The Neuroinflammasome in Alzheimer's Disease and Cerebral Stroke.

AIM/
BACKGROUND: This review investigated a patient with Alzheimer's disease (AD) treated with 4,4'-diaminodiphenyl sulfone (DDS) as a neuroinflammasome competitor.
METHODS: We monitored AD's progression through numeric clinical staging (NCS) with a new biomarker. NCS was determined by the presence of AD symptoms and neuropsychiatric (NP) symptoms caused by anti-AD (AAD) drugs (D) as a biomarker. We also monitored the function of DDS for stroke in a no-intake emergency state.
RESULTS: By introducing (D), AD's progression was monitored through NCS staging. AAD side effects and neuropsychiatric symptoms were identified. DDS was stopped in patients with stroke with NCS 6 caused by AAD, and it rapidly proceeded to cerebral infarct.
CONCLUSIONS: AAD can occasionally exacerbate AD and stroke. DDS can alleviate mild cognitive impairment (MCI), early AD and stroke. We clinically confirmed the role of DDS as a neuroinflammasome competitor after stroke. DDS preserved neuronal survival within 24-55 h in the Seoul Study cohort.

Introduction

In an attempt to prevent the progression from mild cognitive impairment (MCI) to Alzheimer's disease (AD), a prospective cohort was created in 2010 based on the prevention and treatment of dementia by administering 4,4′-diaminodiphenylsulfone (DDS) [1], its didextrose sulfonate derivatives, and other closely related sulfones (sulfone and thiazolsulfone) [2, 3]. The patient took DDS 100 mg once a day from 2010 to 2015 for the treatment of MCI (online suppl. 7, pp. 1–4; see www.karger.com/doi/10.1159/000516074 for all online suppl. material) [4]. Then, in 2016, the production of DDS ceased in Korea [5]. In June 2018, the patient was then diagnosed with AD (online suppl. 6, p. 1, p. 29) [4].

DDS, initially approved for leprosy, has potent antimicrobial effects, even in small doses [6]. This study shows that DDS is also a neuroinflammasome competitor. To demonstrate this, we introduced the application of a new biomarker that can be used to treat and manage AD by applying step-by-step numeric clinical staging (NCS) according to the treatment of neuroinflammation.

Materials and Methods

The Seoul Study was a prospective cohort study of patients diagnosed with MCI in the period from February 2008 to June 2020. All methods were carried out in accordance with relevant guidelines and regulations.

The Use of Ani-AD Drugs as a New Biomarker of NCS

The raw data for AD were prepared according to “symptom-based categorical cognitive impairment stage,” i.e., cognitively unimpaired, mild cognitive impairment (MCI), or dementia. This 3-category division serves as the basis for cognitive categorization in many ongoing studies [7]. NCS was recorded according to the 2018 “NIA-AA Research Framework” as 05-02-2008 Stage 3, 27-06-2018 Stage 4, 06-11-2018 Stage 5, and 14-01-2019 Stage 3, based on Korean neuropsychiatric medical records and magnetic resonance imaging (MRI) reports. When recording NCS stage 2→3→4→5→3, we used the following biomarkers: β-amyloid deposition (A), pathologic tau (T), and neurodegeneration (N).

In this study, anti-AD (AAD) drugs, referred to (D) were used as a new biomarker of NCS [8]. In the periods 27-06-2018 to 01-10-2018 and 06-11-2018 to 21-11-2018, AAD use caused side effects. We examined patients with the same symptoms [9, 10, 11, 12]. After AAD use was stopped from 01-10-2018 to 22-11-2018, the NCS changed from stage 6 to stage 5. After neuroinflammasome treatment, it changed from stage 5 to stage 3.

We recorded the following NCS values: 05-02-2008 Stage 3, 27-06-2018 Stage 4, 27-06-2018 ∼ 01-10-2018 Stage 6, 01-10-2018 ∼ Stage 5, 06-11-2018 Stage 5, 06-11-2018 ∼ 16-11-2018, 21-11-2018 Stage 6, 22-11-2018 ∼ Stage 5, and 14-01-2019 Stage 3.

Case Report of Cerebral Infarction and a Neuroinflammasome Competitor

This study is based on the results of the Seoul Study cohort. Patients' medical records were issued in accordance with Korean medical law. All medical records in this supplement are copies of patients' medical charts.

DDS blocks the bacterial synthesis of dihydrofolic acid via competition with p-aminobenzoic acid for dihydropteroate synthetase's active site [13]. In addition to its antimicrobial effects, DDS is a potent anti-inflammatory agent with high efficacy in dermatitis herpetiformis and a wide variety of other inflammatory dermatological conditions [6]. DDS, that inhibits inflammation without compromising the adaptive immune response, could be the most effective therapeutic strategy. DDS, as an inflammasome competitor [14] should be effective against neuroinflammasomes.

We analyzed the Seoul Study cohort of elderly patients with MCI who underwent precise MRI examinations for stroke in May 2020. The DH Hospital conducted medical examinations (online suppl. 1, 1-1 [11-05-2020-diffusion MRI- Rx image], online suppl. 1-2 [12-05-2020-diffusion MRI- Rx image], online suppl. 1-3 [12-05-2020-perfusion MRI- Rx image]), CT (online suppl. 1, p. 15, p. 18, p. 19], online suppl. 1-4 [11-05-2020-CT- Rx image], online suppl. 1-5 [13-05-2020-CT- Rx image]), chest AP (online suppl. 1, p. 13, p. 20], online suppl. 1-6 [11-05, 20-05-2020-chest-Rx image], and medical report (online suppl. 1, pp. 4–12).

We hypothesized that the deterioration of ischemic stroke to cerebral infarct could be prevented by NLRP3 inflammasome inhibitors [15], such as DDS. The DDS tablets were produced by the local pharmaceutical company, but production was stopped and since then, the Korea FDA has designated DDS as an antiretraction drug and produces it only for leprosy/Hansen's disease (HD) sufferers. The Korea Orphan and Essential Drug Center imported it from Germany. After administering the 2 types of DDS to patients, we found a large difference in clinical effectiveness. DDS from the local pharmaceutical company had one-third the effective dose (ED50) of the DDS from Germany.

On 10 May 2020, the patient was dosed twice daily with 200 mg (2 times daily) and close monitoring revealed the following; rash/exanthema/erythema/erythroderma/mucosal involvement leukocytosis/eosinophilia [16], the appearance of a mononucleosis infection/acute renal failure/hepatitis/liver toxicity [17], hemolytic anemia/methemoglobinemia [18], cholangitis/colitis/thyroiditis/myocarditis/dapsone-induced hypersensitivity syndrome-associated complete atrioventricular block/pneumonitis [19], pancreatitis/pleural effusion [20], and myocardial injury/pneumonia/multiple organ failure [21].

Corroboration of the Neuroinflammasome Findings of the Seoul Study

In Korea, during the SARS-CoV-2 epidemic, children were prohibited from visiting their parents in nursing hospitals [22]. It became difficult for carers to interact with older adults at close range. In nursing hospitals, chemical restraint increased substantially to reduce hospital labor costs during the same period [23].

Medical staff found the patient to suffer from endocarditis and pulmonary effusion symptoms (online suppl. 2, 2–1). The patient took DDS at lunch (12:00) on 12 September 2020, was transferred to Inje University Seoul Paik Hospital, and stopped taking DDS until 19:00 on 15 September 2020. Only after the patient's guardian submitted a memorandum of responsibility (online suppl. 2, p. 6 and 2-2, p. 25) was the patient able to retake DDS with the permission of Professor Jong-Chun Nah, a cardiology specialist at the hospital. The patient's cognitive state over the course of 55 h was observed through medical records (online suppl. 2, 2-2).

Results

AAD Drugs as a New Biomarker of NCS

Observational studies of AD after the treatment of neuroinflammation:

(1) Syndromal staging of the cognitive continuum (SSC)

December 2007 “cognitively unimpaired” → 05-01-2008 “MCI” 27-06-2018 “dementia” → 11-06-2018 “dementia” → 14-01-2019 “MCI.”

(2) NCS 2007 stage 2→ 05-02-2008 stage 3→ 27-06-2018 stage 4→ 06-11-2018 stage 5→ 14-01-2019 stage 3.

(3) NIA-AA (A) (T) (N)) + new biomarker (D)

NCS 2007 Stage 2→ 05-02-2008 stage 3→ 27-06-2018 stage 4→ 27-06-2018 ∼ 01-10-2018 stage 6→ 01-10-2018 stage 5→ 06-05-2018 stage 5→ 06-11-2018 ∼ 16-11-2018 stage 6→ 22-11-2018 stage 5→ 14-01-2019 stage 3.

The comparison table of the above study results can be seen in Table 1.

Table 1

Treatment of neuroinflammation with (D) (added NCS information is italicized)

Year	NCS [7]	Online supplement [4]	SSC	NIA-AA	NIA-AA + (D)
2007	Stage 2	Online supplement_6.pdf (p. 2; online suppl. 6 [4])The patient visited in December 2007 with recent memory disturbanceThere were no abnormalities in the findings	Cognitively unimpaired	Stage 2	Stage 2
05-02-2008	Stage 3	Online supplement_4.pdf (p. 1; online suppl. 4 [4])MMSE = 23, CERAD = 45, CDR = 0.5/0.5/1.5, MRI; hippocampal atrophyAssessment: MCI, amnesticPlan: observation	MCI	Stage 3	Stage 3
Seoul Study − Trial of DDS for AD preventionDDS supply was suspended in Korea from 2016
27-06-2018	Stage 4	Online supplement_6.pdf (p. 1, p. 2; online suppl. 6 [4])On 20 June 2018, the patient presented with leg pain and memory impairment The patient scored 22/30 on the MMSE and 4 on the GDS 4, with decreases in time-keeping, memory and calculation abilityOn 27 June 2018, brain MRI imaging showed multiple lacunar infarction and cerebral cortical atrophy	Dementia	Stage 4	Stage 4
27-06-2018 ˜ Stage 6	Side effects of (D) prescribed by the doctor			Stage 6
01-10-2018		Abdominal pain, bradycardia, heart failure, angina pectoris, perineal incontinence, dysphagia, anemia, weight loss, peripheral edema, edema, leg cramps, myalgia, irritability, anxiety progression, convulsions, transient mental disorder, gait abnormality, apathy, dizziness, delusions, increased frequency of dreaming, increased ecstatic mood, pyramidal symptoms, seizures/hypertension, exercise reduction, difficulty breathing, dysuria
10-2018 ˜	Stage 5	Stop AAD
06-11-2018	Stage 5	Online supplement_1.pdf (pages 1–2; online suppl. 1 [4])MMSE 18/30, CDR 1.0, FAB 16/18, NPI-Q 30, K-IADL 0.6, GDS 3, GSS 0, Lewy bodies 0	Dementia	Stage 5	Stage 5
06-11-2018 ˜ Stage 6	Side effects of (D) online supplement_2.pdf (p. 1; online suppl. 2 [4])			Stage 6
21-11-2018		Abdominal pain, bradycardia, heart failure, angina pectoris, perineal incontinence, dysphagia, anaemia, weight loss, peripheral edema, edema, leg cramps, myalgia, irritability, anxiety progression, convulsions, transient mental disorder, gait abnormality, apathy, dizziness, delusions, increased frequency of dreaming, increased ecstatic mood, pyramidal symptoms, seizures/ hypertension, exercise reduction, difficulty breathing, dysuria
22-11-2018	Stage 5	Stop AAD			Stage 5
The Korea Orphan and Essential Drug Center imported and supplied DDS
28-11-2018		DDS, online supplement_3.pdf (p. 1; online suppl. 3 [4])The Korea Orphan and Essential Drug Center imported and supplied DDS on 2018-11-28, 2018-12-27, and 2019-04-02
14-01-2019	Stage 3	Online supplement_1.pdf (pp. 3–5; online suppl. 1 [4])MMSE 17/30, CDR 1.0, FAB 14/18, NPI-Q 0, K-IADL 0.3, GDS 2, GSS 2, Lewy bodies 0	MCI	Stage 3	Stage 3
01-05-2020	Stage 3	DDS supply resumed in Korea in January 2020. The Seoul Study cohort was prescribed 150–300 mg DDS as a competitor for the inflammasome	MCI	Stage 3	Stage 3

AD Cases 1–5 of the Seoul Study followed a similar path. There were 2 stage 6 cases concealed by the appearance of stage 4 or 5, which could not be monitored (Fig. 1).

Fig. 1

The ranges of syndromal staging of the cognitive continuum (SSC), the National Institute on Aging (NIA) at National Institutes of Health and the Alzheimer's Association published revised guidelines (NIA-AA) for modernization of the diagnosis of Alz­heimer's disease, and NIA-AA + (D) are plotted as a radial chart. NIA-AA standard schematically represents SSC. SSC has the smallest range compared to the NIA-AA and NIA-AA + (D). NIA-AA + (D) monitors a wider range than the NIA-AA. The management scope for Alzheimer's disease will be further expanded if the NIA-AA standard includes (D).

Cerebral Infarction and DDS as a Neuroinflammasome Competitor in the Seoul Study

The attending physician stopped the brain-cell protective drug (DDS) that the patient had been taking in a stable state after stroke onset on 10 May. He prescribed aspirin for antithrombotic treatment and acetylcholine precursor. The patient's NCS was stage 6 after 5 h according to the increase of acetylcholine (online suppl. 1, p. 8 [22:44, 01:00]).

The patient did not take DDS on 11 and 12 May 2020. After antithrombotic treatment, the patient's muscle power changed from grade 1(+) to (4+) at 08:00. However, it suddenly changed from (4+) to (1+) at 11:30 on 12 May 2020. On MRI, the patient's left cerebral infarct was further enlarged (online suppl. 1, p. 16, p. 17; 1-2, 1-3). After 72 h, the patient took DDS again (online suppl. 1, p. 12 [08:50]). The patient's condition did not worsen despite having pneumonia, cardiomegaly, and suspected pulmonary hypertension (online suppl. 1, p. 19).

Although traditional cardiovascular risk factors account for the majority of strokes, infectious pathogens may pose an additional risk and, in some cases, play a direct causal role. Systemic infections have been associated with an increased risk of strokes, and inflammation stimulation has been thought to be the predominant mechanism of certain pathogens [24]. The cerebral stroke in this case was caused by pneumonia (online suppl. 1, p. 19, p. 20; online suppl. 1-5 [13-05-2020- CT- Rx image], 2-6 [11-05-2020, 20-05-2020-Chest- Rx image]) S. pneumoniae and H. influenzae were found in the culture test (online suppl. 1, p. 21).

Neuroinflammasome Causes Exacerbation and DDS Weakens It Again

After the patient was discharged on 20-05-2020, medical staff stopped the acetylcholine precursor in the rehabilitation hospital and the patient recovered to NCS stage 3.

Medical staff found the patient suffering from endocarditis and pulmonary effusion symptoms again (online suppl. 2, 2-1). From lunch (12:00) on 12 September to 19:00 on 15 September 2020, the patient's progress during and after 55 h of DDS discontinuation was monitored. DDS was loaded at 19:00 on 15 September 2020. Below are the data from the patient's medical record from 28 September to 9 December 2020 (online suppl. 2, p. 1, p. 2).

After administering DDS at 19:00 on 15 September and at 18:53 on 16 September 2020, the patient became drowsy from stupor. The patient's cognitive condition is shown in Table 2.

Table 2

The observational record of the Seoul Study during transfer

Date (2020)	DDS	Consciousness level	Medical examination/treatment	Radiologic examination (Suppl. 3, Suppl. 3-1, 3-2)	ECG
03-09		alert or drowsy	The picture was generally clear, but it was difficult to find a specific focus of infiltration
11-09			Haziness in whole left lung
12-09 12:00	1T po tidStop		Transfer due to anemia and pneumonia	Haziness in whole left lung, right pleural effusion	Infective endocarditis with paravalvular invasion/consider surgical treatment
13-09 14:00	Stop	stuporous	Acute endocarditis/pulmonary pneumonia	Improving haziness in left lung, multifocal consolidation in left lung, r/o pneumonia, bilateral pleural effusion -> decreasing, cardiomegaly
15-09 15:30	Stop	stuporous	Acute endocarditis/pulmonary pneumonia	Decreased left pleural effusion and improving haziness in left lungNo other changes
16-09 10:06	Start DDS at 19:00	stuporous	Acute endocarditis/pulmonary pneumonia	No definite evidence of radiographic interval changes since last chest radiographNo evidence of other newly developed abnormal findings at this timeImpression: no definite interval changes
16-09 18:53	1T po tid	drowsy	Acute endocarditis/pulmonary pneumonia
17-09 11:00	1T po tid	confused	Acute endocarditis/pulmonary pneumonia	Bilateral pleural effusion (left > right)Left pigtail tube insertion state
17-09 18:54	1T po tid	drowsy	Acute endocarditis/pulmonary pneumonia	Left pigtail tube insertion state, decreased left pleural effusion, no significant interval change in right pleural effusion
18-09 01:16	1T po tid	confused	Acute endocarditis/pulmonary pneumonia	No significant interval change in bilateral pleural effusion or pulmonary edema	Infective endocarditis, severe mitral regurgitation
18-09 04:45	1T po tid	drowsy
18-09 10:12	1T po tid	drowsy
18-09 18:35	1T po tid	drowsy
28-09 06:52	1T po tid	drowsy	Normal-sized left ventricle with normal LV systolic functionNo regional wall motion abnormalityVegetation at the mitral valveImproved RV systolic pressure (62.5–>38.6 mm Hg) compared to the previous echo (14 September 2020)
28-09 10:35	1T po tid	drowsy

LV, left ventricular; RV, right ventricular; T, tablet; po, per os; bid, bis in die; tid, ter in die.

Except for taking DDS, the patient's treatment did not change, but there was a clear change in consciousness, and infective endocarditis improved to a stable state.

The NLRP3 neuroinflammasome is a common cause of cognitive impairment in AD, stroke, and inflammation by certain pathogens. The action of DDS demonstrates that the inhibition (control) of NLRP3 is a new target for therapeutics.

Discussion

The Alzheimer's Continuum

For clinical research, the Alzheimer's continuum (A + T + [N] + [D]) was selected based on biomarkers. Before AD progressed, biomarkers were changed. Therefore, clinical symptoms and biomarkers were separated from AD diagnosis, and AD was defined only by changes in biomarkers [7]. The AD criteria biologically classify cognitive impairments separately as symptoms/signs caused by these diseases. AD problems may include the following: depression, apathy, social withdrawal, mood swings, distrust in others, irritability and aggressiveness, changes in sleeping habits, wandering, loss of inhibitions, and delusions such as believing something has been stolen [25]. As of mid-2019, several AD drugs were available worldwide: donepezil, galantamine, rivastigmine and memantine [26]. Aripiprazole, olanzapine, risperidone, quetiapine, haloperidol, selective serotonin-reuptake inhibitors, and carbamazepine are used to control the psychiatric symptoms associated with dementia [27, 28, 29, 30, 31, 32]. However, it was challenging to differentiate whether AAD caused symptoms because of the Korea Dementia Act and the health insurance system. (D) can be used as a biomarker to distinguish the symptoms caused by AAD. Since the side effects of AAD have been reported [33, 34], it is necessary to record the biomarker (D).

The FDA warned that dementia-related antipsychotic drugs increase mortality. The boxed warning reads as follows: “Elderly patients with dementia-related psychosis treated with antipsychotic drugs are at an increased risk of death” [33]. More recent studies from many countries confirm that antipsychotic drugs should not be prescribed for dementia patients, as they significantly increase the risk of seizures and all-cause mortality [34]. Therefore, to distinguish the symptoms caused by AAD or AD, it is necessary to stop taking AAD and observe a patient's clinical progress. In this study, when acetylcholine precursor was administered to the patient, the patient's state changed from the NCS 6 stage. Medical staff must label the AAD as a biomarker (D) and monitor the patient's condition for changes.

DDS to Prevent AD and Amyloid-beta Neurotoxicity

At first review [35], DDS was deemed a therapeutic, preventative agent in AD, according to reports [36, 37, 38]. However, in the second review [39], DDS was not a therapeutic, preventative agent in AD [38, 40]. There were different interpretations of the commonly cited “decreased Aβ and increased abnormal tau deposition in the brain of aged patients with leprosy.” It has been reported that amyloid-beta (Aβ) protein deposits were significantly lower in the temporal cortex and hippocampal formation of elderly HD patients and that patients with T-type leprosy (who did not take DDS) exhibited slightly more Aβ deposition than those with L-type leprosy. The brains of HD patients show high abnormal tau deposition in the neurons and neural threads despite the low levels of Aβ deposition [38]. Mycobacterium leprae, which induces leprosy, was assumed to cause the low incidence of AD in HD [41]. However, the next researchers claimed a null hypothesis because the Aβ removal function of DDS and the dementia reduction by M. leprae are irrelevant [1].

The inflammasome competitor model of DDS shows a reaction pattern that is a typical molecular model of electronic clouds. Therefore, in vitro or in vivo, it can show pathological findings that can be either this or that. The autopsy findings of leprosy's brain pathology at the sanatorium in Japan are variable. The pathologic findings in the previous review are consistent with those of a typical inflammasome competitor. The alternative way science can help us prevent or treat AD is to use an inflammasome competitor and reduce the AD prevalence rate.

The molecular properties of DDS, including electron density and its Laplacian delocalization index, have been elucidated to shed light on the chemical bonding and atomic and molecular details [42, 43]. The redox properties of DDS are dependent on amine and sulfone moieties and can explain the oxidation mechanism of DDS by electron transfer. The aniline ring is the nucleophilic moiety conferring potential biological properties via a redox mechanism, mainly electron transfer or oxidation for DDS-NHOH formation [44]. We can understand the various neuropathological findings associated with HD, including unexplained sensory manifestations [45].

DDS should regulate NLRP3 inflammasome activators and a common signaling pathway of SARS-CoV-2 inflammasome activators in the medulla oblongata [46]. It acts via the same competitive therapeutic mechanism to counter the progression of MCI to AD. Korean HD patients on Sorokdo (an island specifically for HD patients) continue to take DDS throughout their lives. This drug appears to have a preventative effect against AD, according to the study of HD patients who have lived there all their lives [47].

Neuroimmunity and Neuroprotection for Stroke Patients

Hypertension causes blood-brain barrier breakdown via mechanisms involving inflammation, oxidative stress, and circulating vasoactive molecules. It exposes neurons to cytotoxic molecules, leading to neuronal loss, cognitive decline, and impaired recovery from ischemia [48]. Active treatment for elevated blood pressure can decrease perfusion at the cerebral infarction area, thus extending this area [49]. However, there is no evidence that high blood pressure that develops after a stroke indicates stroke severity or is intended to provide collateral blood flow to maintain blood flow to the ischemia area (penumbra) [49, 50, 51]. Instead, in 2004, there was a report that patients with stroke had a high mortality rate when hospitalized with high or low blood pressure [51]. There are only reviews reporting that starting treatment for severe hypertension within a few hours of stroke onset can cause a decrease in cerebral blood flow and may be problematic [52]. There is no medical evidence that neglecting high blood pressure can increase a patient's survival rate. However, it has been reported that the stress of being admitted to hospital is actually the main factor causing high blood pressure in stroke patients [50].

Markedly low red-blood cell (RBC) cholesterol and markedly high RBC lipoperoxides may pathologically aggravate cerebral hemorrhage patients and lead to oxidative and lipoperoxidation damage [53]. These factors are positively correlated with erythrocyte deformability [54]. Considering that there are disturbances in the function of erythrocyte membranes and free radicals in acute cerebral infarction, erythrocyte deformity and membrane Na+-K+-ATPase activity in acute cerebral infarction patients were lower than those in healthy individuals [55, 56]. Antioxidants such as DDS attenuate microvascular changes in the early phase of experimental pneumococcal meningitis [57]. DDS increases the viability of brain cells in acute stroke. Clinical trials were already conducted in 2013 and the statistics were significant [58]. In 2014, an analysis was published that was very effective and economical in treating acute ischemic stroke patients [59]. In 2016, MRI results were published to compensate for functional loss after brain-cell damage [60]. Also, studies have been reported of protection of brain cells and increased viability in various experiments [61]. The paper claiming that DDS increased the concentration of Parkin in old rats was from a study that was precisely consistent with the patient (online suppl. 7, pp. 1–4; C.-S. Koh, pers. observ.[4]) in the Seoul Study cohort whose Parkinson's symptoms improved [62].

Astrocytes play a crucial role in regulating homeostasis within the central nervous system. Furthermore, they mediate hypoxia-induced changes in pathological conditions associated with the immune response and manipulate mitochondrial function and metabolism. An in vitro study on the transcriptomic profile of astrocytes showed a detailed characterization of hypoxia-induced changes. Analysis of the significant differentially expressed transcripts identified an increase in immune response pathways and dysregulation of the signaling pathways and metabolism, including glycolysis [63]. After administering DDS at 19:00 on 15 September and at 18:53 on 16 September 2020, the patient recovered consciousness. Except for taking DDS, the patient's treatment did not change, but he improved to a stable state of infective endocarditis. DDS also reduced doxorubicin's cardiac toxicity due to its production of free radicals and inflammatory cytokines [64].

DDS has already been used as a substitute for colchicine. The specific targeting of NLRP3 itself or up-/downstream factors of the NLRP3 inflammasome by DDS may be responsible for its observed MCI-preventative effects [1], functioning as a competitor for the SARS-CoV-2 inflammasome [14].

Conclusions

DDS is a neuroinflammasome competitor. By prescribing this drug for neuroinflammation and brain survival, the incidence of AD can be reduced by more than two-thirds [1, 2, 3]. Early-onset AD and stroke can be treated with DDS in the same manner as MCI when (A), (T), (N), and (D) are recorded as biomarkers. Trials need to be carried out from middle age (>40 years) in parallel, not sequentially, using adaptive trial designs optimized for speed and tested in different populations so that we can ultimately protect everyone.

Statement of Ethics

The Science and Research Center, Seoul National University of College of Medicine, Seoul, approved this study, based on FDA guidelines in accordance with the World Medical Association Declaration of Helsinki. The subjects (or their parents or guardians) provided written informed consent. We administered medicines in compliance with medical and pharmacy laws with the informed consent of the patient.

Conflict of Interest Statement

The authors have no conflicts of interest to declare.

Funding Sources

There are no funding sources to declare.

Author Contributions

J.L. designed and performed this study and wrote the manuscript. C.J.L., J.P., and S.C. analyzed the symptoms of intractable AD and the use of the AAD (D). S.J.L. examined the cerebral infarct patients and wrote online supplements 1, 2.

Supplementary data

Click here for additional data file.

Supplementary data

Click here for additional data file.

Supplementary data

Click here for additional data file.

Supplementary data

Click here for additional data file.

Supplementary data

Click here for additional data file.