the connective tissues immediately neighboring to it. These tissues show a peculiar granular destruction and alter their staining qualities. Moreover, and what is more important, under these conditions the dilated blood vessels are found to suffer from the injuries taking place in their neighborhood. We have repeatedly found partially or completely thrombosed capillaries, arterioles and venules in these surface layers. These thromboses took place while the vessel was in its distended state and thus produced a mold of the dilated vessel. This observation is of importance in indicating the severity of the effect of the virus and toxin upon the tissues of the trachea, and it is also of importance to appreciate that this damaging influence is very different from that which we encounter in pneumococcus infections, and we shall point out in our discussion on lung a reaction very similar to that which takes place very superficially in the trachea may also occur in the alveolar walls of the lung.

Having referred to the intensity of the responses of the blood vascular system, we must also indicate the part played by the lymphatics. Simultaneously with the reactions taking place about the blood vessels of the trachea we observed similar responses in the lymphatic channels. At first these dilated structures contained only fluid. Later the migration of the lymphocytes took place along these routes, and rarely micro-organisms could be demonstrated either free or within an occasional leucocyte. The sharp response of the lymphatics during the serous inflammation is noteworthy, inasmuch as we have found that the lymph glands lying about the respiratory tubes and lungs were early in their response to the irritating virus.

Bacteria were demonstrated in the secretions lying upon the surface of the trachea. In those specimens in which the mucous membrane was still intact we attempted to demonstrate the clustering of the micro-organisms about the ciliated cells as was described by Mallory in whooping cough. Although the organisms, and particularly small Gram negative bacilli, could be demonstrated lying about these cells no characteristic arrangement was found. Furthermore where the mucosa was still attached to its basement membrane we were never able to demonstrate organisms below the surface of the epithelial layer. In several cases where the mucosa was lifted in bleb-like structures a number of organisms were detected below the epithelial layer and in contact with the basement membrane of the submucosa. We have rarely demonstrated bacteria in the interstitial spaces of the submucosa, even where large numbers of organisms were lying upon the inner denuded surface.

The distinction which was made by the gross examination of the trachea between the acute tracheitis with serous exudate, subacute tracheitis and mucopurulent tracheitis was not so readily distinguished in the microscopic sections. In the gross the character of the exudate lying upon the surface was the main guide suggesting the nature and intensity of the inflammatory reaction. In the microscopic sections this exudate was largely wanting, or was not sufficiently characteristic to confirm the gross findings. On the other hand, differences in the nature of the injury were to be found mainly in the reaction of the submucosa. As we have indicated above, the early inflammatory reaction of the trachea is mainly evident in an intense congestion accompanied by an inflammatory œdema of the submucosal tissues, hemorrhage sometimes accompanying this response. In the later stages of the reaction a cellular deposit takes the place of the inflammatory œdema and usually consists of lymphocytes and plasma cells. It is only in those cases where the intensity of the irritant continues to act over a longer period of time that a superficial necrosis with leucocytic infiltration makes its appearance. The epithelial layer of the trachea is desquamated early in the acute reaction, and hence a denudation of the surface is to be found in all stages of the acute lesion. The mucous glands have not been found to show any particular involvement in the inflammatory process, and in the majority of instances they were found to have escaped entirely the damaging effect of the virus. Their response in an over-secretion of mucus may be the outcome of a stimulation by toxins or soluble irritants; but on the other hand, may also probably be a reflex response to the injury of the mucosal surface, which being bared of its covering is highly sensitive. The increased discharge of mucus from the deep glands may well be a protective response to such injury.

_Bronchi_

The lesions in the bronchi were in every way comparable to those in the trachea. The main bronchial tubes differ in no material way from the structure of the trachea, and the extension of the inflammatory process from above downwards leads to a reaction in their walls similar to what has been above described. As we follow the subdivisions of the bronchi we gradually lose some of the characteristics contained in the larger tubes. The mucous glands gradually become fewer and eventually disappear. The cartilage rings become smaller and no longer completely encircle the bronchus, and with the further diminution in the size of these structures disappear entirely. A relatively greater amount of muscle tissues takes the place of the cartilage rings. This change in the anatomy of these structures has a certain influence in modifying the character and distribution of the inflammation.

TABLE V

BRONCHITIS AND TRACHEITIS

═════════════════════════════════════ Acute bronchitis and tracheitis 26 Subacute bronchitis and tracheitis 1 Acute mucopurulent tracheitis 5 Acute purulent bronchitis 2 Acute mucopurulent bronchitis 7 Ulcers of trachea 1 Acute bronchiectasis 1 ─────────────────────────────────────