By conducting a questionnaire survey, this study retrospectively investigated and analyzed the COVID-19-related symptoms, platelet changes, and fear and worry scores of psychological evaluations among the ITP population who were infected with COVID-19 during the period of November 2022 to January 2023. A survey was also conducted on a healthy population as a control group. This study was approved by the Ethics Committee of Xinqiao Hospital, Army Medical University.

The diagnostic criteria for ITP were as follows: (1) blood routine examination conducted at least twice with a platelet count (PC) of less than 100 × 10⁹/L and without abnormal blood cell morphology. (2) Presence or absence of clinical manifestations such as body bruises, skin bleeding, mucosal bleeding, or internal bleeding. (3) Typically, no splenomegaly. (4) Bone marrow examination displaying increased or normal number of megakaryocytes with maturation disorders. (5) Exclusion of other secondary causes of thrombocytopenia, such as inherited or acquired blood disorders, leukemias, myelodysplastic syndromes with isolated thrombocytopenia, or thrombocytopenia associated with other immune disorders or infections (12).

According to Diagnosis and Treatment Plan of SARS-CoV-2 Infection (Trial Version 10 issued by National Health Commission of China), diagnosis was made through a comprehensive analysis of epidemiological history, clinical manifestations, and laboratory tests. The primary criterion for diagnosis was a positive result in nucleic acid testing for the novel coronavirus infection. The diagnostic criteria were as follows: (1) clinical manifestations of COVID-19 infection. (2) Presence of one or more of the following etiological and serological examination results: (1) positive for COVID-19 nucleic acid test; (2) positive for COVID-19 antigen test; (3) positive for COVID-19 virus isolation and culture; (4) acute-phase specific IgG antibody level against COVID-19 in the recovery period is 4 times or more elevated (13).

In this study, ITP patients were further divided into three groups: the patients who did not meet the treatment standards and had not yet started medication, and patients were currently undergoing ITP treatment; and the patients had completed medication and were under observation. The ITP treatment was conducted based on the Chinese ITP guidelines and our center’s experience, including traditional Chinese medicine, glucocorticoids (dexamethasone, prednisone), TPO receptor agonists (TPO-RAs), cyclosporine, rapamycin, etc. (12, 14).

To evaluate psychological status of ITP patients, a questionnaire was designed with reference to the COVID-19 related mental scale (15, 16), including the following items: (1) General conditions: age, sex, education, marital status, course of illness, comorbidities, etc.; (2) COVID-19 infection related Fear Scale consisted of seven subjects, scored on a 5-point scale from 1 (strongly agree) to 5 (strongly disagree). The average score indicated the level of fear regarding COVID-19 infection, with higher scores indicating a greater level of fear. (3) COVID-19 infection related Anxiety Scale had 10 items, scored on a 5-point scale from 1 (not strong) to 5 (very strong). Similarly, the average score indicated the level of anxiety and worry, with higher scores meaning higher levels. Medical staff evaluated the enrolled patients and guide them to complete the questionnaire survey on depression, anxiety, depression, and sleep status. The original scale had a Cronbach’s α coefficient of 0.82 (15), and the Cronbach’s α coefficient of the scale in this study was 0.855, demonstrating good reliability.

Statistical analysis was performed using SPSS 22.0 and GraphPad Prism 6. The enumeration data was expressed as percentage (%), and the measurement data was expressed as ( x ¯ ± s ). ANOVA (normal distribution) or nonparametric test (non-normal distribution) for continuous variables and the chi-square test was used to analyze the clinical features of patients. p < 0.05 was statistically significant. Multivariate analysis was performed using R 4.2.1 (http://www.Rproject.org; The R Foundation, Vienna, Austria) and the Free Statistics software (version 1.9.2; Beijing FreeClinical Medical Technology Co., Ltd., Beijing, China). Missing covariate data are replaced with statistical estimates of missing values, missing values for continuous variables are taken as means, medians, or patterns, and missing values for categorical variables are treated as a separate group.

We primarily utilized descriptive statistics to illustrate the variations in platelet counts among ITP patients before and after COVID-19 infection. This method allows for straightforward data visualization without complex statistical inference. Anyway, to control the potential confounders, we categorized ITP patients based on platelet count levels before infection (PC <100 × 10⁹/L and PC ≥100 × 10⁹/L), vaccination status (vaccinated vs. unvaccinated), and treatment for ITP (treated vs. untreated). This stratification method aids in assessing changes in platelet counts across different subgroups, thereby reducing potential confounding effects, and these categories are also of clinical significance. In the subsequent analysis, we incorporated a multifactorial analysis to better control for various factors, including age, sex, BMI, and ITP treatment, etc.

A total of 90 ITP patients were included, all of whom were infected with the coronavirus and have recovered. The average age was 40 (12–67) years old. Males accounted for 83% (75/90) and females for 17% (15/90). Patients over 60 years old took a proportion of 11% (10/90) of the total, while patients under 60 years old of 89% (80/90). There were 62 patients currently undergoing ITP-related treatment, 22 people who had finished medication and were under observation, and six people who had never received any treatment. The median course of ITP duration was 65 months (6–278 months), with a median of 2 (1–4) prior treatment lines received, and a median of 1 (1–3) occurrences of COVID-19 infection. The median time for the coronavirus to turn negative was 7 (3–11) days. About vaccination, 50 patients had received COVID-19 vaccines and 40 patients not subjected (Table 1).

A control group of 69 healthy individuals who were infected with the coronavirus and recovered were included. We compared the differences in related symptoms after COVID-19 infection between the two groups. Common clinical symptoms were recorded, including fever (low-grade, moderate-grade, high-grade), cough, throat pain, chest tightness, difficult breathing, poor appetite, nausea and vomiting, diarrhea, etc. The results have shown that the proportion of fever was over 80% in both the ITP patients and the healthy group, making it the highest proportion among all the symptoms. In terms of low-grade fever, the proportion among ITP patients was significantly higher than that in the healthy group, with 31% vs. 17% (p = 0.04). There were no statistical differences between the two groups regarding the remaining symptoms (Figure 1) (Supplementary file 1).

Both baseline and 2-week platelet counts were available for 90 ITP patients. If the change was defined as a >20% fluctuation, 9 (10%) patients showed a decrease, 24 (27%) patients showed no change, and 57 (63%) patients showed an increase in the platelet count at 2 weeks after COVID-19 infection (Figure 2A).

In general, platelet counts of 90 ITP patients were measured before and after being infected with COVID-19. According to statistical results, the mean platelet counts before infection was 100 × 10⁹/L. The mean PC 1 week after recovery from infection was 192 × 10⁹/L, 2 weeks after recovery was 178 × 10⁹/L, 3 weeks after recovery was 102 × 10⁹/L, and 4 weeks after recovery was 97 × 10⁹/L. Meaningfully, the increased PC 1 week after recovery from the coronavirus infection was statistically significance compared to the PC level before COVID-19 infection (p = 0.000) (Figure 2B). The dynamic changed of PC after COVID-19 infection could be depicted as a transient increase in 1–2 weeks before a gradual decline over the following 2 weeks to the pre-infection level.

Further, we categorized patients into two groups based on their platelet counts before contracting the virus (Group A: PC <100 × 10⁹/L and Group B: PC ≥100 × 10⁹/L). For Group A, the average platelet count prior to COVID-19 infection was 54 × 10⁹/L. In the initial week post-infection, the average PC rose to 160 × 10⁹/L. Subsequently, it dropped to 131 × 10⁹/L in the second week, further declining to 71 × 10⁹/L by the third week, and stabilizing at 70 × 10⁹/L in the fourth week. As for Group B, the mean platelet counts pre-COVID-19 infection stood at 155 × 10⁹/L. Within the following 4 weeks of infection, the mean PC surged to 226 × 10⁹/L, peaked at 236 × 10⁹/L, then decreased to 119 × 10⁹/L, ultimately settling at 114 × 10⁹/L. Notably, regardless of whether the PC was above or below 100 × 10⁹/L, the overall pattern remained consistent, with a notable disparity in platelet counts before and 1 week after COVID-19 infection (p < 0.05). However, in Group A, platelet counts started declining in the initial week, while in Group B, this decrease commenced after 2 weeks. Ultimately, after a 3 to 4-week recovery period following COVID-19 infection, platelet counts returned to baseline levels (Figure 3A).

Next, the patients were analyzed based on whether they were vaccinated against the COVID-19 (Vaccinated and Not vaccinated). The baseline (before infection) mean PC of vaccinated patients was 98 × 10⁹/L, after the virus antigen test turned negative, the PC at weeks 1, 2, 3, and 4 were 187, 171, 101, and 93 × 10⁹/L, respectively. Similarly, the average PC of patient without vaccination before COVID-19 infection was 102 × 10⁹/L. In weeks 1, 2, 3, and 4 after the patients recovered, the PC were 196, 183, 103, and 101 × 10⁹/L, respectively. Whether being vaccinated or not, the trend of platelet changes indicated an initial increase followed by a decline. Upon analysis, it was observed that there was a notable and statistically significant difference in platelet counts between the pre-infection period and the initial week of recovery for both groups (p = 0.044, and p = 0.002) (Figure 3B).

In addition, we divided the ITP patients into two groups based on whether they were receiving ITP treatment (ITP treatment and non-ITP treatment). The average platelet counts before COVID-19 infection in non-ITP treated patients was 95 × 10⁹/L. In the first week after recovering from the viral infection, the average platelet count increased to 181 × 10⁹/L. In the second week, it slightly increased to 236 × 10⁹/L. In the third week, it further decreased to 118 × 10⁹/L, and in the fourth week, it reached 79 × 10⁹/L. For patients underlying ITP treatment, the platelet count before COVID-19 infection was 113 × 10⁹/L. In the first week after recovery, the mean platelet count was 221 × 10⁹/L, in the second week it was 152 × 10⁹/L, in the third week it was 97 × 10⁹/L, and in the fourth week it was 101 × 10⁹/L. The analysis results revealed that trend of PC changes was as the same with the subgroup outcomes. Interestingly, the platelet counts of the non-ITP treatment group began to decrease from the third week after infection recovery, whereas the ITP treatment group’s platelet count began to decrease from the second week after COVID-19 recovery (Figure 3C).

In the subsequent analysis, we incorporated a multifactorial analysis to better control for various factors, including age, sex, BMI, and ITP treatment. The results showed that there was a significant negative correlation between the platelet count before COVID-19 infection and the clearance time of SARS CoV-2 virus (p = 0.021). However, no correlation was found between platelet variations and factors such as age, sex, and BMI. These findings enhance the reliability of our results and contribute to understanding the complexities surrounding platelet count changes in ITP patients before and after COVID-19 infection (Supplementary file 2).

In summary, we categorized ITP patients based on whether they received ITP-related treatment, their response status (CR or non-CR), and vaccination status. The consistent outcome was that the average platelet count increased during the first week after COVID-19 infection, then gradually decreased, returning to baseline levels by the third week. However, potential mechanisms have not been further investigated, including the lack of measurement of levels of IL-6, TPO, or lymphocyte subgroups such as T, B, and NK cells.

In addition to analyzing symptoms and platelet changes after COVID-19 infection, we separately assessed the level of psychological fear of COVID-19 infection in healthy individuals and patients with ITP.

According to the questionnaire results, it was found that both groups scored above 3 in terms of fear of contracting COVID-19 and the possibility of the virus causing lingering effects or even death, indicating a high level of fear among the participants. However, the overall mean scores for both groups were below 3 in the other five items survey, suggesting a relatively low level of fear towards the current COVID-19 pandemic. There was no statistically significant difference between ITP patients and healthy individuals (Table 2).

Based on the published Fear Scale, we designed a 10-item worry scale for individuals who have been infected with the coronavirus, and collected feedback from ITP patients and healthy individuals. Finally, we evaluated the scores for each item for each patient. It was found that both groups had clear concerns about transmitting the virus to older adults or children, with healthy individuals expressing stronger concerns. For ITP patients, there were strong concerns about “Worsening complications such as organ bleeding,” “Increasing caregiving pressure to the family” and “Affecting platelet recovery” after contracting the virus. And for the three aspects, there was a significant statistical difference in the mean scores for the 10 worries between the two groups (p < 0.001) (Table 3).

Our study focuses on the psychological changes of ITP patients regarding COVID-19 and their concerns about ITP disease, which is a distinctive feature of this research. Table 2 was designed to compare the awareness of COVID-19 among ITP patients and healthy individuals, revealing no significant difference in overall scores (p = 0.301). This suggests that as understanding of COVID-19 deepens, fear of the disease decreases. However, ITP patients express significant concerns about the impact of COVID-19 on their condition if infected, such as exacerbated organ bleeding, delayed platelet recovery, and increased caregiving burden (Table 3). Statistically, the two groups show a significant difference in concerns about the exacerbation of ITP symptoms (p = 0.046). Additionally, while our questionnaire was primarily aimed at understanding the psychological effects of the Omicron outbreak, it did not extensively address the long-term impacts of COVID-19 on ITP patients. We believe that the psychological effects of persistent COVID-19 related symptoms or repeated COVID-19 infections in ITP patients merit further investigation.

Hematological inflammatory parameters of ITP patients, including monocyte-to-lymphocyte ratio (MLR), neutrophil-to-lymphocyte ratio (NLR) and platelet-to-lymphocyte ratio (PLR), were evaluated before and after viral infection. Before the COVID-19 infection, the median PLR was 54.0 (30.2, 77.3), but after viral infection, the PLR increased to 83.6 (41.1, 127.5) (p = 0.001). By the third week, it was down to 59.4 (32.6, 96.4) (p = 0.980). However, the MLR and NLR showed no significant increase or decrease before and after the viral infection, remaining relatively stable (Table 4).