Low level of immunity for SARS-CoV among well healthcare workers reinforces the need for infection control measures in hospitals to prevent epidemics.
To determine the prevalence of inapparent infection with severe acute respiratory syndrome (SARS) among healthcare workers, we performed a serosurvey to test for immunoglobulin (Ig) G antibodies to the SARS coronavirus (SARS-CoV) among 1,147 healthcare workers in 3 hospitals that admitted SARS patients in mid-May 2003. Among them were 90 healthcare workers with SARS. As a reference group, 709 healthcare workers who worked in 2 hospitals that never admitted any SARS patients were similarly tested. The seroprevalence rate was 88.9% (80/90) for healthcare workers with SARS and 1.4% (15/1,057) for healthcare workers who were apparently healthy. The seroprevalence in the reference group was 0.4% (3/709). These findings suggest that inapparent infection is uncommon. Low level of immunity among unaffected healthcare workers reinforces the need for adequate personal protection and other infection control measures in hospitals to prevent future epidemics.
On January 2, 2003, a patient was admitted to the Traditional Medicine Hospital, Guangdong Province, with fever, cough, decreased leukocyte count, and abnormal chest radiographs. Shortly after the patient was admitted, 7 healthcare workers who cared for him became ill with similar symptoms. This index patient was retrospectively confirmed to be the first patient with severe acute respiratory syndrome (SARS) in Guangzhou (
In most cases, the disease was spread through close contact with an infected person (
In mid-May 2003, ≈4 months after the initial SARS outbreak in Guangzhou, a cross-sectional survey was carried out on healthcare workers who worked with SARS patients in the First, Second ,and Third Affiliated Hospitals of the Sun Yat-Sen University, Guangzhou. Outbreaks of SARS had occurred among healthcare workers in the Second and Third Affiliated Hospitals but not the First Affiliated Hospital. Of the 1,394 healthcare workers who cared for SARS patients in these 3 hospitals, 1,147 (82.3%) were surveyed. Those surveyed included healthcare workers from all departments that cared for SARS patients. All healthcare workers on duty were surveyed; only those who were off-duty during the survey were excluded.
For comparison, 709 healthcare workers were sampled from 2 hospitals with no SARS patients: the Affiliated Cancer Hospital, Guangzhou, where no SARS patients were admitted, and the Fifth Affiliated Hospital, Zhuhai, where no SARS cases were reported in the community. A total of 1,856 healthcare workers were surveyed.
For each healthcare worker, 10 mL of peripheral venous blood was collected; the serum was separated and stored at –70°C. A standardized interview with a structured questionnaire was used to obtain information on sociodemographic characteristics and the history of SARS according to a case definition of SARS by the Ministry of Health, China (
A probable case-patient was defined as one who had close contact with a patient, was a member of an infected cluster, or infected other persons; had symptoms and signs of febrile respiratory symptoms, and had changes on chest radiograph. A patient was also considered to have a probable case if he or she visited or lived in an area where SARS was reported with secondary transmission within 2 weeks of illness onset, had symptoms and signs of febrile respiratory illness, had normal or decreased leukocyte count, and had changes on chest radiograph.
A suspected case-patient was defined as one who had close contact with a patient; was a member of an infected cluster, or infected other persons; and had symptoms and signs of febrile respiratory illness; and had normal or decreased leukocyte count. A patient was also considered to have a suspected case if he or she visited or lived in an area where SARS was reported with secondary transmission within 2 weeks of illness onset, had symptoms and signs of febrile respiratory illness, and had changes on chest radiograph. If a patient had no epidemiologic link to SARS but he or she had symptoms and signs of febrile respiratory illness, normal or decreased leukocyte count, and changes on chest radiograph, he or she was still considered to have a suspected case.
A person who had visited or lived in cities where SARS cases were reported with secondary transmission was placed under medical observation if he or she had symptoms and signs of febrile respiratory illness and had a normal or decreased leukocyte count.
Immunoglobulin (Ig) G against SARS-CoV were detected by enzyme-linked immunosorbent assay (ELISA) according to the manufacturer’s instructions (Beijing BGI-GBI Biotech Co., Ltd.) (
Means and standard deviations were used to describe continuous variables. Proportions and prevalence rates were used to describe categorical variables. Chi-square tests were performed to test the association between SARS-CoV IgG seropositivity and the sociodemographic characteristics of the healthcare workers.
The mean age of the healthcare workers investigated was 30.78 years (SD 9.1 years); 71.6% were women. Details of their sociodemographic characteristics are presented in
| Sociodemographic characteristic | No. participants (%) |
|---|---|
| Hospital* | |
| First Affiliated Hospital | 389 (21.0) |
| Second Affiliated Hospital | 361 (19.5) |
| Third Affiliated Hospital | 397 (21.4) |
| Affiliated Cancer Hospital | 371 (20.0) |
| Fifth Affiliated Hospital | 338 (18.1) |
| Age (y) | |
| <26 | 676 (36.5) |
| 26–30 | 404 (21.8) |
| 31–35 | 294 (15.8) |
| 36–40 | 221 (11.9) |
| >40 | 261 (13.0) |
| Sex | |
| Male | 528 (28.4) |
| Female | 1,328 (71.6) |
| Educational level | |
| Senior school | 136 (7.3) |
| Technical secondary school | 718 (38.7) |
| Junior college | 367 (19.8) |
| University | 333 (17.9) |
| MD/PhD | 302 (16.3) |
| Department | |
| SARS ward | 413 (22.3) |
| Emergency department/fever clinic | 196 (10.6) |
| Infectious disease department | 125 (6.7) |
| Respiratory diseases department | 101 (5.4) |
| ICU | 61 (3.3) |
| X-ray | 74 (4.0) |
| Laboratory | 66 (3.6) |
| Others† | 820 (44.2) |
| Job title‡ | |
| Doctor | 567 (30.7) |
| Nurse | 892 (48.3) |
| Health attendant | 101 (5.5) |
| Technician in laboratory | 74 (4.0) |
| Others | 213 (11.5) |
*All 5 hospitals are teaching hospitals of the Sun Yat-Sen University. †Departments of internal medicine, surgery, and logistic service. ‡Missing for 9 healthcare workers.
| SARS-related information | First Affiliated Hospital | Second Affiliated Hospital | Third Affiliated Hospital | Affiliated Cancer Hospital | Fifth Affiliated Hospital |
|---|---|---|---|---|---|
| In SARS-epidemic area? | Yes | Yes | Yes | Yes | No |
| No. healthcare workers exposed to SARS* | 548 | 421 | 425 | 0 | 0 |
| No. healthcare workers surveyed | 389 | 361 | 397 | 371 | 338 |
| No. days when SARS patients were in the hospital | 120 | 110 | 102 | 0 | 0 |
| No. probable SARS patients cared for | 122 | 150 | 31 | 0 | 0 |
| No. suspected SARS patients cared for | 102 | 50 | 30 | 3 | 0 |
| No. SARS patients who required tracheal intubation | 10 | 0 | 1 | 0 | 0 |
| No. SARS patients who required tracheotomy | 0 | 1 | 2 | 0 | 0 |
| Cared for the index patient?† | No | Yes | Yes | 0 | 0 |
| No. healthcare workers who had SARS‡ in SARS wards | 0 | 80 | 20 | 0 | 0 |
| No. healthcare workers who had from SARS in non-SARS wards | 3 | 10 | 2 | 0 | 0 |
*This refers to healthcare workers caring for SARS patients and laboratory personnel handling specimens from SARS patients. †The index patient was identified as a superspreader who subsequently infected >100 persons (both healthcare workers and other patients and family members in the Second Hospital and Third Hospital). ‡According to the clinical and epidemiologic case definition.
Prevalence of IgG against SARS-CoV among Healthcare Workers
Among healthcare workers working with SARS patients, the prevalence of IgG against SARS-CoV was 88.9% (80/90) for those who contracted SARS and 1.4% (15/1,057) for those who did not (
| Affiliated hospital | Healthcare workers with SARS | Healthcare workers without SARS | ||
|---|---|---|---|---|
| No. participants | No. positive (%) | No. participants | No. positive (%) | |
| First | 0 | 0 | 389 | 4 (1) |
| Second | 73 | 63 (86.3) | 288 | 8 (2.8) |
| Third | 17 | 17 (100) | 380 | 3 (0.8) |
| Cancer | 0 | 0 | 371 | 2 (0.5) |
| Fifth | 0 | 0 | 338 | 1 (0.3) |
| Total/overall percentage | 90 | 80 (88.9) | 1,766 | 18 (1) |
We also compared the prevalence of anti-SARS IgG in healthcare workers for each sociodemographic characteristic. We analyzed the data on healthcare workers who worked with SARS patients in the 3 hospitals. These results are presented in
| Sociodemographic characteristics | No. participants | No. positive for IgG | Prevalence (%) |
|---|---|---|---|
| Age (y)* | |||
| <26 | 355 | 44 | 12.4 |
| 26–30 | 310 | 17 | 5.5 |
| 31–35 | 211 | 14 | 6.6 |
| 36–40 | 118 | 9 | 7.6 |
| >40 | 141 | 11 | 7.8 |
| Sex† | |||
| Male | 306 | 15 | 4.7 |
| Female | 743 | 80 | 9.7 |
| Educational level* | |||
| Senior school | 112 | 14 | 12.5 |
| Technical secondary school | 401 | 42 | 10.5 |
| Junior college | 210 | 11 | 5.2 |
| University | 197 | 17 | 8.6 |
| MD/PhD | 227 | 11 | 4.8 |
| Department‡ | |||
| SARS ward | 409 | 13 | 3.2 |
| Emergency/fever diagnoses | 188 | 4 | 2.1 |
| Infection | 125 | 19 | 15.2 |
| Respiratory | 100 | 36 | 36.0 |
| ICU | 55 | 7 | 12.7 |
| X-ray | 57 | 2 | 3.5 |
| Laboratory | 66 | 0 | 0.0 |
| Others | 147 | 14 | 9.5 |
| Job title† | |||
| Doctor | 388 | 24 | 6.2 |
| Nurse | 510 | 52 | 10.2 |
| Healthcare attendants | 91 | 12 | 13.2 |
| Technician in laboratory | 66 | 0 | 0.0 |
| Others§ | 92 | 7 | 7.6 |
*p < 0.05. †p < 0.01. ‡p < 0.001. §Department of internal medicine, surgery and logistic service.
The results showed that the seroprevalence of anti-SARS IgG in healthcare workers
Anti-SARS IgG can be detected 1–2 weeks after the onset of symptoms. Almost all SARS patients in the convalescent stage had anti-SARS IgG in their serum samples (
The low seroprevalence o SARS IgG (0.3%–2.8%) in healthy healthcare workers with different levels of exposure to SARS patients is similar to that reported by Wang et al. (
The low seroprevalence of SARS IgG, at 1.4% (15/1,057) among apparently healthy frontline healthcare workers in all 3 SARS hospitals, suggests that inapparent infection is relatively uncommon. We did not, however, ascertain whether the healthcare workers with a positive antibody test result were carriers of SARS-CoV. Overall, the low seropositivity among healthy healthcare workers suggests that the level of immunity to SARS in the general population in Guangzhou was too low to constitute an effective immune barrier against the spread of SARS. Should the disease recur there, every effort should be made to protect healthcare workers and the general public from being infected by SARS patients.
The First Affiliated Hospital only admitted SARS patients after outbreaks had occurred among healthcare workers in the Second and Third Affiliated Hospitals. After these outbreaks, a series of protective measures were adopted in all 3 hospitals. Sufficient preparation, such as personal protection and designated SARS wards, is important to avert hospital outbreaks. The low seroprevalence of SARS IgG among healthcare workers working in the First Affiliated Hospital indicated the effectiveness of these measures. This finding is consistent with the study by Chow et al. (
The seroprevalence rates were significantly different among the healthcare workers who cared for SARS patients when classified by their age, sex, educational level, hospital, department, and job title. These differences could be due to the probability of exposure to the SARS index case. On January 30, 2003, the index patient was admitted to the Department of Respiratory Diseases of the Second Affiliated Hospital. On February 1, he was transferred to the Third Affiliated Hospital because of worsening dyspnea. During his stay in these 2 hospitals, where protective measures were lacking, he directly and indirectly infected 90 healthcare workers and 22 healthcare workers in the Second and Third Affiliated Hospitals, respectively. This finding accounts for the much higher seroprevalence of SARS IgG among healthcare workers in the departments of respiratory diseases and infectious diseases. Healthcare workers in SARS wards and fever clinics were fully equipped with personal protective measures (caps, gowns, multilayered cotton face masks, eye shields, gloves, and foot covers), which might explain their much lower seroprevalence. None of our laboratory healthcare workers, who performed serologic tests but not live viral tests, were seropositive, which suggests that the probability of SARS infection by handling serum samples of SARS patients was low. Of all occupations, healthcare attendants had the highest seropositive rate, which might be related to their general lower level of education and a lack of training in infection control measures. Future efforts to improve SARS containment should also address this problem among nonprofessional staff.
This study has several limitations. Even though the response rate among healthcare workers who cared for SARS patients was high (82.3%), some selection bias is inevitable. Moreover, the study was limited to 5 university hospitals, so we caution against the extrapolation of our findings to healthcare workers in other hospitals and to the general population. We have not tested serum samples from our healthcare workers against other pathogens, e.g.,
In conclusion, this study shows that a high proportion of healthcare workers who have contracted SARS have IgG against SARS-CoV in their serum samples after they have fully recovered. Inapparent infection with SARS is uncommon. The low seropositivity against SARS among healthcare workers who have not been exposed to SARS patients suggests a lack of immunity in this group and in the general population, where the number of SARS cases is comparatively small.
We thank Beijing BGI-GBI Biotech Co., Ltd for providing the kits for analyzing the serum IgG against SARS-CoV and the management and healthcare workers in the First, Second, Third, and Fifth Affiliated Hospitals and the Affiliated Cancer Hospital of Sun Yat-Sen University.
This project was supported by a research grant from the Ministry of Science and Technology and the Ministry of Education of China.
Dr. Chen is an associate professor of the department of biostatistics and epidemiology. He is vice dean of the School of Public Health, Sun-Yat Sen University. He has broad research interests in epidemiology and public health, including behavioral epidemiology and SARS.