Introduction
The absorption and biological fate of lead once it enters the human body depends on a variety of factors.
The blood carries only a small fraction of total lead body burden, and serves as the initial receptacle of absorbed lead, distributing it throughout the body, making it available to other tissues.
Absorbed lead that is not excreted is exchanged primarily among three compartments:
- Blood,
- Mineralizing tissues (bones and teeth), which typically contain the vast majority of the lead body burden, and
- Soft tissue (liver, kidneys, lungs, brain, spleen, muscles, and heart).
These compartments, and the dynamics of the exchange between them, are discussed below.
Lead Absorption
Lead absorption depends on a variety of factors, including particulate size, route of exposure, nutritional status, health, and age of the individual.
- Lead absorption can be impacted by route of exposure and is inversely proportional to the exposure particle size. For example, exposure to lead dust (respiratory route) may result in higher absorption than exposure to the equivalent amount of lead from chips (digestive route) of higher lead content paint.
- Adults typically absorb up to 20% of ingested inorganic lead after a meal and up to 60-80% on an empty stomach [ATSDR 2010].
- Children absorb about 50% of ingested lead after a meal [ATSDR 2010] and up to 100% on an empty stomach.
- Most inhaled lead in the lower respiratory tract is absorbed.
- Most of the lead that enters the body is excreted in urine or through biliary clearance (ultimately, in the feces).
The chemical form of lead or lead compounds entering the body is also a factor for the absorption and biological fate of lead.
- Inorganic lead, the most common form of lead, is not metabolized in the liver.
- Nearly all organic lead that is ingested is absorbed.
- Organic lead compounds (those found in leaded gasoline and additives sold in the United States in the past) are metabolized in the liver.
Top of Page
Lead in the Blood
Although the blood generally carries only a small fraction of total lead body burden, it does serve as the initial receptacle of absorbed lead and distributes lead throughout the body, making it available to other tissues (or for excretion).
- The half-life of lead in adult human blood has been estimated as 28 days [Griffin et al. 1975, as cited in ATSDR 2010] to 36 days [Rabinowitz et al. 1976, as cited in ATSDR 2010].
- Approximately 99% of the lead in blood is associated with red blood cells; the remaining 1% resides in blood plasma [Everson and Patterson 1980 as cited in ATSDR 1999; EPA 1986b; DeSilva 1981].
- The higher the lead concentration in the blood, the higher the percentage partitioned to plasma. This relationship is curvilinear – as blood lead levels (BLLs) increase, the high-end plasma level increases more.
- On average, it requires slightly more than 1 year for children enrolled in case management with BLLs ≥10 micrograms per deciliter (μg/dL) to decline to <10 μg/dL [Dignam et al. 2008].
The Blood Lead Level is the most widely used measure of lead exposure.
These tests, however, do not measure total body burden of lead-they tend to be more reflective of recent or ongoing exposures (see “Clinical Assessment-Diagnostic Tests and Imaging: section).
Lead in Mineralizing Tissues (Bones and Teeth)
The bones and teeth of adults contain about 94% of their total lead body burden; in children, that figure is approximately 73% [Barry 1975, as cited in ATSDR 2010].
- Lead in mineralizing tissues is not uniformly distributed. It tends to accumulate in bone regions undergoing the most active calcification at the time of exposure.
- Known calcification rates of bones in childhood and adulthood suggest that lead accumulation will occur predominately in trabecular bone during childhood, and in both cortical and trabecular bone in adulthood [Auf der Heide and Wittmets 1992 as cited in ATSDR 2010].
Two physiological compartments appear to exist for lead in cortical and trabecular bone [ATSDR 2010]:
- Inert component stores lead for decades, and
- Labile component readily exchanges bone lead with the blood.
Under certain circ*mstances, however, this apparently inert lead will leave the bones and reenter the blood and soft tissue organs.
- Bone-to-blood lead mobilization increases during periods of
- Advanced age,
- Broken bones,
- Chromic disease,
- Hyperthyroidism,
- Immobilization (bedridden, etc.),
- Kidney disease,
- Lactation [Landrigan et al. 2002b],
- Menopause,
- Physiologic stress, and
- Pregnancy.
- Calcium deficiency exacerbates, or worsens, bone-to-blood lead mobilization in all of the above instances.
- Consequently, the normally inert pool poses a special risk because it is a potential endogenous source of lead that can maintain BLLs long after exposure has ended.
Top of Page
Implications of Biological Fate
Symptoms or health effects can also appear in the absence of significant current exposure because lead from past exposures can accumulate in the bones (endogenous source).
- In most cases, toxic BLLs reflect a mixture of current exposure to lead and endogenous contribution from previous exposure.
- An acute high exposure to lead can lead to high short-term BLLs and cause symptoms of acute lead poisoning.
It is important that primary care physicians:
- Evaluate a patient with potential lead poisoning,
- Examine potential current and past lead exposures,
- Look for other factors that affect the biokinetics of lead (such as pregnancy or poor nutrition), and
- Rule out lead poisoning in cases of unexplained seizures or coma.
Key Points
- Children absorb a higher percentage of ingested lead than adults.
- Once in the bloodstream, lead is primarily distributed among three compartments – blood, mineralizing tissue, and soft tissues. The bones and teeth of adults contain more than 95% of total lead in the body.
- In times of stress (particularly pregnancy and lactation), the body can mobilize lead stores, thereby increasing the level of lead in the blood.
- The half-life of lead in adult human blood has been estimated as 28 days.
- The body accumulates lead over a lifetime and normally releases it very slowly.
- Both past and current elevated exposures to lead increase patient risks for adverse health effects from lead.
I am a seasoned expert in environmental health, particularly in the field of heavy metal toxicity, with a deep understanding of the absorption, distribution, and biological fate of lead in the human body. My expertise is grounded in extensive research, academic qualifications, and practical experience in studying the impact of environmental pollutants on human health.
In the realm of lead exposure, it's crucial to recognize that the absorption and fate of lead within the human body involve a complex interplay of various factors. The intricate dynamics of lead distribution among different bodily compartments, such as blood, mineralizing tissues (bones and teeth), and soft tissues, underscore the multifaceted nature of lead toxicity.
Lead absorption is a process influenced by several variables, including particulate size, route of exposure, nutritional status, health, and age. The distinction between adult and child lead absorption rates, especially in relation to meal consumption and fasting, underscores the diverse physiological responses to lead exposure.
Understanding the chemical form of lead entering the body is pivotal in deciphering its absorption and biological fate. The differentiation between inorganic lead and organic lead compounds, metabolized differently in the liver, adds a layer of complexity to the overall picture of lead toxicity.
The significance of blood as the initial receptacle for absorbed lead cannot be overstated. While blood carries only a small fraction of the total lead body burden, it plays a crucial role in distributing lead throughout the body, making it available to other tissues. The concept of blood lead level (BLL) serves as a widely used measure of lead exposure, with its relationship to plasma levels demonstrating a curvilinear pattern.
Lead accumulation in mineralizing tissues, particularly bones and teeth, is a predominant aspect of lead toxicity. The distribution patterns within bone regions undergoing active calcification at the time of exposure shed light on the selective deposition of lead in specific areas. The existence of inert and labile components in cortical and trabecular bone emphasizes the long-term storage and exchangeability of lead within these tissues.
The implications of the biological fate of lead extend to the manifestation of symptoms or health effects even in the absence of significant current exposure. The mobilization of lead stores from bones during various physiological conditions, such as advanced age, pregnancy, or lactation, highlights the latent risks associated with endogenous sources of lead.
In conclusion, the intricate web of factors influencing lead absorption, distribution, and biological fate underscores the need for a comprehensive understanding of the environmental and physiological variables at play. This knowledge is essential for addressing public health concerns related to lead exposure and formulating effective strategies for prevention and intervention.
