What Was Observed? (Introduction)
- The study explores the idea that cognition and sentience, or the ability to experience, can exist in many types of systems, not just those with brains.
- It challenges the old belief that mental functions must be tied to specific brain structures and shows that diverse systems, including non-neural systems like plants or engineered robots, can also exhibit cognitive abilities.
- The idea is that cognition can be realized in different substrates (or mediums), like non-living materials or synthetic entities like cyborgs, which might act intelligently even if they don’t have a biological brain.
What is Sentience and Cognition?
- Sentience refers to the capacity to experience subjective thoughts and feelings, like pain or joy.
- Cognition refers to mental functions like thinking, learning, decision-making, and adapting to new information.
- Traditionally, scientists believed only organisms with complex brains could display cognition or sentience.
- Recent discoveries show that even simpler systems, such as single cells, plants, or even robots, can display forms of cognition and decision-making.
How Can Cognition Be Realized in Different Systems? (Multiple Realizability)
- Cognition is “multiply realizable,” which means it can appear in many different forms across various systems and substrates (materials or biological components).
- For example, both machines and biological organisms can perform computations (like solving problems or making decisions) but with different mechanisms.
- Some non-neural organisms (like slime molds or plants) show behaviors that suggest they can learn, adapt, and solve problems, even without a brain or nervous system.
- This suggests that cognition does not require a brain and can emerge in different kinds of systems with the right properties for processing information.
Can We Expand the Definition of Cognition Beyond Biological Systems?
- The paper argues that cognition is not limited to living systems. It can also be realized in bio-engineered systems or synthetic intelligence (AI).
- These systems could include cyborgs (a mix of biological and mechanical components), robots with artificial intelligence, and even materials that can process information.
- The challenge is to identify what kinds of elements are necessary to create systems that can process information, learn, and adapt.
- Instead of asking about which specific system (like a brain) is required for cognition, we should focus on the abstract elements needed to create any cognitive system.
What Is the Difference Between Adaptation and Learning?
- Learning typically refers to a system’s ability to change based on previous experiences or inputs. This can be seen in animals, cells, and even machines.
- However, similar processes in simple organisms or non-living materials are often called “adaptation” instead of learning, despite being fundamentally the same.
- The paper argues that these arbitrary distinctions should be removed, allowing us to view all systems that exhibit similar behaviors as performing cognitive functions, regardless of their composition (biological or mechanical).
Sentience in Non-Neural Systems (What Is It Like to Be Something Else?)
- Sentience, or the ability to experience things, is a private process that cannot be directly observed or measured. We infer it by looking at behaviors (like how something moves or reacts).
- The challenge is that many systems (like single cells or robots) might display intelligent behaviors, but we can’t be sure if they are “experiencing” anything.
- Humans often assume other beings are sentient if they show similar behaviors to us. However, the paper warns that this approach might miss sentience in systems that behave differently, like non-human animals or artificial intelligence.
What Are the Minimal Requirements for Sentience? (Complexity and Scale)
- The paper asks whether sentience can exist in simpler systems, like individual cells or single neurons, or if it only emerges when many cells work together in complex organisms.
- While individual cells show behaviors like decision-making and learning, it’s still unclear if they experience subjective states like humans do.
- The paper suggests that we might need to rethink the scale and complexity required for sentience, recognizing that even small systems might have some form of experience.
How Can Bioengineered Systems Help Us Understand Cognition?
- Advances in bioengineering, like creating hybrid robots (called “hybrots”), have opened new avenues for studying cognition in non-biological systems.
- Hybrots involve biological cells controlling robots, allowing scientists to test how cells respond to sensory input and how these responses can lead to intelligent behavior.
- Bioengineering also allows us to create modular neural circuits in the lab to isolate and study specific cognitive functions, which can give insights into how cognition might arise in other types of systems.
Ethical Considerations (New Ethical Frameworks)
- As our understanding of cognition broadens, we will need new ethical frameworks to consider systems that may not share our biological makeup or evolutionary history, such as cyborgs, synthetic intelligences, or bioengineered beings.
- Traditional distinctions between “sentient” beings (like animals) and “mechanical” systems (like machines) are no longer sufficient. These old labels are becoming outdated as more diverse types of cognitive systems are created.
- The ethical challenge is to develop ways to treat all systems fairly and ethically, regardless of whether they are made of biological material or synthetic components.
Key Conclusions (Discussion)
- The concept of cognition is far more expansive than previously thought. It is not limited to brains and can emerge in a variety of systems, including non-neural and synthetic ones.
- Sentience is likely more widespread than we realize, and we must develop new ways to detect and interact with sentient systems that do not fit traditional categories.
- As technology progresses, we will need to reconsider old ethical frameworks and develop new approaches to address the ethical implications of interacting with diverse forms of sentience.