How to Improve Eyesight Through Proper Food Selection

Beri means słaby in Chinese. Berry-berry disease appeared in the late 19th century in China. Thousands of victims lived near the stations and it was originally thought that the disease was caused by bacteria. Years later, the real cause was found. Near the railway lines, people could buy white (polished) rice. In later areas, brown rice was still consumed (unpolished). People assumed that white rice, which by modern machine-made techniques was removed from the outer layer of the stomach (toxin), because it was better.

The majority of ophthalmic disorders are intrinsically linked to retinol deficiency, manifesting clinically as nyctalopia (impaired twilight vision, colloquially termed "night blindness"), xerophthalmia (chronic dryness of the conjunctiva), or inflammatory conditions affecting ocular structures. A preliminary self-assessment of dark adaptation can be conducted by transitioning from a brightly lit environment to a darkened space and timing the duration required for visual acclimatization. An adaptation period of 2–5 seconds is considered physiologically normal; prolongation to 7–8 seconds may indicate a mild deficiency, whereas an adaptation exceeding 10–15 seconds warrants an ophthalmological evaluation. Ensuring adequate retinol intake is straightforward, as it is abundant in both animal-derived sources (preformed vitamin A, including retinol and its esters) and plant-based foods (provitamin A carotenoids, primarily β-carotene). The most concentrated sources include fish liver oils, organ meats (particularly liver), full-fat dairy products, egg yolks, and deeply pigmented leafy vegetables (e.g., carrots, spinach, kale, apricots, tomatoes, bell peppers). It is critical to note that retinol is highly susceptible to degradation from external factors—such as prolonged heat exposure, ultraviolet radiation, and extended storage—thus emphasizing the importance of consuming fruits and vegetables raw or with minimal thermal processing (e.g., steaming, brief blanching). Both retinol deficiency and excess pose significant health risks. Hypovitaminosis A may result in corneal ulceration, compromised epithelial immunity, and in severe cases, irreversible blindness. Conversely, hypervitaminosis A can induce hepatotoxicity, epidermal desquamation, alopecia, peripheral neuropathy, and painful osseous abnormalities, particularly in the long bones.

Excessive consumption of animal-derived fats—particularly saturated fats—may contribute to the development of arterial stiffness, thereby impairing the body’s ability to maintain optimal blood pressure regulation. This condition can also exert detrimental effects on the structural integrity and functional capacity of the visual system. Dietary guidelines recommend limiting the intake of foods rich in saturated fats, including fatty cuts of meat, high-fat sauces, lard, heavy cream, butter, and processed foods containing these components. Instead, preference should be given to plant-based fats, which provide essential unsaturated fatty acids. Furthermore, high meat consumption is not advisable; the body’s protein requirements should be met primarily through plant-based sources. Particular attention should be paid to soy protein and its derivatives—such as tofu, miso, and tempeh—which are gaining increasing recognition in Western markets. Additionally, whole grains, a variety of nuts and seeds, and legumes—including multiple bean varieties, lentils, spinach, and broccoli—serve as valuable sources of amino acids.

Excessive intake of sucrose and confectionery items may serve as a significant risk factor for the development of glycemic disorders, particularly when it results in android-type obesity (commonly referred to as abdominal obesity), which exhibits a strong correlation with insulin resistance. Furthermore, patients diagnosed with type 2 diabetes frequently experience diminished visual acuity as a consequence of diabetic retinopathy. From a historical standpoint, sucrose was regarded for centuries as a substance of limited availability—its distribution was confined exclusively to pharmacies, where it functioned as a specialized laboratory reagent. During that era, bee honey remained the primary source of sweetness, though its procurement demanded substantially greater labor input compared to modern refined sugar production. Presently, the landscape has undergone a radical transformation: honey has become a niche commodity, whereas sugar has evolved into an omnipresent and excessively consumed dietary component.

In numerous individuals, impaired visual function often stems not from primary ophthalmic conditions but rather from the cumulative systemic burden imposed by a diverse array of biologically dubious substances that chronically tax the body. This category encompasses not only the factors previously outlined but also ubiquitous consumer products: sugar-laden carbonated and isotonic beverages, ethanol in all its forms, caffeine derived from coffee and other stimulants, as well as pharmaceutical agents used in an uncontrolled manner or at doses exceeding prescribed limits. Prolonged overreliance on medicinal preparations—whether their efficacy is scientifically validated or merely perceived through subjective belief in their benefits (the placebo phenomenon)—gradually depletes the body’s innate self-regulatory capacities, thereby compromising its ability to sustain physiological equilibrium.

The most reliable indicator of how our dietary patterns influence overall health—including visual function—proves to be the deliberate practice of fasting. When systematically implemented under the guidance of a nutrition specialist, this approach yields measurable preventive and therapeutic benefits. Above all, it helps mitigate the risk of developing—or alleviates symptoms of—conditions closely linked to poor nutritional habits. Throughout this detoxification process, maintaining adequate hydration is paramount; consuming substantial quantities of high-quality spring water or natural grape juice facilitates the removal of accumulated toxins from the body. Typically, after approximately 48 hours, sensations of hunger diminish, giving way to a renewed sense of lightness and heightened energy. However, transitioning out of this state requires a gradual reintroduction of food: beginning with small portions of easily digestible meals consumed at a leisurely pace, with full attention devoted to thorough mastication and mindful savoring of each bite. It is critical to emphasize that all forms of fasting or food abstinence should be discussed with a healthcare provider and conducted under the supervision of a qualified dietitian. Notably, this period presents an opportune moment to monitor potential improvements in visual acuity. Should a significant enhancement in this area be observed, it may serve as a compelling incentive to thoroughly reassess existing dietary practices and implement modifications that promote sustained physical and mental well-being.

Optimal conditions for meal consumption involve creating an environment that fosters focus and inner tranquility. Distracting activities—such as engaging in intense conversations, watching television, or using electronic devices—should be avoided, and above all, one must refrain from eating while emotionally agitated, angry, or stressed. Research confirms that full mental engagement in the act of eating, both physically and cognitively, significantly enhances nutrient absorption. Just as vision achieves its sharpest clarity when fixated on a single object, digestion operates most efficiently when the body and mind collaborate in harmony, free from unnecessary external stimuli.