The sequelæ after exposure to gas may be markedly delayed. They occur, not only in animals which have exhibited characteristic acute symptoms, but also, and especially with phosgene, where no serious immediate clinical effects followed exposure to the gases. They are dependent upon the fact that the pneumonic process has a very striking tendency to undergo organization, a process which involves not only the exudate in the alveoli, but also that within the bronchioles. The organizing process may be present in both these portions of the lung or may be confined to the bronchiole alone, and lead to a progressive interference with the ingress and egress of alveolar air, so that atelectasis and emphysema become permanent, and in turn lead to narrowing of the vascular bed, ultimately producing right-sided cardiac decompensation. Bronchiectases also occur; they may be tubular, associated with organization of the pneumonic process in their vicinity, or saccular if death has not followed the destruction of the bronchiolar wall.
Compare this picture with that of influenzal pneumonia and its sequelæ; in both there is, first the acute diffuse involvement of the lung, initiated by, or occurring simultaneously with, an acute tracheobronchitis and presenting clinically dyspnœa, cyanosis, blood-stained, abundant sputum, and even interstitial emphysema; next, the tendency for the pneumonic process to localize and to necrotize; and finally, if the acute period is survived, organization of the pneumonic and bronchiolar exudates with resulting bronchiolitis and bronchiectasis. With even more minute comparison, the resemblance is sustained. The initial or early dilatation of the ducti alveolares, so characteristic in gas poisoning, also occupies the foreground of the histological picture in influenza. These dilated structures are the more prominent on account of the red, ribbon-like strands that cover the surface and often involve the walls. Similar necrotization, varying in its depth even to involve the whole of the alveolar walls, occurs in both of these conditions. Similar hemorrhages in the early stage, rupture of the alveolar wall with interstitial and subcutaneous emphysema, necrotization, gangrene, and organization in the same localities, characterize the two lesions, and are not found with the same uniformity in any other type of respiratory disease.
D. THE IMPORTANCE OF THE TRACHEA AND ITS RAMIFICATIONS AS A PROTECTIVE MECHANISM AGAINST INFECTION OF THE PULMONARY PARENCHYMA
In gas poisoning it has been demonstrated that the initial damage to the epithelium of the larger air passages is followed by an invasion of the pulmonary parenchyma by the bacteria of the mouth. Repeated cultures from the mouth before the exposure of the animal to gas have been followed by the recovery of the same organisms, including the pneumococci, the streptococci, the staphylococci, and a gram-negative, hemoglobinophilic, small bacillus from the pneumonic lung. They find their way into the lung after the destruction or incapacitation of the protective mechanism (70) of the upper respiratory tract,—into a lung which has been so damaged by the irritative gas that bacteria innocuous in the normal pharynx now find a favorable medium for their development. The inflammatory reaction which develops into pneumonia, perhaps necrotizing, perhaps later organizing, can only be explained by the combined action of the corrosive gas and the organisms saprophytic in the normal mouth, but now pathogenic in varying degrees in the lung whose vital reactions have either been inhibited or impaired by the gas.
FIG. XL. AUTOPSY NO. 140. LEFT LUNG. THE HISTOLOGY OF THE PULMONARY CHANGES IN THIS CASE IS ILLUSTRATED IN FIGURES [XI], [XLI], AND [XLIV]. THESE PROCESSES, ILLUSTRATED IN FIGURE [XXXIX], ARE ACCENTUATED AND THERE IS ALSO AN ORGANIZATION OF THE EXTENSIVE PURULENT PLEURISY TO BE MADE OUT IN THE ABOVE FIGURE.
There is no reason why this analogy should not be drawn, no reason why we should not consider that the unknown etiological agent in influenza produces a similar injury to, or even destruction of, the protective mechanism of the respiratory tract. Similarly, gas and influenza damage the pulmonary parenchyma itself, so that the bacteria of the air and of the mouth which find their way into the damaged lung[[16]] initiate processes and produce complications which may not be distinguished.
V. PECULIARITIES OF THE HISTOLOGY OF INFLUENZAL PNEUMONIA
A. THE EXTENT OF THE INITIAL PULMONARY LESION
One of the features differentiating the pneumonic process in influenza from the usual types of inflammation of the lung, is diffuseness (90). In the early cases especially, or in cases which terminate fatally at an early period, both lungs are often involved, and, on histological examination, only a small portion of the pulmonary parenchyma is found unaffected. The exudate, largely acellular, presents serum as its most conspicuous feature. The picture is one of a patchy pneumonia with intermediary areas of what might be called edema, although fibrin is often demonstrable in the coagulated, albuminous material. So little attention has been paid to earlier stages of the usual types of pneumonia, for example lobar, that it is impossible to say whether or not diffuse involvement of the pulmonary parenchyma initiates the process which later becomes localized in one or more lobes. The initial edema of influenzal pneumonia is the expression of a widespread irritation. If the injury has not extended deeply, the edema may disappear within a relatively short time, and exfoliated lining cells fill the alveoli; those remaining in their normal position are frequently in process of division (Fig. [XLVII]). It is conceivable—and the view has already been announced—that this edema is a disseminating factor and perhaps responsible for the diffuseness of the pneumonic process which may follow. If the fluid is simply a serous exudate, it may play no essential rôle in the severe acute symptoms manifested by these patients, for it has been shown, both in the experimental lesions induced by pulmonary irritating gases and by pulmonary irrigation through which extensive artificial edema of the lungs may be attained, that the presence of fluid in the lung in itself is not harmful (161).