Using the Rebuck skin window technique, which was to remain the standard for many years, Perillie et al. (6) studied polymorphonuclear leukocyte (PMN) chemotaxis in ten patients with well-controlled diabetes, six patients with diabetic ketoacidosis, four patients with nondiabetic uremic acidosis, and ten healthy controls. An abrasion was created on the volar forearm, and sterile coverslips were serially applied over the next several hours. Mobilization of PMNs to the area of inflammation was graded by microscopic examination of the coverslip after staining. The PMNs of all acidotic patients had a diminished early (24 hour) response. This response time became normal in the four patients with diabetes whose acidosis was corrected. In an ambitious analysis of leukocyte function, Brayton et al. (7) examined chemotaxis with use of a modified Rebuck technique in 18 patients with fairly well-controlled diabetes, five of whom were acidotic at the time of study. At 2 and 4 hours, mobilization of the PMNs of all diabetic subjects was diminished. However, at later time points, no differences were seen between the mobilization responses of the PMNs of diabetic subjects and those of healthy controls. The PMNs of acidotic uremic patients had a chemotactic response similar to that of controls at all time points.

Mowat and Baum (8), in an in vitro study using a modified tissue-culture chamber, studied chemotaxis of PMNs from 31 diabetic patients with various degrees of glycemic control. A chemotactic index was derived by comparing the original number of PMNs with the number that had completely crossed a filter barrier in response to chemoattractants. The PMNs of all patients with diabetes had a lower chemotactic index (i.e., diminished response), without any correlation between chemotactic index and type of therapy or fasting blood glucose levels. Incubation of the PMNs from 11 controls with glucose at concentrations of 100 to 900 mg/dL did not change the chemotactic index of the PMNs. Incubation of the PMNs of diabetic patients with insulin at concentrations of 10 to 100 μU/mL improved the chemotactic index of PMNs of the diabetic patients if glucose was also present. Molenaar et al. (9) used a bacterial factor from Escherichia coli as a chemoattractant and found a lower chemotactic index for the PMNs of 52 first-degree relatives of 15 patients with diabetes as compared with the chemotactic index for the PMNs of controls. Not all the subjects with diabetes had PMNs with a depressed chemotactic index, but the average chemotactic index was lower than that for the PMNs of their relatives. A later study (10) that used a similar technique (Boyden modified chamber) with cells washed free of plasma found no difference in the chemotactic index of the PMNs of control subjects and those of patients with insulin-dependent diabetes mellitus (IDDM) with various degrees of glucose control or duration of disease.

Shortly after the above studies were conducted, there was a shift to the subagarose technique for assaying chemotaxis. This technique yielded more reproducible results and corrected for chemokinetic movement. Measurements are made of the migration from a center well in an agarose plate toward a chemoattractant (zymogen-activated plasma) and of random migration toward a control well. With this technique, the average chemotactic index of the PMNs of 58 patients with diabetes was found to be depressed (11). Chemically defined chemotactic activity of PMNs under agarose was investigated by Naghibi et al. (12) for 26 patients receiving oral hyperglycemic agents, daily insulin injections, or continuous insulin infusion before an intensive control regimen and in 11 of these patients after institution of the intensive regimen. Chemotaxis of the PMNs of all groups was comparable to that of control PMNs.

Bybee and Rogers (13) studied leukocyte phagocytosis in 31 patients with well-controlled diabetes, seven patients with diabetic acidosis, and a control group. Washed PMNs and an equal number of Staphylococcus aureus or Staphylococcus epidermidis were incubated together for 60 minutes in 10% human serum. Phagocytosis was considered to be present if at least one bacterium was ingested. There was no quantitation of the number of organisms engulfed per cell. Only the PMNs of ketotic diabetic patients were found to exhibit diminished phagocytosis. This defect was corrected if acidosis was reversed but not if the cells were incubated with normal serum. Control PMNs functioned normally if they were incubated with serum from acidotic diabetic patients. However, serum factors may have been diluted out, given that a 10% concentration of serum was used.

Bagdade et al. (14) used a similar system, but with 90% serum, to examine phagocytosis of Streptococcus pneumoniae type 25 by leukocytes from eight patients who were not acidotic but had poorly controlled diabetes. Decreased phagocytosis was especially notable when fasting blood glucose levels were higher than 250 mg/dL. After the patients’ glucose levels were controlled, phagocytic activity improved but did not attain control values. In contrast to the findings of Bybee and Rogers (13), the activity of control PMNs was diminished when the cells were incubated with serum from patients with diabetes, whereas the activity of PMNs from patients with diabetes was increased when the cells were incubated with normal serum. The work of Rayfield et al. (15) supported the possibility of an opsonization defect affecting PMNs of individuals with diabetes. Normal PMNs had decreased uptake of radiolabeled E. coli or S. aureus in the presence of serum from patients with diabetes.

Using the lysostaphin assay technique, which allows differentiation between phagocytosis and intracellular killing, Tan et al. (16) demonstrated a defect in phagocytosis of S. aureus by the PMNs of 31 patients with adult-onset diabetes. The presence of the defect showed no correlation with level of glycemic control or history of recurrent infections. The addition of normal serum had no effect. Using shorter observation periods, Nolan et al. (17) found that PMNs from 17 patients with poorly controlled diabetes ingested a smaller proportion of an inoculum of 10⁶ S. aureus after 20 minutes (the interval during which most engulfment takes place under normal physiologic conditions) than did control PMNs. This difference vanished at 60 minutes. Davidson et al. (18) measured engulfment of Candida guilliermondii over a 45-minute period by PMNs from 11 patients with moderately well-controlled diabetes. The ratio of white cells to organisms was such that 90% of the control cells
would have ingested at least one yeast cell in 30 minutes. Phagocytosis was diminished in the PMNs of the patients with diabetes, regardless of levels of glycosylated hemoglobin 1C (HbA_1c). A defect in opsonization was suggested, since preopsonized yeast particles added to serum from diabetic patients with PMNs from control subjects were engulfed at normal levels. Alexiewicz et al. (19) demonstrated impaired phagocytic ability of PMNs from patients with newly diagnosed, non-IDDM, which correlated inversely with fasting serum glucose level. Both phagocytosis and glucose control improved significantly after 3 months of therapy with glyburide. The authors also demonstrated an inverse relationship between cytosolic calcium concentrations in PMNs and phagocytic function and postulated that the functional defect may relate to the high calcium levels.

Comparatively few papers have specifically addressed the question of adherence by the leukocytes of patients with diabetes. Peterson et al. (20) found that the PMNs of six of seven patients with poorly controlled diabetes exhibited impaired adherence to a glass-wool column. Adherence improved 1 to 2 months later when glycemic control had improved. However, no control patients were examined. Bagdade et al. (21) showed an enhancement of adherence of PMNs to a nylon-fiber column following an improvement in the control of blood glucose levels. Adherence increased from 53% to 74% of control values. In another study, Bagdade and Walters (22) demonstrated a direct relationship between degree of glucose control and PMN adherence.

Andersen et al. (23) pointed the study of adhesion in a dramatic new direction by devising a more physiologic system. Noting that vascular endothelium is not a passive participant in the inflammation cascade, they examined the ability of PMNs from 26 patients with diabetes and from age-matched controls to bind to bovine aortic endothelium. The PMNs of 60% of the patients with diabetes had severely depressed function that did not correlate with HbA_1c levels. PMN-PMN aggregation was not defective. No quantitative defect in fibronectin was seen, but a qualitative defect could not be excluded.

Early studies, such as that of Dziatkowiak et al. (24), compared the number of live S. aureus bacteria in a granulocyte with the total number engulfed to calculate the proportion of organisms killed. Several studies (16) demonstrated diminished killing by the PMNs of patients with diabetes while others did not. Repine et al. (25) took a more quantitative and functional approach. Instead of using a single low ratio of bacteria to PMNs, they used five different ratios (1:1 to 100:1). Study patients included infected and noninfected individuals with and without diabetes. Cells were incubated with S. aureus for 1 hour, after which colonies were counted. The rates of intracellular killing of bacteria by PMNs from uninfected controls and by PMNs of persons with well-controlled diabetes were comparable. PMNs from uninfected patients with poorly controlled diabetes functioned less well, especially when the higher ratios of bacteria to white cells were used. Although the functioning of PMNs from infected patients with well-controlled diabetes was on a par with the functioning of those from uninfected controls, the PMNs from the infected patients with diabetes did not display the increase in killing activity seen in the PMNs of infected patients without diabetes. The bactericidal function of PMNs from infected patients with poorly controlled diabetes was the lowest of all the groups. Naghibi et al. (12), using a single low ratio of bacteria to PMNs, found depressed bactericidal function of the PMNs of patients against Pseudomonas aeruginosa, but they did not study any infected patients. Serum from patients with diabetes had an inhibitory effect on PMNs from both normal controls and diabetic subjects before and after intensive glucose management. Bactericidal activity of PMNs from the patients with diabetes remained depressed even after intensive management.

Stimulated PMNs display a burst of oxidative metabolism that produces superoxide anions and other oxygen-derived species implicated in bacterial killing. These reactions produce chemiluminescence, a sensitive indicator of oxidative metabolism that correlates with antimicrobial activity. Shah et al. (26) looked at the production of superoxide anion and chemiluminescence of PMNs from patients with diabetes, examining the cells in both the resting state and in response to soluble and particulate stimuli. In resting PMNs from patients with diabetes, the chemiluminescence of cells placed in serum from patients with diabetes was comparable to that of cells placed in control serum. Superoxide production was higher in autologous serum from patients with diabetes than in normal serum. The significance of these findings taken together was unclear. When stimulated, the PMNs from patients with diabetes showed a blunted response with regard to both superoxide production and chemiluminescence. Cross-incubation serum studies effected no change, suggesting that an intracellular defect rather than an inhibitory serum factor might have been present. The precise role of defective in vitro bactericidal activity of PMNs, associated with impaired superoxide production, as a predisposing factor for infection is uncertain, however. Such defects can be demonstrated in patients with diabetes who have not been subject to recurrent or particularly serious infections (27).

Sato et al. (28) reported improvement in chemoluminescence measurements related to O₂^– and OCl^– production by PMNs of patients with diabetes after 4 weeks of therapy with an aldose reductase inhibitor, although levels did not reach those of PMNs from healthy controls. This observation could not be attributed to improvement in glucose control, as both the postprandial glucose and HbA_1c levels were unchanged. It has been suggested that advanced glycation products associated with diabetes may bind to specific motifs common to lactoferrin, lysozyme, and other antimicrobial proteins found in PMNs and interfere with the antimicrobial function of these host defense molecules (29).

The PMNs of patients with diabetes have shown a decreased prostaglandin E and thromboxane B₂ response to stimulation by zymosan or killed S. aureus (30). The synthesis and release of leukotriene B₄ by these cells also were diminished compared with those of the PMNs of sex- and age-matched controls (31). The significance of these findings is not known.

The term mucormycosis connotes a variety of infections caused by fungi belonging to the order Mucorales, members of the class Zygomycetes (54,55). Zygomycosis and phycomycosis are synonyms that have been rendered obsolete by ongoing reclassification. Rhizopus species (especially Rhizopus oryzae and Rhizopus arrhizus) are the most commonly isolated pathogens, followed by Mucor organisms. Cunninghamella (56) and other species have also been found to cause disease. These molds produce large, thick-walled, nonseptate hyphae that branch at more-or-less right angles. Ubiquitous in the environment, these organisms are most often found in decaying matter. Humans commonly inhale the spores, which have a low virulence potential. The ability of the spores to germinate successfully is dependent on specific host factors. Most information regarding pathogenesis comes from studies in rabbit and mouse models. After inhalation of spores, normal animals do not become ill, whereas diabetic animals develop a rapidly progressive pulmonary disease (57). Alveolar macrophages from normal mice, but not those from diabetic mice, will ingest the spores and inhibit their germination into the invasive hyphal forms. Experimentally, neither hyperglycemia nor metabolic acidosis alone is sufficient to permit infection (58), despite the propensity for the development of certain mucormycosis syndromes among acidotic patients with diabetes. In contrast to normal human serum, the serum of patients with diabetes with ketoacidosis does not inhibit the growth of R. oryzae (59). It has been proposed that acidosis disrupts the ability of transferrin to bind iron, a deficiency that results in the release of free iron into the serum and perhaps to an interference in the host defenses against Rhizopus (60), an iron-requiring organism (61). Credence has been lent to the proposed role of iron regulation in host defense by the increasing recognition of the occurrence of deferoxamine-associated mucormycosis in patients undergoing dialysis. In this situation, it appears that Rhizopus organisms may be able to use the iron mobilized by the chelating agent, a capability that has been demonstrated in other organisms (61).

Mucormycosis may present as a rhinocerebral, pulmonary, cutaneous, gastrointestinal, or disseminated form of the disease. Rhinocerebral mucormycosis was first recognized more than 50 years ago (62). It occurs primarily in persons with diabetes, although other immunocompromised patients may be affected, and is one of the most fulminant forms of fungal disease affecting that population. The typical patient presents with ketoacidosis. Fungal elements gain entry through the nasopharynx, where tissue invasion may result in nasal discharge that may be tinged with blood. Close inspection of the infected region may reveal necrotic areas with black eschar involving the nasal mucosa or hard palate. The patient is likely to have a fever and to remain lethargic even after metabolic derangements have been corrected. Commonly, by the time the diagnosis is suspected, headache and/or facial pain already reflect extension of the process into the paranasal sinuses and possibly into the orbit of the eye. Occasional patients present with a dramatic, rapid onset of ocular proptosis and vision loss caused by invasion of the orbit. Rapid progression of clinical findings is the result of invasion of blood vessels, with vascular occlusion and subsequent necrosis of tissues dependent on the affected vessels. Progression of thrombosis can include the cavernous sinus (63)
and the internal carotid artery (64). Invasion of the brain results in meningoencephalitis and/or abscess formation with deterioration of neurologic function.

Progression usually occurs over a matter of hours to days and is invariably fatal if the patient is not treated early. Diagnosis must be established by demonstration of characteristic invasion of tissues by hyphal elements in biopsy specimens. A careful search for evidence of vascular invasion must be conducted. Culture results will often be negative. Spinal fluid findings are nonspecific (65). Sinus films may show mucosal thickening and clouding with some spotty destruction of the orbit (66). Computed tomography (CT) scans, with special orbital views, can help define the extent of involvement, although the extent estimated by this method may underestimate the actual extent of involvement determined at surgery (67). Angiography has been used to define the degree of large-vessel involvement. Magnetic resonance imaging offers the potential to provide useful information on the extent of infection, including assessment of soft tissue and vascular structures. Extension beyond the orbit carries a poor prognosis.

Aggressive surgical management is mandatory in all situations; radical debridement sometimes necessitates orbital exenteration. Repeated debridement may be necessary. Concomitantly, underlying metabolic disorders must be addressed. Amphotericin B remains the standard antifungal therapy and must be used in conjunction with surgery (54,68,69). Aggressive antifungal therapy should be used, and although the exact duration of treatment and the total dosage administered have not been well defined, it is reasonable to aim for a total dosage of at least 2 g. The currently approved azole antifungal agents have no defined role in therapy (70). Repeated imaging is necessary to follow the response to treatment, and repeated biopsy may be necessary (71). With optimal therapy, mortality remains at 50%, despite some reports of more encouraging results (72). The nature of the almost universal neurologic residua depends on the anatomic structures that have already been compromised by the time the infection is brought under control.

The remaining forms of mucormycosis do not have a predilection for a specific host, although the pulmonary disease may have a distinctive presentation in patients with diabetes. In contrast to the fatal pneumonia and extensive thrombosis that is typical in immunocompromised patients, diabetic patients have been noted to develop endobronchial and large-airway lesions that may follow a less fulminant course. The main complication of pulmonary mucormycosis is massive hemoptysis. Lesions may respond to aggressive local resection in combination with intravenous therapy with amphotericin B (73,74,75,76).