Friday, August 29, 2025

Auscultation: A Clinical Perspective

 

Auscultation and the Stethoscope: A Clinical Perspective


by: lin ru wu alias 

lim ju boo


Introduction:


Auscultation is one of the most venerable and fundamental clinical skills in medicine, denoting the act of listening to internal bodily sounds to evaluate physiological processes and discern potential pathology. Since René Laennec's invention of the stethoscope in 1816, this technique has remained indispensable in the bedside examination of patients, particularly in the assessment of the respiratory and cardiovascular systems, as well as in the identification of vascular abnormalities such as bruits. Despite the emergence of advanced diagnostic technologies, auscultation continues to maintain a pivotal role due to its immediacy, non-invasiveness, and capacity to yield vital diagnostic insights (1,2).


Auscultation of the Respiratory System  


When appraising the thorax, auscultation enables the clinician to evaluate airflow dynamics within the lungs and detect abnormal or adventitious sounds. The primary normal respiratory sound is the vesicular breath sound, which is audible over the majority of lung fields. These sounds are characterized by their soft and low-pitched quality, reminiscent of a gentle rustling. They manifest during active inhalation as air traverses into the bronchi and alveoli, persisting through passive exhalation driven by alveolar elastic recoil. The phases of these sounds can be broadly delineated as the tubular component, succeeded by the alveolar phases during both inspiration and expiration (3).


Any deviation from this normative pattern may signify underlying pathology. For instance, bronchial breath sounds, if detected in peripheral lung fields, may indicate consolidation, as seen in pneumonia, while adventitious sounds such as crackles, wheezes, or rhonchi may reflect conditions such as pulmonary fibrosis, asthma, or chronic obstructive pulmonary disease (3,4).

Auscultation of the Cardiovascular System  

Cardiac auscultation entails the act of listening to the heart using a stethoscope to assess valve functionality and identify abnormal blood flow patterns. Both the diaphragm and the bell of the stethoscope are employed: the diaphragm for high-pitched sounds such as the first (S1) and second (S2) heart sounds, and the bell for low-pitched sounds such as the third (S3) and fourth (S4) heart sounds, or certain diastolic murmurs (5).

A systematic approach is imperative. The examination typically commences at the apical impulse and progresses to the lower left sternal border, the right and left upper sternal borders, and ultimately to the axilla when indicated. Various patient positions, including supine, sitting forward, and left lateral decubitus, are often utilized to accentuate specific sounds (6).

The normal heart sounds comprise S1, produced by the closure of the mitral and tricuspid valves, and S2, resulting from the closure of the aortic and pulmonic valves. Physiological splitting of S2 during inspiration is commonplace and generally benign. Abnormal sounds encompass S3, associated with rapid ventricular filling and often suggestive of heart failure, and S4, which arises from atrial contraction against a stiff ventricle, potentially indicating left ventricular hypertrophy or ischemia (7).

Murmurs represent additional sounds generated by turbulent blood flow across valves. They are described by their timing within the cardiac cycle, intensity, pitch, location, and radiation. Systolic murmurs occur between S1 and S2 and may be further classified as midsystolic, holosystolic, or late systolic. Diastolic murmurs transpire between S2 and S1, while continuous murmurs extend across both systole and diastole. Noteworthy examples include the holosystolic murmur of mitral regurgitation radiating to the axilla, the pansystolic murmur of tricuspid regurgitation accentuated during inspiration, the harsh pansystolic murmur of a ventricular septal defect at the left sternal border, and the Austin Flint murmur indicative of severe aortic regurgitation (8,9). Innocent murmurs, such as Still’s murmur in children, may also be encountered and must be differentiated from pathological murmurs.

To standardize assessment, systolic murmurs are classified from I to VI, with grade I being scarcely perceptible and grade VI audible without the stethoscope in contact with the chest. Murmurs graded IV or higher are typically associated with a palpable thrill (5). The early identification of abnormal heart sounds is of paramount clinical importance, as it enables timely intervention, mitigates morbidity, and enhances patient outcomes (7).


Auscultation of Blood Vessels: Bruits

Beyond the examination of the lungs and heart, auscultation proves invaluable for evaluating major blood vessels. A bruit is an aberrant, blowing or whooshing sound discerned over an artery, resulting from turbulent blood flow through a narrowed or partially obstructed vessel. In contrast to heart murmurs, bruits are extracardiac and generally signify vascular pathology.

Common sites for the auscultation of bruits encompass the carotid arteries in the neck, the abdominal aorta, the renal arteries, as well as the iliac and femoral arteries. Etiological factors include arterial stenosis, often attributable to atherosclerotic plaque, or other obstructive lesions. Clinically, the identification of a carotid bruit holds particular significance, as it may indicate carotid artery disease and herald an elevated risk of stroke (10). Similarly, abdominal or renal bruits can denote aneurysm or renovascular hypertension, conditions necessitating further imaging and prompt intervention.


Auscultation and the utilization of the stethoscope remain foundational elements of clinical examination. Whether assessing vesicular breath sounds, differentiating complex cardiac murmurs, or detecting vascular bruits, auscultation yields critical insights into the underlying physiology and pathology of the patient. While contemporary imaging and diagnostic techniques provide enhanced precision, the art of attentive listening remains indispensable for bedside evaluation, early diagnosis, and clinical decision-making. Mastery of this skill not only augments diagnostic accuracy but also sustains the essential doctor–patient rapport that is central to medical practice. The significance of auscultation extends beyond immediate diagnostics; it embodies a symbiotic relationship between clinician and patient, fostering a deeper understanding of the patient's unique health narrative. Engaging in this intimate process allows for the exploration of subtle shades that may escape more mechanized assessments.

Moreover, the ability to discern minute variations in sound can unveil a myriad of conditions, from valvular heart diseases to systemic ailments, where the implications of timely recognition can be life-altering. This diagnostic skill transcends routine practice and becomes an art form, one that demands both patience and profound attentiveness.

As the landscape of medicine evolves, integrating technological advances with traditional methodologies, the role of auscultation should not be relegated to obsolescence. Rather, it should be viewed as an essential complement to innovative diagnostic tools, serving to enrich the clinician’s toolkit. The harmony between advanced imaging and the time-honored technique of auscultation ensures a holistic approach to patient care, empowering practitioners with a comprehensive understanding of health dynamics.

In conclusion, while the complexities of modern medicine continue to expand, the fundamental principles of clinical assessment remain steadfast. The mastery of auscultation, with its capacity to provide immediate feedback and understanding, is an invaluable asset in the clinician's repertoire. It not only enhances the precision of diagnoses but also reinforces the humanistic aspects of medical practice, ensuring that care remains not only effective but deeply empathetic. Thus, embracing and refining the art of auscultation will continue to be paramount as we navigate the intricate interplay between health and healing in the evolving landscape of healthcare.


Summary Table: Auscultation Findings


SystemNormal SoundsAbnormal SoundsClinical Significance
RespiratoryVesicular breath sounds: soft, low-pitched, rustling, heard across most lung fieldsBronchial breath sounds in periphery; Adventitious sounds (crackles, wheezes, rhonchi)Consolidation (pneumonia), asthma, COPD, fibrosis
Cardiac – Heart SoundsS1: closure of mitral & tricuspid valves; S2: closure of aortic & pulmonic valves (physiological splitting in inspiration)S3: rapid ventricular filling (HF); S4: atrial contraction against stiff ventricle (LVH, ischemia)Heart failure, hypertrophy, ischemic heart disease
Cardiac – MurmursNoneSystolic, diastolic, or continuous murmurs, described by timing, pitch, intensity, radiationValvular disease (e.g., MR, TR, VSD, AR, AS)
Cardiac – Murmur ExamplesInnocent murmurs (e.g., Still’s murmur in children)Austin Flint (severe AR); Graham Steell (pulmonary regurgitation); Holosystolic MR/TR murmursDifferentiates benign vs. pathological murmurs
VascularNo bruitBruit: blowing/“whooshing” sound over arteryCarotid bruit (stroke risk), renal bruit (renovascular HTN), abdominal bruit (aneurysm)


Clinical Pathway of Auscultation: 


Step 1: Preparation

Ensure a quiet environment.

Patient positioned appropriately (supine, sitting, left lateral, etc.).

Use diaphragm and bell of stethoscope correctly.


Step 2: Systematic Listening

Respiratory system: Listen over multiple lung fields (anterior, posterior, lateral).

Cardiovascular system: Listen systematically over the four valve areas (aortic, pulmonic, tricuspid, mitral) and axilla if needed.
Vascular system: Listen over carotids, abdominal aorta, renal, femoral, and iliac arteries when indicated.

Step 3: Identify Normal vs. Abnormal

Respiratory: Vesicular vs. bronchial/adventitious sounds.

Cardiac: S1, S2 normal; presence of S3, S4, murmurs.
Vascular: Presence or absence of bruits.

Step 4: Characterization of Abnormal Sounds

Respiratory: Type of adventitious sound (crackles, wheezes, rhonchi).

Cardiac murmurs: Timing (systolic, diastolic, continuous), pitch, intensity (I–VI), location, radiation, quality.
Bruits: Site, intensity, duration.

Step 5: Correlate with Clinical Context
Match auscultatory findings with symptoms (dyspnea, chest pain, syncope).
Integrate with physical signs (cyanosis, edema, pulse quality, BP changes).

Step 6: Clinical Decision

Normal findings → reassurance and routine monitoring.

Abnormal but benign (e.g., Still’s murmur) → observation.


Pathological findings → further investigations:


Respiratory: Chest X-ray, CT, spirometry.
Cardiac: Echocardiography, ECG.
Vascular: Doppler ultrasound, CT angiography.

Step 7: Management and Follow-up

Use auscultatory findings as early diagnostic evidence.

Guide medical/surgical treatment decisions.
Monitor progression or resolution during follow-up.


A Medical Psalm: The Shepherd’s Auscultation


“The Lord is my Shepherd; I shall not want. He makes me lie down in green pastures; He leads me beside still waters; He restores my soul.” 

(Psalm 23:1–3)

So too, the physician with stethoscope in hand becomes a shepherd of the patient. To auscultate is to pause, to lean in, and to listen, not only to the rhythms of heart and lung, but to the unspoken fears and silent hopes of the one who suffers.

1. The quiet room is the green pasture.

2. The still diaphragm of the stethoscope is the still water.

3. The sounds of the heart and lungs are the voice of the flock, calling for guidance.

When the physician listens with humility, wisdom, and compassion, auscultation becomes more than a diagnostic tool, it becomes a ministry of healing. As the Good Shepherd restores the soul, the attentive clinician restores the trust, dignity, and hope of the patient.


Conclusion:

 
Auscultation remains a vital pathway, uniting clinical science with the healing art of listening. Its practice, structured, disciplined, and compassionate, reminds us that medicine is not only about discovering pathology but also about shepherding life with care. In the stillness of auscultation, the voice of both body and soul can be heard.


References


1. Laennec RTH. De l’Auscultation Médiate. Paris: J.-A. Brosson & J.-S. Chaudé; 1819.


2. Mangione S, Nieman LZ. Cardiac auscultatory skills of internal medicine and family practice trainees: a comparison of diagnostic proficiency. JAMA. 1997;278(9):717–22.


3. Vukanovic-Criley JM, et al. Competency in cardiac examination skills in medical students, trainees, physicians. Arch Intern Med. 2006;166(6):610–6.


4. Shaver JA. Cardiac auscultation: a glorious past—and it does have a future! Circulation. 1995;91(4):1256–9.


5. Roy D, Sargeant J. The disappearing art of auscultation: a call to action. Med Teach. 2012;34(7):568–70.


6. Chizner MA. Cardiac auscultation: rediscovering the lost art. Curr Probl Cardiol. 2008;33(7):326–408.


Tuesday, August 26, 2025

Is Cukur Manis or Mani Cai Safe for Consumption?

 Nutritional Anaemia and Hypotension Among Rural Malaysian Women: Investigating the Role of Sauropus androgynus (Cekur Manis)


by  Lim Ju Boo alias Lin Ru Wu


Abstract: 


This paper explores the relationship between dietary patterns in rural Malaysian villages and the prevalence of nutritional anaemia and hypotension among young women, with a specific focus on the widely consumed vegetable Sauropus androgynus (cekur manis). Through field studies and chemical analyses, a potential link was established between frequent consumption of this vegetable and observed low blood pressure. The phytochemical component papaverine, a vasodilator, was identified in the plant. This paper discusses the dual nature of S. androgynus as both a nutritional and potentially toxic plant, citing documented outbreaks of bronchiolitis obliterans in Taiwan and Japan from the raw consumption of the plant in large quantities. Recommendations for safe consumption and further public health implications are provided.


1. Introduction:  During medical research and health surveys conducted by my medical and nutrition team from the Institute for Medical Research from 1970 till mid 1990's in the villages of Malaysia, a recurring health problem among young women was observed, namely, frequent complaints of giddy spells, later correlated with nutritional anaemia and consistently low blood pressure. These women, often on nearly meatless diets, experienced chronic iron deficiency worsened by monthly menstrual blood loss.

Upon deeper investigation, it was discovered that many of these villagers consumed large quantities of a local leafy vegetable known as cekur manis (Sauropus androgynus), valued for its affordability, taste, and traditional health benefits, and easy to plant in their own village fields and compounds. 

Intrigued by the potential physiological effects of this plant, samples of cukur manis were collected by one of my colleagues from the National University of Malaysia (UKM), and sent  to the Dept. of Nutrition at Queen Elizabeth College (QEC), University of London where we once studied -  for chemical analysis. There at QEC they used their mass spectrometers and nuclear magnetic resonance (NMR) spectrometers to identify the  compound present. It turned out to be papaverine, a smooth muscle relaxant that has hypotensive properties. Of course we can also use other analytical procedures such as spectroscopy (UV-Vis, FTIR) and chromatography (GC-MS, HPLC-MS), but magnetic resonance (NMR) spectrometers is better, and we did not have that analytical instrument.  

An NMR spectrometer is huge and a complex instrument, not easily visualized without prior knowledge, nor is it easy to use,  but it's essentially a huge machine  that uses strong magnetic fields and radio waves to analyze the magnetic properties of atomic nuclei within a sample. 

NMR (Nuclear Magnetic Resonance) spectroscopy is a powerful tool for elucidating and identifying the molecular structure of a compound. It provides detailed information about the connectivity of atoms within a molecule, as well as their chemical environment, which helps in determining the overall structure.

While not  simple to use, modern benchtop NMR spectrometers have become more user-friendly, with integrated consoles and software to aid in data acquisition and interpretation.

We did not have an NMR spectrometer in Malaysia then in the 1970's, so we sent samples of cukur manis to scientists at the Department of Nutrition and in the Department of Chemistry at Queen Elizabeth College, University of London to help us identify the unknown compound that causes hypotension. The scientists at QEC identified it as papaverine.

2. Nutritional Composition and Traditional Use S. androgynus is commonly consumed in Southeast Asia, known locally as cekur manis (Malay), mani cai (Chinese), or sweet leaf. Rich in iron, protein, vitamins A, B, and C, calcium, potassium, and carotenoids, it has been used traditionally to:

  • Promote lactation

  • Support skin and eye health

  • Improve vitality and digestion

3. Field Observations and Clinical Correlation In the studied villages, the majority of women consumed cekur manis in cooked form, often stir-fried. No cases of respiratory distress or lung disease were reported, but hypotension was consistently noted. This prompted the hypothesis that a phytochemical component in cekur manis might be acting as a vasodilator.

4. Phytochemical Analysis: As already mentioned, laboratory analysis confirmed the presence of papaverine, an opium-derived but non-narcotic alkaloid known for its ability to relax smooth muscle tissues, particularly those of blood vessels. Papaverine’s pharmacological actions include:

  • Dilation of cerebral and coronary arteries

  • Smooth muscle relaxation in the gastrointestinal and genitourinary tracts

  • Temporary blood pressure lowering effects

Although once used in the management of vascular diseases, papaverine is no longer widely prescribed for hypertension due to its:

  • Short duration of action

  • Potential hepatotoxicity

  • GI and CNS side effects

  • Unpredictable pharmacokinetics

The naturally occurring papaverine in cekur manis likely explains the consistent hypotension observed in the villagers, compounded by anaemia from poor iron intake.

5. Toxicity Concerns and International Incidents Between the 1990s and early 2000s, Taiwan and Japan saw multiple cases of bronchiolitis obliterans, a rare and irreversible lung disease, linked to the excessive raw consumption of S. androgynus. Young women consumed large quantities of raw cekur manis in juices or smoothies, often for weight loss or to enhance lactation.

Over 100 cases in Taiwan required long-term oxygen therapy, some requiring lung transplants [Chen et al., 2000].

The suspected mechanism involves certain alkaloids and non-protein amino acids that induce immune-mediated inflammation and fibrotic scarring of bronchioles.

The specific compound in raw Sauropus androgynus (cukur manis) that causes bronchiolitis obliterans has not been definitely identified. However, it is believed that certain compounds within the plant, particularly in the aqueous fraction, may be responsible for inducing lung inflammation and tissue damage. Studies suggest that the aqueous fraction of S. androgynus may play a significant role in the development of the disease. 
Several compounds have been isolated from S. androgynus, including nucleosides,  flavonols, and lignan glycosides, none have been definitively pinpointed as the sole cause of bronchiolitis obliterans.
T-cell Mediated Immunity:
Research indicates that T-cell mediated immunity might be involved in the pathogenesis of lung damage, suggesting an immune response is triggered by the plant's compounds.

Crucially, no cases were associated with cooked cekur manis, suggesting the  toxic compounds is destroyed during cooking (heat-labile).  

6. Recommendations and Public Health Implications Given the dual nature of S. androgynus ,  as a nutrient-dense vegetable and a potential source of toxicity, public education is essential:

Encourage consumption in moderation and only in cooked form, bear in mind cekur manis is  known to be rich in beta-carotene, which is a precursor to vitamin A (retinol). This means that the body can convert the beta-carotene found in cekur manis into vitamin A. Studies have shown that cekur manis contains a high level of total carotenoids, which are converted to retinol equivalents (RE). 

Avoid large quantities of raw cekur manis, especially in juice or smoothie form. Continue research to identify the exact causative toxic compounds

7. Conclusion:

The study highlights how local diets, when examined in conjunction with phytochemical analysis, can reveal both therapeutic and harmful health effects. The vasodilatory property of papaverine in cooked S. androgynus may explain low blood pressure among rural Malaysian women, especially those also affected by anaemia. However, international cases of bronchiolitis obliterans from raw consumption underscore the need for caution. Traditional wisdom and modern science must work hand-in-hand to ensure safe dietary practices.


References:


1, Chen CH, Shih CL, et al. (2000). Sauropus androgynus-induced bronchiolitis obliterans in Taiwan: a review of epidemiology, clinical presentations, and pathogenesis. Am J Respir Crit Care Med, 161(4): 1241–1246. PMID: 10764302

2. Ismail A, et al. (2000). Nutrient composition of selected indigenous vegetables in Malaysia. Food Chemistry, 68: 51–59.

3. Wong KC, Tan GL. (1995). Chemical constituents and biological activities of Sauropus androgynus. Natural Product Communications, 2(6): 199–204.

4. Wu CC, et al. (1997). Obliterative bronchiolitis associated with consumption of Sauropus androgynus in Taiwan. Lancet, 349: 1306.

5. Liu GY, et al. (2006). Papaverine and its pharmacological applications: past, present and future. International Journal of Clinical Pharmacology and Therapeutics, 44(9): 480–488.

Friday, August 22, 2025

The Medicinal Values of Garlic - from Clove to Circulation

 Title: The Biochemistry and Pharmacology of Garlic: From Clove to Circulation


by: Lin Ru Wu alias Lim Ju Boo

 

In the mid 1960's I was doing my postgraduate in Nutrition at the University of London when one of my professors mentioned about the medicinal values of garlic. Today, I like to share further knowledge I gained  there about this valuable medicinal  clove 


Abstract:


Garlic (Allium sativum) has been revered since antiquity for its culinary and medicinal properties. This paper explores the biochemical transformation of garlic's sulfur compounds, particularly allicin and ajoene, through mechanical processing, digestion, and hepatic metabolism. It discusses the pharmacologically active derivatives of garlic, their bioavailability, and the evidence-based therapeutic doses. By synthesizing findings across food chemistry, enzymology, and clinical pharmacology, this work aims to serve as a concise but comprehensive resource for doctors, nutritionists,  healthcare enthusiasts and scholars


1. Introduction:


Garlic is widely recognized for its diverse medicinal applications, including antimicrobial, cardiovascular, and anticancer effects. These properties are attributed to sulfur-containing compounds formed upon cellular disruption of garlic tissues. While traditional knowledge praises garlic's benefits, understanding the journey of its bio-actives from raw clove to systemic circulation requires a multidisciplinary approach.


2. Allicin Formation: The Moment of Activation


Allicin is not present in intact garlic cloves. Upon mincing or crushing, the enzyme alliinase converts the stable compound alliin into allicin within 5 to 10 minutes. This enzymatic reaction is highly sensitive to:

  • Heat (>60°C), which denatures alliinase

  • Acidity, which can reduce enzyme efficiency

Reaction Pathway: Alliin (S-allyl-L-cysteine sulfoxide) + Alliinase → Allicin (diallyl thiosulfinate)

Waiting 10 minutes after crushing allows maximal allicin formation before further cooking or ingestion.


3. Stability and Degradation of Allicin


Allicin is unstable, reactive, and decomposes quickly into secondary sulphur compounds, including:

  • Ajoene (anti-platelet, antifungal)

  • Diallyl disulfide (DADS)

  • Diallyl trisulfide (DATS)

  • S-allyl cysteine (SAC) (stable, bioavailable in aged garlic)

Heat, time, and pH conditions all influence the breakdown pathway.


4. Oral Processing vs Mechanical Mincing


Chewing garlic activates alliinase, but swallowing too quickly reduces time for full allicin conversion. Saliva does not appear to inactivate alliinase significantly, but the enzymatic activity is more reliable in a controlled setting (e.g., mincing and waiting 10 minutes).


5. Gastrointestinal and Hepatic Fate

In the digestive tract:


  • Allicin is mostly degraded in the stomach
  • Derivatives like DADS, DATS, ajoene, and SAC survive and are absorbed

In the liver:

  • Some compounds are metabolized but retain activity

  • SAC is especially bioavailable and used in standardized supplements


6. Pharmacological Activity and Effective Doses


CompoundEffective DoseActivity
Allicin    20–50        mg/day       Antimicrobial,                       antihypertensive
Ajoene    ~10–25         mg/day       Antithrombotic,                   antifungal
SAC    Varies       Antioxidant, anti-                 inflammatory


Garlic supplements are typically standardized to 1.3% allicin content or 3.6 mg per 600 mg tablet. But this value may not be stable on storage as for garlic pills. I shall talk on this later.  

7. Preparation Guidelines for Maximum Medicinal Value

MethodAllicin YieldNotes
Mince + wait 10 min + consume rawMaximumBest for medicinal use
Chewing raw garlicModerateFaster ingestion limits yield
Cooking after 10 min restMildLow heat preserves some value
Aged garlic extractHigh (SAC)Ideal for long-term supplementation


8. Conclusion


While allicin itself is ephemeral, its derivatives may or may not persist and contribute meaningfully to garlic's therapeutic potential. For instance, from the very beginning I mentioned that in the mid 1960's when I was doing my postgraduate in Nutrition at the University of London when one of my professors mentioned about the medicinal values of garlic. But he also told us that they took over two dozens different types of garlic pills manufactured by various companies from various parts of the world and analyzed them for the presence of ajoene, the derivative of allicin since allicin is not stable. What the researchers at London University found was, even ajoene which was supposed to be more stable was not present in any of those hundreds of garlic pills. This implied that even the derivatives of allicin - ajoene is not stable when the garlic was processed into pill form or when stored in a bottle for sales. Probably garlic pills were  just oils - like any vegetable oil with no medicinal values in them?  

My strong advised is, when raw garlic has been minced or crushed, wait for at least 10 minutes for the enzyme alliinase to release the allicin and consume immediately - not longer than a few hours later. We are unsure if storing the minced raw garlic in a refrigerator will retain its medicinal values - allicin and its derivatives - DADS, DATS, ajoene, and SAC, since as far as I know, no study has been done on this. 


Understanding garlic as a sequence of biochemical transformations, from mechanical activation to hepatic metabolism, enables more effective use of this ancient botanical medicine.


References


1. Amagase H, Petesch BL, Matsuura H, Kasuga S, Itakura Y. Intake of garlic and its bioactive components. J Nutr. 2001 Mar;131(3s):955S-962S.

2. Lawson LD, Wang ZJ. Allicin and allicin-derived garlic compounds increase breath acetone through allyl methyl sulfide: Use in measuring functional allicin in garlic. J Agric Food Chem. 2005;53(6):1974-1983.

3. Dirsch VM, Kiemer AK, Wagner H, Vollmar AM. Effect of allicin and ajoene, two compounds of garlic, on inducible nitric oxide synthase. Atherosclerosis. 1998;139(2):333-339.

4. Rahman K. Effects of garlic on platelet biochemistry and physiology. Mol Nutr Food Res. 2007;51(11):1335-1344.

5. Iciek M, Kwiecien I, Wlodek L. Biological properties of garlic and garlic-derived organosulfur compounds. Environ Mol Mutagen. 2009;50(3):247-265.


Acknowledgments:

 Special gratitude to my friend and colleague, Professor Sage for his additional inputs that has inspired me to write this paper

Monday, August 18, 2025

Medicines in Mushrooms

 A paper  presented by Professor Dr Ong Wei Yi from the National University of Singapore and his colleagues on 


"Ergothioneine Treatment Ameliorates the Pathological
Phenotypes of Parkinson's Disease Models" 


This paper was presented at the 8th International Anatomical Sciences and Cell Biology Conference on 14 and 15th August, 2025 in Kuala Lumpur. Malaysia 



Nature’s Healing Arsenal in Foods

 

Nature’s Healing Arsenal: Functional Foods and Phytochemicals in Disease Prevention and Therapy


by: 


Nutritionist Lim Ju Boo and Professor Dr M Sage MD PhD  


Abstract


Functional foods are increasingly recognized for their capacity to promote health and reduce the risk of chronic diseases. Beyond providing essential nutrients, these foods contain hundreds, if not thousands, of phytochemicals and bioactive compounds. These compounds, including ergothioneine in mushrooms, sulforaphane in broccoli sprouts, curcumin in turmeric, and catechins in green tea, play vital roles in modulating oxidative stress, inflammation, metabolism, and immunity. This article provides a comprehensive overview of selected functional foods and their phytochemicals, with emphasis on mechanisms of action, disease-preventive roles, and evidence from clinical studies.


Introduction


The concept of functional foods extends beyond basic nutrition. These are everyday foods that confer specific physiological benefits or reduce disease risk, thanks to their natural bioactive components. Phytochemicals, a diverse class of plant- and microbe-derived compounds, exert health-promoting effects by interacting with cellular pathways. Unlike vitamins and minerals, phytochemicals are not considered essential nutrients, yet their presence in the human diet is associated with reduced risk of non-communicable diseases such as cardiovascular disease, cancer, diabetes, and neurodegeneration.

Among the wide array of bioactives, certain compounds stand out due to their robust mechanistic evidence and clinical evaluation. These include ergothioneine and β‑glucans from mushrooms, sulforaphane from cruciferous vegetables, curcumin from turmeric, epigallocatechin gallate (EGCG) from green tea, organosulfur compounds from garlic, lycopene from tomatoes, and isoflavones from soy. Their health effects are mediated by key molecular pathways including activation of antioxidant defenses, suppression of pro-inflammatory signals, modulation of lipid and glucose metabolism, and regulation of immune responses.

Ergothioneine: The Longevity Molecule from Mushrooms

Ergothioneine is a sulphur-containing antioxidant produced by fungi and some bacteria, but not by plants or animals. Humans acquire it exclusively through diet, with mushrooms being the richest source. Ergothioneine is transported into cells by the specific transporter OCTN1 (SLC22A4) and preferentially accumulates in tissues exposed to high oxidative stress such as the liver, kidneys, brain, and eyes. It functions as a cytoprotectant, scavenging reactive oxygen species, preserving mitochondrial function, and reducing inflammation.

Recent studies suggest that lower plasma ergothioneine levels are associated with faster cognitive decline in older adults, raising the possibility that it may be a conditionally essential nutrient. Regular consumption of a variety of mushrooms, such as shiitake, oyster, or king trumpet mushrooms, can help increase ergothioneine intake and simultaneously deliver β‑glucans with immune-modulating effects (Tian et al., 2023; Fu et al., 2022).

β‑Glucans: Immune and Metabolic Regulators

β‑Glucans are polysaccharides found in both cereals (such as oats and barley) and fungi (mushrooms and yeast). Their health benefits differ depending on the source. Cereal-derived β‑glucans form viscous gels in the gut, lowering LDL cholesterol by reducing intestinal absorption of cholesterol and increasing bile acid excretion. Large meta-analyses consistently show that consumption of 3 g/day of oat β‑glucan significantly reduces LDL cholesterol and improves lipid profiles (Yu et al., 2022; Noronha et al., 2023).

Fungal β‑glucans, on the other hand, interact with innate immune receptors such as Dectin‑1 and Toll-like receptors, priming immune cells and enhancing their pathogen-fighting ability. This “trained immunity” effect has implications for infection control and oncology, with β‑glucan supplements from mushrooms like shiitake and reishi under active clinical investigation (Cerletti et al., 2021).

Sulforaphane: A Cruciferous Defender

Broccoli sprouts are an exceptional source of sulforaphane, an isothiocyanate derived from glucoraphanin through enzymatic action by myrosinase. Sulforaphane potently activates the Nrf2 pathway, which regulates the expression of antioxidant and detoxification enzymes such as heme oxygenase‑1 and glutathione S‑transferases. In doing so, it enhances the body’s defense against oxidative damage and inflammation. Sulforaphane also influences mitochondrial function and has shown neuroprotective and anticancer properties in experimental models. Human trials indicate promising biomarker improvements, although outcome data remain mixed, often due to variability in preparation and bioavailability (Yan et al., 2024; Bessetti et al., 2025).

Curcumin: Golden Spice with Broad Potential

Curcumin, the active pigment of turmeric, is a pleiotropic molecule that targets multiple signaling pathways. It downregulates NF‑κB, a master regulator of inflammation, and influences epigenetic enzymes involved in gene regulation. Clinical studies and meta-analyses have demonstrated its efficacy in reducing C-reactive protein (CRP), tumor necrosis factor‑α, and markers of oxidative stress. Curcumin has shown benefits in conditions such as arthritis, metabolic syndrome, and certain cancers. However, its low bioavailability has limited its clinical translation, and modern formulations using piperine, phospholipids, or nanoparticles are helping to overcome this challenge (Dehzad et al., 2023; Lee et al., 2024).

Epigallocatechin Gallate (EGCG): Green Tea’s Polyphenolic Star

Green tea is rich in catechins, with EGCG being the most studied. EGCG influences multiple signaling cascades including AMPK activation, PI3K/Akt/mTOR inhibition, and suppression of NF‑κB. It exhibits anti-inflammatory, cardioprotective, and anticancer properties. Clinical evidence supports its role in improving cardiovascular risk markers and as a potential adjunct in oncology. However, caution is warranted with high-dose extracts due to rare cases of hepatotoxicity, whereas brewed green tea remains a safe and effective option (Capasso et al., 2025).

Garlic Organosulfur Compounds: Traditional Medicine with Modern Proof

Garlic has been used for centuries as both food and medicine. Its organosulfur compounds, such as allicin, diallyl disulfide, and S‑allyl‑cysteine, exhibit antimicrobial, antioxidant, and cardiovascular benefits. Mechanistically, these compounds act as hydrogen sulfide donors, reduce platelet aggregation, and modulate lipid metabolism. Clinical studies support modest reductions in blood pressure and cholesterol with garlic consumption, with effects varying by preparation type (Seki et al., 2025; El‑Saadony et al., 2024).

Lycopene: The Tomato’s Red Shield

Lycopene, a carotenoid found abundantly in tomatoes, is a powerful singlet oxygen quencher. It accumulates in tissues such as the prostate and adrenal glands, influencing signaling pathways including insulin-like growth factor‑1. Observational studies and meta-analyses have linked higher lycopene intake to reduced cancer risk, particularly prostate cancer, and lower overall cancer mortality. Lycopene absorption is enhanced by cooking and co-consumption with oils, making tomato-based dishes with olive oil particularly beneficial (Balali et al., 2025).

Isoflavones: Soy’s Phytoestrogenic Benefits

Soy isoflavones, particularly genistein and daidzein, act as selective estrogen receptor β agonists. They modulate tyrosine kinase activity and influence epigenetic regulation. Clinical evidence supports their role in reducing menopausal symptoms, improving bone health, and supporting cardiovascular function. Their impact on hormone-sensitive cancers is complex and context-dependent, requiring individualized dietary advice (Sharifi‑Rad et al., 2021; Zhang et al., 2025).


Summary Conclusion: 


Functional foods and their phytochemicals form a natural arsenal against chronic disease. They modulate oxidative stress, inflammation, immune defense, and metabolic regulation, offering preventive and adjunctive benefits. A food-first approach, emphasizing mushrooms, crucifers, turmeric, green tea, garlic, tomatoes, soy, oats, and barley, provides a practical and safe way to harness these benefits. While supplements may be useful in targeted cases, dietary integration remains the most sustainable strategy. More research is needed to define optimal intake levels, bioavailability strategies, and long-term clinical outcomes, but the existing evidence strongly supports their role in human health.


References


1. Tian X, et al. Ergothioneine: an underrecognised dietary micronutrient. Biochem J. 2023.

2. Fu TT, et al. Ergothioneine as a Natural Antioxidant Against Oxidative Damage. Front Pharmacol. 2022.

3. Cerletti C, et al. Edible Mushrooms and Beta‑Glucans: Impact on Human Health. Nutrients. 2021.

4. Yu J, et al. Effects of Oat Beta‑Glucan Intake on Lipid Profiles: Meta‑analysis. Nutrients. 2022.

5. Noronha JC, et al. Effect of Oat Beta‑Glucan on LDL‑C, non‑HDL‑C and apoB: SRMA. Eur J Clin Nutr. 2023.

6. Yan Z, et al. Sulforaphane’s NRF2 and Antiviral Activities. iScience/Cell Rep Med. 2024.

7. Bessetti RN, et al. Sulforaphane neuroprotection review. Front Neurosci. 2025.

8. Dehzad MJ, et al. Antioxidant and anti‑inflammatory effects of curcumin/turmeric: Meta‑analysis of RCTs. Phytother Res. 2023.

9. Lee YM, et al. Is Curcumin Intake Really Effective for Chronic Inflammation? Nutrients. 2024.

10. Capasso L, et al. EGCG: Pharmacological Update. Pharmaceutics. 2025.

11. Seki T, et al. Functionality of garlic sulfur compounds (Review). Exp Ther Med. 2025.

12. El‑Saadony MT, et al. Garlic bioactive substances and therapeutic applications. Front Immunol. 2024.

13. Balali A, et al. Dietary and blood lycopene with cancer risk/mortality: Meta‑analysis. Nutrients. 2025.

14. Sharifi‑Rad J, et al. Genistein: Mode of Action & Health Outcomes. Nutrients. 2021.

15. Zhang K, et al. Genistein mechanisms in oxidative stress & inflammation. Antioxidants. 2025.


Disclaimer: This article is for educational purposes only and is not a substitute for individualized medical advice. Always consult healthcare professionals such as a qualified nutritionist or a dietician before making major dietary or supplement changes.

Sunday, August 17, 2025

Paper on the Management of Dementia by Traditional Chinese Medicine

 A paper on the Treatment of Dementia by Traditional Chinese Medicine by Professor Dr Ong Wei Yi et al  

Department of Anatomy, Yong Loo Lin School of Medicine, National University of Singapore   Chair, LSI Neurobiology Programme Steering Committee, NUS Centre for Life ..


https://sg.docworkspace.com/d/sIPzrptKmAr2tiMUG?sa=601.1074


https://link.springer.com/article/10.1007/s12035-018-0908-0

Are We Saved by Faith Alone or by Our Good Works - a Christian Perspective

 Last evening, Saturday, 16 August, 2025 I was having a family dinner with Professor  Dr  Ong  Wei Yi who is my nephew from the National University of Singapore.

He was here in Kuala Lumpur with his pharmacist wife Lim Siew Mei for a two day conference on Neuroanatomy where he presented a paper. 

During dinner we talked about Christianity, and he being a Christian probably belonging to the protestant church told me  we receive Salvation from Jesus through faith alone. I did not discuss this one single sentence further with him as I seldom see him, and there were so many other stories to talk about. 

Today, being a Sunday, 18 August 2025 I had lunch with my nephew Vincent Lee who was also present during dinner last evening. He told me his late wife (my niece) and their daughter are both Catholic. 

After lunch I decided to remain at home to pen my personal view all day long till night on this, both from the Catholic, Protestant and Orthodox point of view. 

I would now like to dedicate my independent thoughts to Wei Yi and probably for Vincent's daughter also, though she was absent for dinner or lunch 


Here's my combination thoughts guided silently through my still small voice: 


Faith, Works, and the Still Small Voice: Catholic, Protestant, and Orthodox Perspectives on Salvation


Abstract


The question of salvation is,  whether by faith, works, or both,  has long divided Christians. Catholics, Protestants, and Orthodox believers who hold different emphases, yet all agree that authentic faith must express itself in love and action.

Catholics

Salvation is a lifelong process through faith, good works, and sacraments (James 2:17; Matthew 25:31–46).


Protestants

Salvation is by grace through faith alone (sola fide), not by works (Ephesians 2:8–9). Yet, true faith always produces fruit (James 2:18).


Orthodox

Salvation is theosis (union with God), where faith transforms the believer into Christ-likeness, expressed in love (John 13:35).

All three traditions recognize the role of conscience, namely, the “still small voice” (1 Kings 19:12) — guiding believers to act in mercy and compassion. Without faith, conscience falls silent; without conscience, works lose meaning; without works, faith is dead (James 2:26).


The Catholic View

The Catholic Church teaches that salvation is a lifelong journey involving faith, good works, and the sacraments. Faith opens the door to God’s grace, but grace must be lived out in action.

“Faith by itself, if it has no works, is dead” (James 2:17).

Jesus’ parable of the Sheep and the Goats teaches that those who feed the hungry, clothe the naked, and visit the sick will inherit the kingdom (Matthew 25:31–46).

Conscience is central in Catholic teaching, described as “the inner voice of God’s law written on our hearts” (Romans 2:15). Catholics believe that to ignore conscience is to turn away from God. Faith, guided by conscience, naturally bears fruit in works of mercy.


The Protestant View

Protestants emphasize salvation by grace through faith alone (sola fide). They turn often to Paul’s words:

“For by grace you have been saved through faith, and this is not your own doing; it is the gift of God, not a result of works, so that no one may boast” (Ephesians 2:8–9).

Good works cannot earn salvation. However, genuine faith is never idle. As James challenges:
“Show me your faith apart from your works, and I will show you my faith by my works” (James 2:18).

For Protestants, conscience is guided by Scripture alone (sola Scriptura). Faith awakens the heart, and conscience confirms the call to love and service. Luther himself said that “faith is a living, busy, active, mighty thing,” always bearing good fruit (Galatians 5:6).


The Orthodox View

The Eastern Orthodox Church understands salvation as theosis , a lifelong process of becoming united with God. Faith begins this journey, but it must grow through prayer, worship, and works of love.

Jesus said: “By this all men will know that you are my disciples, if you have love for one another” (John 13:35). To believe in Christ is to walk as He walked, showing mercy, forgiving, and healing.

Orthodox spirituality calls conscience the “eye of the soul.” But sin can darken it (John 3:19–21). Through prayer, fasting, and sacraments (like confession and Eucharist), conscience is purified, enabling believers to follow God’s will more fully.

Good works are not “duties” but the natural overflow of divine love. As Paul writes: “It is God who works in you, both to will and to work for his good pleasure” (Philippians 2:13).


A Comparative Glance

AspectCatholic ChurchProtestant ChurchesEastern Orthodox Church
AuthorityBible (73 books) + Tradition + Magisterium (Pope, bishops).Bible alone (sola Scriptura, 66 books).Bible (Septuagint tradition) + Holy Tradition (Fathers, liturgy).
SalvationFaith + works + sacraments (James 2:17; Matthew 25:31–46).Grace through faith alone (Ephesians 2:8–9); works as fruit (James 2:18).Theosis: lifelong union with God (2 Peter 1:4).
FaithOpens grace; must be lived out (Galatians 5:6).Central and sufficient; true faith is active (Romans 3:28).Seed of divine life, transforming into Christ-likeness (John 17:21).
WorksNecessary fruit; evidence of faith (James 2:26).Evidence of faith, not basis of salvation (Ephesians 2:10).Outflow of divine love (John 13:35).
ConscienceInner voice of God’s law (Romans 2:15).Guided by Scripture; confirms faith (Hebrews 9:14).“Eye of the soul,” purified by prayer (1 Timothy 1:5).
Jesus’ TeachingsMatthew 25; Sermon on the Mount (Matthew 5–7).John 3:16; Romans 5:1; James 2:18–26.John 13:35; Matthew 6:33; Luke 6:36.


Faith and Works Together

Despite differences, all traditions agree: faith and works cannot be separated. Jesus Himself never said “faith alone.” Instead, He tied faith to action:

1. The Good Samaritan: “Go and do likewise” (Luke 10:25–37).
2. The Rich Man and Lazarus: condemned for ignoring mercy (Luke 16:19–31).
3. The Sheep and the Goats: judged by acts of compassion (Matthew 25:31–46).
4. The Sermon on the Mount: blessed are the merciful, peacemakers, and pure in heart (Matthew 5:3–10).
*Not everyone who says ‘Lord, Lord’ will enter the kingdom, but he who does the will of my Father” (Matthew 7:21).

5. To “believe in Him” (John 3:16) means to trust Him fully, follow His example, and live His teachings.

My Personal Conclusion

Faith, conscience, and works are not rivals but companions.

Faith is the root.


Conscience is the sap that carries life through the soul.


Good works are the fruit seen by the world.


Without faith, conscience falls silent; without conscience, works lose meaning; without works, faith is barren (James 2:26).

Though Catholics, Protestants, and Orthodox differ in emphasis, the call of Christ is the same: to let faith awaken conscience, and let conscience lead to works of mercy, for in doing so, we walk in His footsteps.

Auscultation: A Clinical Perspective

  Auscultation and the Stethoscope: A Clinical Perspective by: lin ru wu alias  lim ju boo Introduction: Auscultation is one of the most ven...