This has, unexpectedly, little or nothing to do with PHP. It's not PHP that answers the user's request but the web server. For example Apache, NginX, IIS, and so on.
The web server then routes the call to a PHP instance that is usually independent of any other request being satisfied in that exact moment. The number of concurrent requests depends on the server configuration, architecture, and platform capabilities. So-called "C10K" servers are designed to front up to ten thousand connections simultaneously.
But PHP is not the only factor in the process that goes from "GET /index.php" to a bunch of HTML; any active page (PHP or ASP or Python etc.) may request further resources from, say, a database. In that case a concurrency problem arises, and whenever two users need to acquire the same resource (a row in a data table, the whole table, a log file...), some sort of semaphore system makes it so that only one of them at a time can acquire a "lock" on that specific resource, and all others must wait for their turn, even if the overlying web server is capable of handling hundreds or thousands of concurrent connections.
In your example and seeing the "WAMP" tags, you have a Windows Apache serving data retrieved from MySQL by PHP, and serving requests on products.
The Apache server will receive hundreds of connections, activate hundreds of instances of PHP module (they'll share most of their code, so memory occupation doesn't go up disastrously fast), and then all these instances will ask to MySQL, "What about product XYZ?". In MySQL parlance they will try to obtain a
READ LOCK. Read lock means something like, "I'm reading this thing, so please none of you dare write on it until I'm finished". But all of them are just reading, so they will all succeed - concurrently.
So no, there will be no stops -- just then.
But suppose you also want to update a counter of product views. Then every PHP instance also needs a
WRITE LOCK, which means, "I want to write on this thing, so none of you read until I'm finished or you'll risk reading half-baked data, and of course none of you write here while I'm going at it".
At this point, the table type counts. MyISAM tables have table locking: if the instance updating product A's statistics is writing on
product_views, no other instance will be able to do anything with that whole table. They will all queue and wait. If the table is
InnoDB, the lock is at row level - all instances updating product A will queue one after the other, parallel to those updating product B, C, D and so on. So if all instances are writing to different records, they'll run in parallel.
That's why you really want to use InnoDB tables in these cases.
Of course, if you have a record such as "page visits", and they are all updating the row for "product-page.php", you have a bottleneck right there, and in case of a high traffic site, you'd do well if you designed some other way of writing that information (one of many workarounds is to store it in a shared memory location; every now and then one of the many instances accessing it receives the task of saving the information to the database. The instances still compete for locking on the memory, but that's orders of magnitude faster than competing for a database transaction).